PRO ® U120 User Manual A91M.12-271956.06
Contents
1. 00 0 cece eee eee 165 Function Block FB2 eee eee 169 Function Block FB3 0c cece eee ee eee 169 Function Block FB4 0 ena 170 Function Block FB5 eee eee 171 Function Block FB6 00 cee eee eee ee 172 Function Block FB7 cee eee eee eee 173 Function Block FB 8 seen 174 Function Block FB10 00 cee eee eee ee 175 Function Block FB11 seen 175 Function Block FB12 s eese 177 Function Block FB13 0 cece eee eee 178 KOS 201 Parameter assignment 179 General Information 181 Handling 00 cece cece eee eee eee eee ene 183 Main Menu EB B1 ena 184 Process parameter list EG B1 185 General Parameters E7 B1 seus 185 SEAB parameter E7 B2 22 222 nn nenn 187 KOS Parameters for SEAB 1F E7 B3 188 Assignment Lists for SEAB 1F E7 B4 190 APS Parameter E7 B5 0 ee 196 Archiving E6 B2 greens 200 Transfer EO BB oett ned 203 Printer Output E6 B4 L LL 205 EPROM Menu E6 B5 seen 208 EPROM 27C256 SMD 000 c ccc e eens 208 KOS Firmware and Parameter EPROM 211 Reset of PADT Memory E5 B1 214 Bottom Up Configuration Export E6B6 215 xviii Table of Contents 05 05 Part V Chapter 1 1 1 Part VI2. the data are extended or removed from the existing list Extension here means that the next free object number is allocated to a new message 05 Handling 215 n lh Bottom Up Configuration Export Delete PV Number List F7 gt F2 A reallocation of the PV numbers can be forced by deleting the PV list as well as by automatically reallocating by extending the object number range downwards Reallocation means that all the PVs are assigned sequential object numbers sorted according to F and A1 bytes If PVs are deleted from an existing configuration gaps may occur in the object numbers These gaps are maintained after a new generation run unless the PV list was deleted and all numbers were reallocated General information Since the bottom up configuration is called by the KOS parameter assignment all the messsages parametrized in the menues Data Monitoring Direction and Data Control Direction are included also those configured manually afterwards Relocated counted measurands are also entered in the list if the transfer bit was parametrized for relocated counted measurands The counted mesurand and the relevant relocated counted measurand have the same object numbers but different PV attributes A Caution In operations with 2 KOS modules in one outstation you should ensure that they are operating with different substations or master stations for a successful bottom up configuration The configuration of redundant lines
3. 10 OUTP MB1 kkk 11 LD MB1 Load command counter and if 1 command 12 V1 was transferred from the KOS 13 AN M1 5 and if the command output timer expired 14 E M1 4 set input marker for the timer l kkk 15 LD MB1 if command from the KOS is waiting and 16 V1 the input marker of the command output timer 17 AN M1 6 was 0 in the last IL scan 18 BCC PB14 call check for persistent command 19 DA M1 4 Store state of the timer input marker 20 A M 1 6 in M 1 6 E kkk 21 SA M 1 4 22 BCC FB9 Call command output 23 NAME BEFAUS BE Macro file BEF 1AN MAC Command output Call 1 of n check BA FB7 EBe b MB1 kk 144 IL Blocks and Macros 05 Macro file BEF1_AUS MAC Command output conditional call MB1 K1 UN M1 5 M1 4 mes U M1 4 BAB FB9 BE Macro file BEF2_AUS MAC Command output conditional call L MB1 K1 UN M1 5 M1 4 Tes L MB1 K1 UN M1 6 BAB PB14 U M1 4 M1 6 em U M1 4 BAB FB9 BE Lines 1 and 2 are generated by PRO 7 U120 Lines 3 to 10 are generated from macro BEF 1AN MAC and lines 11 to 23 from macro BEF2 AUS MAC The individual input bytes of the KOS are transferred to the function block FB7 in lines 3 to 10 This checks whether a command is to be output MB1 0 no command output MB1 1 gt command output MB1 gt 1 no command output because several commands may not be output simultaneously 05 IL Blocks and Macros 145 If persist
4. 150 IL Blocks and Macros 05 Since two outputs which lie under one another always form one command the 1st and 3rd outputs of a module are copied to the position of a marker string which the corresponding command has in the input byte of the KOS The function block then checks the input byte and the marker string are then checked for agreement This is not necessary for 16 output modules since the upper 8 outputs form the 2 pole commands there together with the lower 8 outputs Therefore only the upper 8 outputs need be compared with the input byte As with the 1 pole command output this is done using the macro DAUERBEF MAC 05 IL Blocks and Macros 151 6 3 15 Program Block PB15 Cancellation check for 1 pole command output 01 BC FB10 02 NAME P ABEF 03 AUSG Q8 1 8 outputs defined as 04 CNT1 CNT 8 cancelled command output 05 EING 17 1 are compared with 06 CNT2 CNT 8 8 inputs defined as return information kkk 07 BC FB10 08 NAME P ABEF 09 AUSG Q9 1 4 command outputs of a DAP 212 10 CNT1 CNT 4 11 EING 19 1 are compared with the 4 12 CNT2 CNT 4 first inputs s kkk BE Macro file P ABEF MAC Check command for cancellation BA FB10 Ax y ANZ a Ez y ANZ a kk In the check for cancellation the outputs are checked for agreement with the corresponding inputs The transfer parameters CNT1 and CNT2 define whether 4 or 8 I Os should be checked 152 IL Blocks and Macros 05 Cancellation chec
5. BE1 AUS2 MAC Command to 2 x group of 8 outputs 2 pole BE2 AUS2 MAC Output command on 4 x 2 outputs 2 pole BE4 AUS2 MAC Command to 2 x 2 outputs 2 pole BE1 RSET MAC Reset command to group of 4 outputs BE2 RSET MAC Reset command to group of 16 outputs BEF 1AN MAC Call 1 of n check BEF1 AUS MAC Call command output conditionally without persistent commands BEF2 AUS MAC Call command output conditionally with persistent commands F ABEF MAC Generate return information check poss organization information P ABEF MAC Check cancellation DISW MAC Digital setpoint value output ANSW MAC Analog setpoint value output T STOER MAC Timer for malposition suppression time T BEFAUS MAC Timer for command output time VERKL MAC Timer for cancel link time DAUERBEF MAC Check persistent command for 8er output group DAUERBE1 MAC Check persistent command for DAP 208 2 pole DAUERBE2 MAC Check persistent command for 4er output group ZWREGFB MAC Function block two position controller ZWREG MAC Call two position controller DRREGFB MAC Function block three position controller DRREG MAC Call three position controller PBMFB MAC Function block pulse width modulator PBM MAC Call pulse width modulator EXTREM 1 MAC Call extreme value processsing EXTREM 2 MAC Standardize extreme values INTERV M MAC Minute interval for extreme values INVERV H MAC Hours interval for extreme values 124 IL Blocks and Macros 05 6 2 The Organization Block Note The end o
6. Data input Edit library Fi F8 All existing library files are listed in alphabetical order in a window The arrow marking the selected library can be shifted with f and gt The lines are scrolled at the start and end of the window if more library files exist than can be displayed in the window When installing PRO U120 a library PRO120 BIB is provided which contains all the necessary hardware and software components for the U120 The individual components are listed together with their names and part numbers You can copy this file to another with F1 You will be requested to enter the file name of the new library which may have a maximum length of 8 characters PRO U120 appends the extension BIB and thus identifies the file as a library file A Caution Even if you created a new library with the copy funciton you are still in the library which you selected when entering this menu If you want to process the new library leave the menu with F9 or Esc and select it again with F8 The new library is then displayed for selection in the window You can delete all libraries except the one you read in to process with F2 You will be queried as to the file name and the corresponding library will be deleted after termination of the input with Cr It is advisable to create several library files if PRO U120 is also to be used as a calculation aid You can then enter a price per unit fo
7. 0 0 ccc eee nennen 60 Table of Contents 05 05 Chapter 5 5 1 5 1 1 5 1 2 5 1 3 5 2 5 2 1 5 2 2 5 2 3 5 2 4 5 2 5 5 2 6 5 2 7 5 2 8 5 3 5 4 5 5 5 6 Chapter 6 6 1 6 1 1 6 1 2 6 1 3 6 2 6 3 6 3 1 6 3 2 6 3 3 6 3 4 6 3 5 6 3 6 6 3 7 6 3 8 6 3 9 6 3 10 6 3 11 6 3 12 6 3 13 6 3 14 6 3 15 6 3 16 6 3 17 6 3 18 Handling 00 cece cece eee eee eens 61 General Information 00 cece cece 62 The Line Editor d 224 22 2422 222 ERIC 63 Start of PRO U120 EOB1 0000 65 AULOSaVE i coss an Kar ee 66 Data Input ET BT iw ee ee 67 Project data E2 B ccs 2444 040 ass past 67 General Outstation Data E2 B1 69 Number of data points E2 B1 0000000 75 Subrack select E2 B1 2 eee 79 Module and Subrack Assignment E2 B1 80 Special Processing of Data Points E3 B6 90 Comment Data Point List E3 B7 96 Edit Library E3 B8 0 000 99 Data Archive E1 B1 eee eee 101 Generation of IL and Transfer E1 B1 103 Printer Output E1 B1 0 2 00 eee eee 108 Display Bill of Materials on the Screen E1 B1 117 IL Blocks and Macros nenn 119 S imraty ana een 120 List of the IL Blocks 0 0 00 eee eee eee 121 List of the Markers Used 002 eae 122 List of the Macro Files seeeesseeese 124 The Organiza
8. 05 vii Copyright All rights reserved No part of this document may be reproduced or transmitted in any form or by any means electronic or mechanical including copying processing or any information storage without permission in writing by the AEG Aktiengesellschaft You are not authorized to translate this document into any other language Trademarks All terms used in this user manual to denote AEG products are trademarks of the AEG Aktiengesellschaft 1994 AEG Aktiengesellschaft viii 05 Terminology Note This symbol emphasizes very important facts A Caution This symbol refers to frequently appearing error sources Warning This symbol points to sources of danger that may cause financial and health damages or may have other aggravating consequences er Expert This symbol is used when a more detailed information is given which is intended exclusively for experts special training required Skipping this information does not interfere with understanding the publication and does not restrict standard application of the product ab Path This symbol identifies the use of paths in software menus Figures are given in the spelling corresponding to international practice and approved by SI Systeme International d Unit s l e a space between the thousands and the usage of a decimal point e g 12 345 67 05 ix Abbreviation Explanation ALU A byte A1 byte AWD IL BGT D1 D2 D3 D4 byte
9. Bottom Up Configuration Export Generate Export File F7 gt FI The PV number range of the particular KOS module is first defined by entering the first and last object numbers Object numbers between 1 and 65535 are possible The generation of the export file is then called The range should contain some reserve for extensions since it is not possible to define or extend individual object numbers A range of about 300 numbers is recommended since this covers the maximum number of PVs which can be configured with PRO U120 The maximum number of PVs which can be transferred with a KOS 201 is 2048 This number however is a theoretical value based on 64 x 16 informations plus 64 x 16 commands This number of PVs will hardly be reached even with a user dependent IL If a defined area is extended upwards and the generation is then called this has no effect on the PV numbers which were already assigned You must simply ensure that the range does not overlap with other outstations since there is a plausibility check for the import functions of other configuration tools e g PRO Z120 and PRO UZ120 If a range is shifted or extended downwards all the object numbers are reallocated gt Note If the data of an existing KOS parameter assignment SEAB parameter number of messages etc were changed the PV number list must always be generated again If the old PV number list is not completely deleted see Delete PV Number List
10. Command No 1 4 9 24 25 40 41 44 1 16 17 32 33 36 37 40 Command group No 0 f 01 1 2 2 0 1 2 2 Information group No 0 1 0 1 gap Figure8 Equipment suggestion for command output modules 05 Handling 89 5 2 6 Special Processing of Data Points E3 B6 Measurand processing E4 BA ao Data input Special processing of data points Measurand processing F1 F6 F1 All the measurands configured in the module select menu are listed Each single one can be assigned an upper and a lower limit to be monitored and a hysterese Limits from 32000 to 432000 for 11 bit measurands and from 0 to 250 for 8 bit measurands are possible The hysterese is defined as an absolute value be tween 0 and 32000 250 and is valid for the upper and lower limits Two items of virtual monitored information are assigned to each measurand to be monitored during generation of the IL One each is assigned for the upper and lower limit even if only one limit is to be monitored The virtual monitored information is assigned to the measurands in the order in which it occurs If the supplement mode of processsing is selected limits which are entered later do not change the original order of the monitored information The new monitored information is appended The virtual monitored information for the limit monitoring begin with SEAB subaddress 32 20H 90 Handling 05 lower limit value upper limit value Y 14 A A Y Y A 32000 0 32000 Hy
11. EIN IWL OUT B2R ANZ ANZR ck LD EIN Load measurand input C MW1 and write to marker word MW1 VO If measurand less than NULL zero JT zNEG skip to processing of negative MW LD MW1 Load measurand and check gt V16382 for overflow JF LAB1 If no overflow convert measurand LD V 16382 Limit measurand to maximum MW1 MW1 SHR V6 MW2 Corresp measurand 64 SHR V1 Corresp measurand 128 ADD MW2 MW2 Measurand 64 Measurand 128 LD MW1 SUB MW2 MW2 Measurand Measurand 64 Measurand 128 MW2 SHL V1 Converted measurand x 2 left justified TBW OUT Reload converted measurand DBB CNT to two KOS output bytes JT ENDE LD MW1 Load measurand and D V 16386 check for overflow JF LAB2 If no overflow convert measurand LD V 16386 Limit measurand to minimum n MW1 WA MW1 Load negative measurand DA VH7FFF Mask out sign bit and MW3 store in marker word MW3 SHR V6 C MW2 Corresp measurand 64 IL Blocks and Macros 171 ENDE 6 4 6 NAME BEZ BEZ BEZ BEZ BEZ BEZ 172 DBB Function Block V1 MW2 MW2 MW3 MW2 MW2 MW2 V1 MW2 VO MW2 OUT CNT EXTREM MESS B2L CNTI CNT L MIN B2R CNT2 CNTR MAX B2R CNT3 CNTR RK LBW MESS DBB CNT1 MW 1 LBW MIN DBB CNT2 MW 2 LBW MAX DBB CNT3 MW 3 LD MW 1 i lt MW 2 JF LABEL L MW 1 TBW MIN IL Blocks and Macros Corresp measurand 128 Measurand 64 Measurand 128 Measurand Measurand 64
12. If the KOS file is newly created the standard values for the transfer bit ring buffer entry edge detection code etc are set If you made no changes to the data points you can call the KOS parametering without generating a new file The settings you made in a previous call are not changed by this 182 General Information 05 Chapter 2 Handling Handling 183 2 1 Main Menu E5 B1 The main menu appears after the KOS parametering has been called You can change the individual submenues with the function keys F1 F6 g g F1 F2 F3 F4 F5 F6 F7 F8 F9 Configure parameter lists Data Archive Transfer Printer Output EPROM Menu Reset of PADT Memory Bottom up configuration export Switch Monochrom Color Return to DOS or PRO 7 U120 main program 184 Handling 05 2 2 Process parameter list E6 B1 A menu appears from which you can branch to the particular submenues 2 2 1 General Parameters E7 B1 ihe Process parameter lists General parameters F1 F1 The current date is displayed if this outstation is processed for the first time The last date of processing is displayed if an existing parameterdefinition was read in from diskette hard disk EPROM or KOS RAM System A maximum of 8 characters may be entered Only characters which are valid for file names under DOS are permitted because the system name is the name of the subindex under which the
13. and is reset with the reset enable ER 1 You can set the time intervals in which the controller module should be executed using the clock pulse time TA If the controller is to be executed in each IL scan enter the constant O Clock pulse time TA Constant 100 ms Three position controller E4 B6 Data input Special processing of data points Three position controller F1 F6 F3 If the difference between the setpoint value WE and the actual value XE exceeds half the hysterese value HYS the output YP or YN is set depending on the sign of the control deviation A neutral zone UZ can be entered as well The output is reset when the value is less than the corresponding inner edge Overlapping of the hysteresis up to HYS 2 UZ is possible The controller is released with the release enable EF 1 and reset with the reset enable ER 1 You can set the time intervals in which the control block is to be executed with the clock pulse time TA If the controller is to be executed in each IL scan enter the constant 0 Clock pulse time TA Constant 100 ms 05 Handling 93 Pulse width modulator E4 B7 Data input Special processing of the data points Pulse width modulator F1 F6 F4 The pulse width modulator converts a numeric control deviation WE XE amplified by a factor KR into a proportional control time which is repeated regularaly in a fixed time pattern TTK The effective o
14. made in monitoring direction after the first word required for the status transport or after the third word if module failure information n of 18 was configured Reservation starts with the first word in control direction The area thus defined is not used by PRO U120 during generation of the IL The EB AB area of KOS which is reserved is auatomatically displayed when your input is terminated with Cr 05 Handling 73 gt Note The reserved area of EB AB can be defined manually with the KOS parameters Module failure information Failed terminals are reported in the organization information with the subaddress 0 If several terminals fail only the one with the highest slot address is reported Since is some cases this is not sufficient you can set here that the failed I O terminals should be reported coded n of 18 2 organization information telegrams with subaddress 1 slots 1 16 and subaddress 2 slots 17 and 18 are generated for this purpose The setting is made by toggling 1st Module location Subaddress 1 D2 0 ABx 3 Bit 20 2nd Module location Subaddress 1 D2 1 ABx 3 Bit 21 18th Module location Subaddress 2 D2 1 ABx 5 Bit 21 x Slot reference KOS DCF Receiver You can specify whether or not the KOS 201 should be equipped with a DCF receiver The setting is made by toggling 74 Handling 05 5 2 3 Number of data points E2 B1 This menu contains the call for two more submenues E3 B2 o Pr
15. 15 20 30 minutes and 1 2 4 8 12 24 hours can be selected as reload periods The selection is made by toggling 05 Handling 195 Edge detection real time information E8 B6 Configure parameter lists Assignment lists Edge detection real time information F1 gt F4 F6 If real time information was parametered in the menu for monitoring direction you can specify in this menu whether the rising edge falling edge or both edges should be transmitted as event Basic setting both edges The 16 real time information bits of a SEAB 1F telegram are always represented in the form of mouse pianos The falling edge is interrogated in the upper and the rising edge in the lower One can change between rising and falling edge with F and S The switch for the set bit can be switched between yes and no with Cr The individual bits are selected with lt gt and lt gt The group number is incremented or decremented with T and gh The individual real time information words are set in this way The first byte of the set real time information word in the KOS data field is also displayed 2 2 5 APS Parameter E7 B5 amp Configure Parameter Lists Automatic Polling Service APS F1 F5 This menu can only be selected if APS was set as the type of communications in the menu General Parameters If the communications with the master station currently only Z300M is to use the public network the
16. 20 Hz are possible but depend on the IL scan time First there is a check of the edge The allocated marker word is incremented for each rising edge of the pulse input It is reset to 0 when the value 65535 FFFFH is reached A Caution For counted measurand processing the ALU201 must be used with a backup battery so that the counter states are not deleted if there is a power failure 4 2 7 Measurand 8 Bits without Sign Configurable at ADU 204 ADU 205 ADU 206 Allocation Depending on module The number of actually required inputs is also specified Processing The measurands are formatted left justified in a function block Only positive measurands are transmitted Negative measurands are set to 0 Note f the ADU 206 is used a measuring range of 1V or 10V can be set for each of the 4 measurand inputs The ADU 206 already provides left justified measurands Therefore there need only be a limitation to 32000 52 Configuration 05 4 2 8 Measurand 11 Bits with Sign Configurable at ADU 204 ADU 205 ADU 206 Allocation Depending on module The number of actually required inputs is also specified Processing The measurand is formatted left justified in a function block and limited to 32000 This corresponds to a scale end value of 2000 gt Note f the ADU 206 is used a measuring range of 1V or 10V can be set for each of the 4 measurand inputs The ADU 206 already provides left justified measurands Therefore the
17. Blocks and Macros 05 6 3 20 Program Block PB21 Measure minimum and maximum extreme values in 10 minute interval 01 BC FB 6 Call extreme value processing 02 NAME EXTREM 03 MESS QB 2 5 Obtain measurand from transfer byte 04 CNT1 CNT 2 05 MIN QB 2 27 Transfer byte for minimum value 06 CNT2 CNT 2 07 MAX QB 2 29 Transfer byte for maximum value 08 CNT3 CNT 2 09 jek 10 LD IB 128 Transfer byte for seconds 11 VH1 If the seconds are not 1 12 M 4 1 end of block 13 BEZ 14 LD IB 126 Transfer byte for minutes 15 DIV VH10 Divide minutes bv 10 16 MB 1 17 A SMB1 If the remainder of division is 0 18 VO the interval has elapsed 19 BCC PB 22 Call extreme value standardization ok BE Macro file EXTREM 1 MAC Measure minimum and maximum extreme values BA FB6 AB a b ANZ 2 AB a b ANZ 2 AB a b ANZ 2 yk Lines 1 to 8 are generated depending on the measurand for which extreme val ues are to be computed 05 IL Blocks and Macros 161 The computed ADU 204 205 or limited measurand is transferred in line 3 The 2 output bytes for minimum and maximum value are transferred in the subsequent lines up to and including 8 In lines 10 to 13 there is a check whether the 1st second of a minute is reached If this is not the case the block is aborted In lines 14 to 19 the minutes are divided by the parametrized time interval If the remainder of the division is 0 the time interval must have been
18. LAB1 ENDE 174 Function Block DAUEBE INPU IBL MERK ML AUS B8L ANZ ANZL kkk LBB AUS DBB CNT uu MB1 DA MERK SP LAB1 LD MB1 MUL VH10 MB1 LD MB1 VHO SP ENDE LD MB1 INPU JF ENDE DA VH1 M1 4 BE IL Blocks and Macros FB 8 Load command outputs and store in marker bvte MB1 If MERK 0 shift lower 4 bits by 4 positions to the left Command in upper 4 bits of the KOS IB s If no command output set skip to end of block If command output not equal to new command from KOS skip to end of block If equal start timer for command output time again 05 6 4 9 Function Block FB10 NAME P ABEF BEZ AUSG B8L BEZ ANZI ANZL BEZ EING B8L BEZ ANZ2 ANZL kk LBB AUSG Load command outputs DBB CNT1 ma MB4 and store in marker byte MB4 LBB EING Load monitored information inputs DBB CNT2 M MB5 and store in marker byte MB5 DA MB4 Compare marker byte MB4 and marker byte MB5 DA MB5 with UND operation ik VO If comparison positive 0 M1 7 or input marker timer link time x M1 7 already set input marker BE is set to 1 6 4 10 Function Block FB11 NAME GRW BEZ KENN ML BEZ ENG B2L BEZ ANZ ANZL BEZ GREN MWL BEZ HYST MWL BEZ MELD QBR BEZ BIT MB R l kkk LBW EING Store transferred measurand DBB CNT in marker word MW1 MW1 DA KENN If KENN 0 skip to lower JF U GR limit monitoring A MW1 Compare measura
19. PRO FWT are the default settings of the AKF installation program The subdirectory in which the AKF12 EXE or AKF25 EXE are located including the drive identifier must be defined as program path Example C AEG A91 AKF12 C AEG A91 AKF12V5 D AKF125 You must make sure that a backslash V is entered after the drive identifier in order to specify the program path from the basic directory The current entries are stored when you leave PRO FWT and are available again during the next call PRO FWT always works with the current program paths in the calls Read in IL and AKF Call 05 Operating 19 20 Operating 05 Part Ill Configuration Instructions b 21 22 05 Chapter 1 Introduction Introduction 23 1 1 Program package PRO U120 The program package PRO U120 consists of o disks with the configuration software oO a disk with the conversion program D a disk with the KOS firmware g the user manual 24 Introduction 05 1 2 System requirements Hardware Software U120 ALU 200 Eprom SPS Basic software KOS Basic software KOS 201 ALU EPS 2000 YDL 52 Pad ADP 004 ADP 001 i YDL 36 1 YDL 44 Operating system P d pires PADT IBM compatible PRO U120 N Dolog AKF KOS firmware Printer Figure 1 Components for configuration and programming 05 Introduction 25 1 2 1 Hardware PUTE IBM compatible PCs with hard disk and 640 Kbyte
20. Part Ill Chap 5 2 6 If necessary enter the data for the control blocks Part Ill Chap 5 2 6 Call the IL generation Part IIl Chap 5 4 Archive the system on diskette Part IIl Chap 5 3 Print the documentation Part IIl Chap 5 5 1 2 Check list parametering and program ming When you have terminated configuration you can begin parametering the KOS and programming the ALU m 05 Call the KOS parametering using the ZOOM function in PRO gt U120 Part Ill Chap 5 2 5 Check whether the SEAB parameters are set correctly for your requirements Part IV Chap 2 2 2 Check whether the KOS parameters are set correctly for your requirements Part IV Chap 2 2 3 Check the entries in the individual assignment lists Part IV Chap 2 2 4 Archive the parameters on diskette Part IV Chap 2 3 Print the documentation Part IV Chap 2 5 Generate a KOS firmware EPROM Part IV Chap 2 6 Check List 5 o Transfer the parameters online to the KOS Part IV Chap 2 4 However this is only possible if the KOS is already equipped with a firmware EPROM or Oo Generate a parameter EPROM Part IV Chap 2 6 1 Leave the KOS parametering and return to the PRO gt U120 main menu Install the programmable controller station Part Ill Chap 5 5 Q 0 Leave the configuration aid PRO gt U120 and return to the PRO gt FWT main menu Oo Call the function read ASCII IL Part Il Chap 1 3 1 U Cal
21. This information is only given a time stamp in the KOS 132 IL Blocks and Macros 05 6 3 5 01 02 03 04 05 06 07 08 NAME 09 IN 10 CNT 11 DMNR 12 DMMB 13 14 15 16 17 18 19 20 NAME 21 IN 22 CNT 23 QB 24 MERK kkk 25 26 27 28 29 30 31 32 33 05 Program Block DA VO UR M1 9 LA VO is M1 10 ck DA VO E MBO 4 BC FB1 DOPPELM 12 1 CNT 8 MBO 7 MBO 4 LD MBO 7 Dm VO i M1 13 AN M1 11 LA M1 12 0 M1 13 BCC FB2 DM UMSP 12 1 CNT 8 QB1 7 MBO 7 M1 11 T M1 12 DOA M1 9 TOF T3 DTB 100MS LD V200 EA M1 10 R T3 M1 11 ck Marker for malposition timer Start reset Marker for malposition timer Stop reset Load double point information code in MB4 Call Check malposition Transfer inputs 2 1 to 2 8 PB5 Transfer double point information marker byte Transfer double point information code If the double point information marker byte is equal to 0 M 1 13 is set to 1 If the malposition timer expired in the last IL scan or M1 13 is set then call restore DM Transfer double point information Transfer KOS output byte Transfer double point information marker byte Store current timer output setting in M 1 12 Input marker malposition timer Malposition suppression time x 100msec M 1 10 1 Reset for timer Output timer IL Blocks and Macros 133 Macro file DOPPEL MAC Double point infor
22. Two KOS output bytes in which the counter measurand is stored The macro file is copied depending on the number of counter measurands x y are then replaced with the terminal address The variable v is replaced with the contents of the edge detection counter and the counter is incremented The variables a b are replaced with the KOS slot address and the output byte 136 IL Blocks and Macros 05 6 3 7 01 02 03 04 NAME 05 IW 06 OUT 07 08 09 10 NAME 11 IW 12 OUT 13 14 15 16 NAME 17 IW 18 OUT 19 20 21 22 23 24 LAB 25 26 Program Block LD MB 2 Marker for measurands to be converted je V1 Query 1st ADU BCC FB4 205 8BOV IW6 1 Transfer measurand QB1 15 Transfer KOS output byte i ck LD MB2 Marker for measurands to be converted Dus V1 Query 1st ADU BCC FB4 205 8BOV IW6 2 Transfer measurand QB1 16 Transfer KOS output byte i ck LD MB2 Marker for measurands to be converted iues V2 Query 2nd ADU BCC FB4 205 8BOV IW7 2 Transfer measurand QB1 19 Transfer KOS output byte ck LD MB 2 Dus V2 JF LAB LD VO ES MB2 DA MB2 INC iom MB2 BE 05 IL Blocks and Macros PB7 137 Macro file MESS8 MAC 8 bit measurands L MB2 Kk BAB FB4 EWX y ABa b ok Macro file MW ZAEHL MAC Counter for increment and reset measurand modules L MB2 Kk SPZ LAB KO MB2 LAB MB2 U INC MB2 kkk Lines 1 to 18 are generated by the ma
23. bus extension cable is printed as connection between the 1st and 2nd rows Printout of the Analog Extreme Values and the Measurand Limit Table E2 B4 Printer Output Analog Extreme Values Measurand Limit Table F4 gt F3 The limit table for measurands and the table of the analog extreme values are printed with this function If no table exists because the corresponding processing was not configured for measurands this is indicated on the sc reen by a comment Both tables are sorted according to the slot references of the particular configured measurands The slot reference is the software address with which a measurand is addressed under Dolog AKF It does not correspond to the h ardware address The first measurand of an ADU at slot 6 is thus meant by 03 01 A total of 4 hardware connections belong to this measurand Analog Extreme Values The time interval which was parametrized for determining the extreme values is first printed followed by the table This comprises 5 columns ist column Slot reference of the measurand 2nd column First of two output bytes in which the minimum value is transferred 3rd column Subaddress of the minimum value 4th column First of two output bytes in which the maximum value is transferred 5th column Subaddress of the maximum value 05 Handling 109 If both extreme values were not configured only the QB column and the subaddress of the particular configured extreme value are fill
24. byte Upper limit less hysterese to marker byte Code for limit information in marker byte 05 37 BC FB1 Call for limit monitoring 38 NAME GRW 8 bit measurands 39 M1 2 Code of upper limit 40 QB1 003 Reloaded measurand from KOS area 41 ONT 1 42 MW2 43 MW3 44 QB1 007 KOS output byte for limit information 45 MB4 ck BE Macro file MESS GR MAC Limit monitoring of measurands 11 bit Kgr MWO 2 L Khy MWO 3 L Kbit MBO 4 BA FB11 M1 1 ABx y ANZz MWO 2 MWO 3 ABa b MBO 4 ek Since no constants can be transferred to function blocks the relevant limit and the hysterese value must first be reloaded into marker words Furthermore the constant which sets or deletes the corresponding information bit if a limit value overflows or a hysterese value underflows is transferred in a further byte The limits are monitored with the converted measurands which are read from the relevant KOS output byte One byte is transferred for 8 bit measurands with the instruction CNT 1 Two successive bytes are passed for 11 bit measurands with the instruction CNT 2 The variable z in the macro is replaced accordingly 05 IL Blocks and Macros 141 Furthermore the KOS output byte in which the particular monitored information bit is to be set or deleted is transferred Transferring the marker 1 2 which is always set to 1 informs the function block that the values transferred are the upper limits
25. command when the connection to an outstation should be aborted 1 255 The APS driver itself aborts the connection after n short messages from an outstation 05 Handling 199 2 3 Archiving E6 B2 If the KOS parametering is called from PRO U120 you need not archive the parameters with this menu When parametering has been terminated and there has been a return to the PRO U120 main program the data are automatically saved in the file USTx y KOS If a station is archived on diskette in the PRO U120 main program this file is also saved Read data aw wes m Data Archive Read F27 FI All the systems processed so far are listed alphabetically in a window The arrow marking the selected system can be shifted with T and lt l gt The lines are scrolled at the start and end of the window if more systems exist than can be displayed in the window The selection is confirmed with and the previously processed KOS parameter files of this system are then listed The files are selected according to the same principle as described above If the selection of a KOS parameter file was confirmed with it is loaded into the user memory The windows can always be left with Esc or F9 without a new station being loaded 200 Handling 05 Save data aw van Data Archive Save F2 F2 First a sub directory with the name of the system is opened if it does not yet exist The data are saved in these subdirectory
26. components of a library are always used for creating the bill of materials 05 Handling 117 118 Handling 05 Chapter 6 IL Blocks and Macros The individual IL blocks and the macros used to create them are described in this chapter 05 IL Blocks and Macros 119 6 1 Summary Warning An IL generated with PRO U120 can be extended with user dependent PLC functions according to the Dolog AKF 7 A120 rules If a block generated with PRO 7 U120 is changed no guarantee can be given that it will function completely correctly The organization block is generated directly by PRO U120 there is no macro file for this The final form of the function blocks are stored in the file FBS MAC These are only read and copied by PRO 7 U120 but not changed The program blocks are divided into three categories a Block is directly generated by PRO gt U120 o Block is generated using a macro file 1 Block is generated partly by PRO U120 and partly by a macro file Blocks PB2 PB17 PB18 and PB19 belong to the first category Blocks PB4 PB6 PB12 PB15 PB20 and PB22 belong to the second category Blocks PB1 PB3 PB5 PB13 PB14 PB16 and PB21 belong to the third category 120 IL Blocks and Macros 05 6 1 1 List of the IL Blocks IL Block Meaning OB1 Block organization PB1 Process organization information PB2 Process monitoring direction PB3 Process control direction PB4 Process monitored and real time infor
27. correcting the last malposition A Caution Double point information inputs which are not used should be assigned alternately the levels 0 and 1 as otherwise they are interpreted in the IL as malpositions and constantly start the timer for the supervise time M1 M2 E1 und E2 Double point information inputs T Malposition suppression time M1 und M2 Information status which is tranferred to master station Figure 5 Time diagram for malposition suppression 72 Handling 05 Delay time for persistent commands E3 B2 Setting range 100 msec to 99 9 sec Standard setting 2 sec This delay time spans the telegram operating times between the outstation and the master station If a consistent command is sent by the master station the timer for the delay time is started If the same command arrives again during the timer operating time the timer is reset and started again immediately The command output is only reset when the timer has expired B dd A j B Command from master station T Delay time A Command output Figure 6 Delay time for persistent commands Reserved Words in Monitoring and Control Direction E3 B2 You can reserve transport capacity for virtual data or for process data which you keep in a separate part of the IL The number of words to be reserved can be specified but not their position on the ALU KOS interface The reservation is
28. data of the individual stations is archived For this reason input is absolutely necessary Otherwise the requirements of the line editor are valid If a system was terminated or confirmed with it is displayed in each menu to the upper right Comments Operator Outstation A maximum of 16 characters can be input but input is not compulsory The requirements of the line editor are valid 05 Handling 185 Type of communication The type of communication displayed in the inverse field can be toggled with Cr The standard setting is SEAB 1F Further settings SEAB 1F without M5 APS automatic polling service Outstation number A number between 0 and 126 may be input KOS address The slot in the basic subrack 1 3 in which the KOS is inserted is entered Note If the KOS parameter assignment is called by PRO U120 the entries transferred for system comment programmer and outstation cannot be edited 186 Handling 05 2 2 2 SEAB parameter E7 B2 j Configure parameter lists SEAB parameter F1 F2 First the baud rate is interrogated The standard setting is 600 baud Another baud rate can be selected by toggling with Cr 50 100 200 300 600 1200 2400 4800 9600 The subsequent times are entered in tbits Values between 1 and 255 or 60 and 65635 are possible For the standard setting see Chap 2 7 If the KOS is driven together with a UEM 001 the following times are valid Table3 Time Parameter
29. e g for PRO Z120 PRO UZ120 Overview And General Information 05 o Documentation of system by printing o Bill of materials a Hardware configuration a Data point reference list o Table of limits for measurands n KOS 201 parameters o Control blocks n General outstation data C Archiving on hard disk or diskette of the files entered and generated 05 Overview And General Information 33 2 2 Rough structure Data input Chap 5 2 r Project Data General Datas of Outstation Number of Data Points Selection of Subracks r Module and Subrack Assignment Special Processing of the Data Points List of Data Points Edit Library Archiving Chap 5 3 Read Data Save Data Delete File Change Drive IL generation and transfer Chap 5 4 Start IL Generation German Start IL Generation English Create PLC Station And Copy ASCII IL Printer output Chap 5 5 r Bill of Materials Hardware Configuration r Table of Measurand Limits Analog Extreme Values r List of Data Points General Datas of Outstation Loading Control Blocks All Lists Selection of Printers Printer Output to File Screen Output of Bill of Materials Chap 5 6 KOS 201 Parametering Part IV 34 Overview And General Information 05 2 3 Keyboard operation If a command is specified in pointed brackets lt gt in the following description this me
30. i ck DA EIN If pulse input is 1 AN FLK and was 0 in last scan JF ENDE LBW OUT load the two KOS output bytes of the measurand DBB CNT and increment them by 1 ING TBW OUT Store result in the 2 bytes again DBB CNT ENDE A EIN Store state of pulse input RUE FLK in edge detector marker BE 05 IL Blocks and Macros 169 6 4 4 Function Block NAME 205 8BoV BEZ EIN BEZ OUT kkk LD rise ED SP LD D JF LD LAB1 A SHR o SHR ADD r ll D SUB HL BW DBB SP NEG DA TBW DBB UMSP LBB DBB domi BE 170 IL Blocks and Macros IWL QB R EIN MW1 VO NEG MW1 V16382 LAB1 V16382 MW1 MW1 V6 MW2 V1 MW2 MW2 MW1 MW2 MW2 MW2 V1 M4 1 ANZ 16 UMSP VO M4 1 ANZ 16 M4 8 ANZ 8 OUT FB4 Load measurand input and write to marker word MW1 If measurand less than NULL zero skip to processing of negative MW Load measurand and check for overflow If no overflow convert measurand Limit measurand to maximum Corresp measurand 64 Corresp measurand 128 Measurand 64 Measurand 128 Measurand Measurand 64 Measurand 128 Computed measurand x 2 left justified Reload converted measurand to bit string If negative measurand set bit string to NULL zero Write markers 4 8 to 4 16 as 8 bit measurand to KOS output byte 05 6 4 5 NAME BEZ BEZ BEZ LAB1 NEG LAB2 05 ik Function Block FB5 ADU205
31. is confirmed with Cr all the files belonging to this outstation are deleted If all the outstations of a system are deleted the corresponding subindex is automaticlly deleted The delete function can be aborted with Esc or F9 Note The station which is just being processed display at the upper right of screen cannot be deleted Change drive E2 B2 TE Data archive Change drive F2 F4 Drives A Z can be toggled with F4 The drive identifier can also be entered directly after calling the function with F4 The initial state is the drive from which PRO U120 was started If this setting is changed for example from C to A drive A is now accessed for the functions read file save file and delete file 102 Handling 05 5 4 Generation of IL and Transfer E1 B1 Start generation of IL German E2 B3 Generation of IL and Transfer Start IL generation German F3 F1 The individual generated blocks are written into the file USTx AWL The file USTx AWL is opened for writing in APPEND mode APPEND means that additional write operations are always appended to the current end of the file The generation of the IL can also be called with Alt G The IL is generated as follows Step 1 Determine maximum number of single data points Step 2 Write macro file for function blocks into file USTx AWL Step3 Set up organization block OB1 Step 4 Read macro for organization informatio
32. is not included in the bottom up configuration 216 Handling 05 Data storage The files with the data for the bottom up configuration are stored in the system directory with the name Uxxx yyy KOM The file structure is described in Part V Example C ANLAGE1 PRO FW U000 001 KOM XXX Outstation number yyy line number or slot of the KOS if KOS201P is started directly Handling 217 05 218 Handling 05 Part V File Structures 219 220 05 Chapter 1 File Structures File Structures 221 1 1 Bottom Up File The bottom up file generated in the outstations has the name Uxxx yyy KOM The same file can also be generated for the slave KOS of a substation These are given the names Zxxx yyy KOM XXX outstation or substation number yyy line number The files are stored in the subdirectory of the particular system e g C ANLAGE1 PRO FW U000 001 KOM The file for the bottom up configuration has three parts with the following structure struct head File header struct comm Communications data struct pv PV number list Structure of file header struct head char tool 10 Text Name of the tool e g PRO U120 char version 5 DEC Version of the tool e g 02 01 char date 10 DEC Date of last file processing 222 File Structures 05 Structure of Communications File struct comm char mode 1 DEC l master 2 slave char baud 5 DEC baud rate char lead 3 DEC lead time char
33. main memory A guarantee is only given for AEG devices Printer with parallel interface DRU 292 293 DRU 120 DRU 096 DRU 1200 PRT 294 295 EPROM programming station EPS 2000 Programming adaptor ADP 001 ADP 004 1 2 2 Software o DOS Version 3 2 3 3 5 0 o Dolog AKF 7 A120 Version 5 0 a KOS firmware 26 Introduction 05 1 3 Installation Installation PRO U120 Switch on device operating system level Display C2 Step 1 Diskette 1 in diskette drive A or B Step2 Installation routine with call A INSTAL or B INSTAL depending on the drive selected and start Cr Step 3 Now follow the instructions of the installation program 05 Introduction 27 1 4 New Features 1 4 1 Compared to PRO U120 V 4 0 Note t is essential that you observe the remarks about the update version in Part Ill chapter 1 5 Control file A control file was introduced in Dolog AKF A120 version 5 0 for the call by PRO FWT This version of the software package PRO creates a corresponding file and thus controls the flow in the call Read in ASCII IL The software package is no longer compatible with older AKF12 versions Clock time management in KOS firmware The message Minute pulse missing can be suppressed with parameters Part IV chap 2 2 3 The running reserve for the time management can be set to 1 26 and 50 hours with parameters part IV chap 2 2 3 ALU battery status The status of the ALU ba
34. of a substation The files of a substation are identified bv the leading Z in the file name e g Z020 002 KOM 226 File Structures 05 Part VI Index 228 05 Index A Archiving Part Ill 101 Arrow keys Part Ill 36 Autosave Part Ill 66 B Bill of materials Part Ill 117 C Cancel link time Part Ill 56 70 Cancel supervise time Part Ill 56 71 Cursor keys Part Ill 36 D Data archive Part Ill 101 102 Change drive Part Ill 102 Delete file Part IIl 102 Read data Part Ill 101 Save data Part Ill 101 Data input Part III 67 100 Comment data point list Part III 96 Edit library Part III 99 General outstation data Part Ill 69 74 I O module select Part III 80 Number of data points Part Ill 75 Project data Part III 67 Subrack select Part Ill 79 Data model Part Ill 65 Data point list Part Ill 96 98 Data type Actively cancelled command Part III 56 Analog setpoint value Part Ill 58 05 Command 1 pole Part Ill 70 2 pole Part Ill 70 Command type Part Ill 70 Commands Part Ill 53 56 Counted measurand Part Ill 52 Digital setpoint values Part Ill 57 Double point information Part Ill 49 Measurand 11 bits Part Ill 53 Measurand 8 bits Part III 52 Monitored information Part Ill 49 Persistent command Part III 55 Pulse command Part Ill 84 Pulse commands Part Ill 55 Real time information Part Ill 51 Return information Part Ill 50 56 System Information Part Ill 51 DCF rece
35. operated The firmware files are stored by an installation routine on the diskette in the subdirectory PRO FWT PRO U120 TEXTE 05 Handling 211 Read Parameter EPROM s EPROM Menu Read Parameter EPROM F5 FI The range from 7A00H to 7FFFH in which the parameter lists are stored is read in The data are converted and displayed in the corresponding submenues of the data input Program Parameter EPROM E EPROM Menu Program Parameter EPROM F5 gt F2 The parameters are stored in the EPROM range from 7A00H to 7FFFH Read Firmware EPROM EPROM menu Read Firmware EPROM F5 gt F3 The firmware EPROM is read in from address 0000H to 7FFFH in user memory and can then be copied Program Firmware EPROM e EPROM Menu Program Firmware EPROM F5 gt F4 You have read a programmed firmware EPROM or a firmware file into user memory The contents of the user memory are now programmed from address 0000H to 7FFFH on an empty EPROM Caution Remove the backup battery from the KOS before changing an FW EPROM 212 Handling 05 Read firmware file em EPROM Menu Read Firmware File F5 gt F5 All the installed firmware files are displayed in a selection window With lt F gt you can display the helptext for the firmware version marked with the arrow After reading the file the part number and the index of this firmware is displayed on the screen The selection is made with lt
36. ovtr 3 DEC trailer time char pause 3 DEC pause time char rept_kt 3 DEC call repetition KT char rept 1t 3 DEC call repetition LT char s r 1t 3 DEC send repetition LT char ackno 5 DEC acknowledge long message char M5led 3 DEC M5 lead time monitoring char M5tr1 3 DEC M5 trailer time monitoring char with m5 1 DEC 0 with M5 l without M5 char list 1 DEC list 1 SEAB IF 2 APS char pv_strt 5 DEC start of object number range char pv_end 5 DEC end of object number range char s_idnt 12 DEC station identifier char new_strt 3 DEC new inquiry if disturbed outstation after n polling scans char multi_6 12 DEC multicast command char multi_7 12 DEC multicast command char multi_8 12 DEC multicast command char multi_1 12 DEC multicast command 1 char multi_2 12 DEC multicast command 2 char multi_3 12 DEC multicast command 3 char multi_4 12 DEC multicast command 4 char multi 5 12 DEC multicast command 5 6 1 8 The parameters s idnt new strt multi n were included in the file structure in preparation for MODNET 1W 05 File Structures 223 Structure of PV Number List struct pv i char pv attr 2 HEX PV attribute char kpv cnr 4 HEX PV counter number char a 2 HEX A Byte SEAB IF char f 2 HEX F Byte SEAB 1F char al 2 HEX Al Byte SEAB 1F A combination of the A1 and D1 bytes and not just the A1 byte are stored here in commands Thi
37. that there is no collision with the generated IL The generated IL must be changed if necessary Warning An IL generated with PRO U120 is supplemented with user dependent PLC functions according to the Dolog AKF A120 rules If the blocks generated by PRO U120 are changed no guaraantee can be made that these changed blocks will function correctly The following upper limits are checked after each data point assignment tj maximum number of data points per data type O capacity of the ALU KOS interface 0 power load of the 24 V and 5 V power supply 86 Handling 05 A message appears on the screen if an upper limit is exceeded and the assignment is not made You can call a survey of the assigned data points with the function key F8 see Chap 5 2 5 Peculiarities when zooming the KOS The module KOS 201 has a special status No data points are assigned here in the ZOOM function instead the parameter assignment program is called and the line numbers and possibly an additional module are entered The input of a line number is necessary for the bottom up configuration in order to make a connection between the outstation and the master station or subst ation The line number also defines the file names for storing the KOS parameters The descriptions of these parameter assignment programs can be found in Part IV The call becomes active with Cr The line number is entered in decimal between 1 and 999 The addi
38. the data model should be regenerated or only supplemented The data model should always be regenerated as long as it is not passed to a master station A Caution If the data model of an outstation has already been ac cepted in a master station please only continue processing with supplement as otherwise the data model of the master station also must be changed Warning Supplementing means that the data points are in cluded Data points which already exist may not be modified or deleted as this results in chaos in the data model Deletion or modification is only possible in restart mode 05 Handling 65 5 1 3 Autosave Before leaving certain submenues the data edited or generated there are stored on hard disk In particular these are the menues Data input Number of data points Module select Measurand processing Control blocks Data point list Edit Library Generate IL Display of the bill of materials on the screen 000212002000 000 66 Handling 05 5 2 Data Input E1 B1 Note Modification of the module or data point assignments is only possible in restart mode The same is valid for deleting modules or data points Empty slots can be assigned modules in the supplement mode Similarly inputs or outputs can be defined on already existing modules for which no data was previously assigned These new entries can be modified and deleted within a supplementary run If the station is processed again in sup
39. 1 Supply O 03 02 Supply O o sa oo 1 7 aBoo3 o 03 03 Mon Inf o o O 8A 00 16 QBO03 1 03 04 Mon Inf o O 8A 00 15 QBO03 2 03 05 Mon Inf e O 8A 00 14 QBO03 3 03 06 Mon Inf O o 8A 00 1 3 QBo0o3 4 03 07 Mon Inf Oo O 8A 00 1 2 QB003 5 03 08 Mon Inf O 8A 00 1 1 QB003 6 03 09 Mon Inf o o aa o0 1 0 aBoo3 7 03 10 Mon Inf O 03 11 Common O 03 12 Supply 9 03 13 Supply 0 AA 00 QB 005 03 14 Count M e o 0 AA 01 QB 005 03 15 Count M e 0 AA 02 QB 009 03 16 Count M Oo 0 AA 03 QB 011 03 17 Count M O 0 AA 04 QB 013 03 18 Count M O 03 19 free O 03 20 free o 03 21 free oO 03 22 Common l 8 c N Figure 10 Excerpt of the data point list Printout of the general outstation data and Loading E2 B4 Printer output General outstation data and Loading F4 F5 The folloiwing data are printed oO Type of command a Output time of the pulse commands listed according to slot address and terminal group a Cancel link time oO Cancel supervise time 0 Malposition suppression time o Delay time for persistent commands 112 Handling 05 oO Reservations in monitored and control direction a Module failure information n of 18 o DCF receiver for KOS o Assignment of organization information telegrams On a further page the configured module as well as its load on the 5 V and 24 V power supply are printed for each slot Since it is not always necessary to print a
40. 11 bit measurands The 8 bit measurands are scaled accordingly from 0 255 or from 0 250 Set by toggling 0 Some master stations e g A350 cannot process 4D telegrams One can Switch to pure 2D telegram operation for these master stations 188 Handling 05 Note There can be no ring buffer processing if there was a switch to pure 2D telegrams The system information is sent in a special format see user manual U120 For this reason the module failure information cannot be transferred n of 18 as system information subaddr 1 and 2 It should be reparametrized into monitored information if a transfer is necessary rj There is a query whether a DCF receiver should be connected This is set with the keys J and N or by toggling o The starting behavior of the KOS after a power failure is set One can toggle between cold restart and hot restart A cold restart means that the ring buffer RAM is normed when the power returns In a hot restart the battery buffered ring buffer data is transferred to the master station o There is a query whether the KOS should transfer the time of day to the PLC see also Chap 2 2 4 Data for Control Direction 0 Suppress meassage Missing Minute Pulse The meassage Missing Minute Pulse is send once 10 minutes after the last valid minute puls via DCF 77E Every valid time meassage resets the error counter of the KOS firmware so that at least 10 wrong or missing time meassages in
41. 2 6 4 2 7 4 2 8 4 2 9 4 2 10 4 2 11 4 2 12 4 2 13 4 2 14 4 2 15 4 3 4 4 Overview And General Information 31 Summary of Features 0 e eee eee eee 32 Rough structure 22 lisse de pe 34 Keyboard operation 0 cece eee eee 35 Mouse operation erinra viii ernennen 37 General information L 38 Overview How To Work sees 39 Flow Ghart na M Reb te s 40 Tree Structure of the Menues 000000 0 41 Directory Structure 00 cc cece eee ee 44 Configuration 2 432252 47 Definitions of the Communication Ports 48 Definition of the Data Types 005 49 Monitored Information sssaaa nennen 49 Double point Information sees 49 Return Information 00000 eee eee eee 50 Real Time Information 000 000 51 System Information 0 0 eee eee eee 51 Counted Measurands 0c ee eee 52 Measurand 8 Bits without Sign 52 Measurand 11 Bits with Sign 00000000 53 1 Pole Commands L20 0c cece eee eens 53 2 Pole Commands 00 i 54 Pulse Commands 00 ea 55 Persistent Commands 0 0c eee eee eee 55 Actively Cancelled Command Luuuuu 56 Digital Setpoint Values 0 cee eee 57 Analog Setpoint Values eee 58 Configuration Limits 0 0 eee eee eee eee 59 Special Features
42. 212 subdivided into 1 x 4 and 1x 8 DAP 292 subdivided into 1 x 4 and 1x 8 DAP 216 subdivided into 2 x 8 DAP 220 subdivided into 1 x 8 and 1x 8 ADU 204 subdivided into 1 x 4 ADU 205 subdivided into 1 x 4 ADU 206 subdivided into 1 x 4 DAU 202 subdivided into 1 x 2 DAU 208 subdivided into 1 x 8 OQ OOOOOOOoOooOooOoOaoaaAaaA The individual connect groups are selected with lt Home gt and lt End gt The data types are set with lt f gt and lt gt The selected data type is passed to the connect group with Cr An assigned data type can be deleted with Del Note When working in supplement mode data points which were configured during previous processing cannot be deleted or overwritten For pulse commands a command runtime command duration can be assigned per output group Times between 100 msec and 99 9 sec are possible The standard setting is 300 msec The runtimes for persistent commands and actively cancelled commands are assigned in the menu general outstation data see Chap 5 2 2 Connect groups with 8 or 4 inputs are always defined for counter measurands and measurands but the number of inputs actually used must also be specified Analog setpoint value outputs are handled in the same manner 84 Handling 05 The number or command runtime must always be input if the corresponding query is displayed inversely in the ZOOM window If an ADU 206 was selected for the measurand processing a mea
43. 3 MB5 M4 5 M4 6 ME33 DMNR VH4 VH4 MEL4 VH1 M1 9 DMNR VH4 DMNR MB5 MB6 ENDE DMNR VH4 VH 4 MEL4 DMNR VHFB DMNR MB5 MB6 MEL4 VH1 M1 10 VHZO MB 6 Check 3rd double point information Add constant 3 to DMMB for 3rd double point information and store result in MB5 Check input 5 and 6 for inequality Further processing and check in the same manner as for 1st double point information IL Blocks and Macros 167 MEL4 LD DMMB ADD VH4 E MB5 SUA M4 7 DX M4 8 SP ME44 SA DMNR A VH8 Ji E VH 8 SP ENDE DA VH1 M1 9 TA DMNR 0 VH8 nS DMNR D MB5 ve MB6 SP ENDE ME44 DA DMNR DA VH8 VH8 JF ENDE DA DMNR A VHF7 DMNR LD MB5 SS MB6 JF ENDE DA VH1 E M1 10 SA VHO uS MB6 ENDE BE 168 IL Blocks and Macros Check 4th double point information Add constant 4 to DMMB for 4th double point information and store result in MB5 Check input 7 and 8 for inequality Further processing and check in the same manner as for 1st double point information 05 6 4 2 Function Block FB2 NAME DM UMSP BEZ IN B8 L BEZ ANZ ANZL BEZ OUT QBR BEZ MERK MBR ck DA VH O The double information marker byte is transferred in MERK IKS MERK and set to NULL zero LBB IN Load double point information inputs DBB CNT ins OUT and reload in KOS output byte BE 6 4 3 Function Block FB3 NAME ZAEHLWER BEZ EIN IL BEZ FLK MR BEZ OUT B2R BEZ ANZ ANZR
44. A DMNR If both equal check if malposition DA VH1 was already recognized jam VH1 1st bit set malposition recognized SP MEL2 Skip to 2nd malposition check DA VH1 DH M1 9 Set input malpositon timer DA DMNR 0 VH1 Set malposition in DMNR as recognized E DMNR 05 IL Blocks and Macros 165 ME11 MEL2 ME22 166 LD MB5 E MB6 SP ENDE TA DMNR SUA VH1 VH1 JF MEL2 SA DMNR SHA KHFE di DMNR LD MB5 GG MB 6 JF MEL2 TA VH1 M1 10 DA VO ES MB6 LD DMMB ADD VH2 MB5 A M4 3 DX M4 4 SP ME22 A DMNR DA VH2 EE VH2 SP MEL3 SUA VH1 M1 9 UN DMNR 0 VH2 DMNR LD MB5 Mr MB6 SP ENDE DA DMNR N VH2 m VH2 JF MEL3 DA DMNR DOA KHFD IL Blocks and Macros Enter malposition code in marker word for last malposition occurred Skip to block end Was this malposition set in last IL scan If no check 2nd malposition If yes delete malposition bit from DMNR l schen Was this last malposition to occur If no check 2nd malposition If yes set marker for malposition timer reset Delete marker byte for last malposition Check 2nd double point information Add constant 2 to DMMB for 2nd double point information and store in MB5 Check input 3 and 4 for inequality Further processing and check in same manner as for 1st double point information 05 MEL3 ME33 05 gt Il ADD gt Oo DMNR MB5 MB6 MEL3 VH1 M1 10 VHO MB6 DMMB VH
45. B CNT 2 03 TBW OB 2 27 for minimum vlaue 04 DBB CNT 2 05 TBW MB 3 06 DBB CNT 2 RK BE or 01 LBW QB 2 5 Store measurand oniv in ABs 02 DBB CNT 2 03 TBW MB 3 04 DBB CNT 2 05 IL Blocks and Macros 163 05 TBW QB 2 27 for maximum value 06 DBB CNT 2 kkk BE Standardization of extreme values after expiration of the time interval LBW a b DBB CNT 2 TBW a b DBB CNT2 TBW a b DBB CNT 2 kkk In this way it is possible to manage with only one macro for standardizing the extreme values 164 IL Blocks and Macros 6 4 The Funciton Blocks The function blocks all reside in the macro file FBS MAC They do not contain any variables which the generator must replace All the function blocks are written into the file USTx AWL whether or not they are required This does not result in an unnecessarily large instruction list because only those blocks which are also called in the IL are linked during PLC linkage under Dolog AKF 7 A120 6 4 1 Funktion Block FB1 NAME DOPPELM BEZ IN B8 L BEZ ANZ ANZL BEZ DMNR MBR BEZ DMMB MBR i kkk LBB IN Load double point information as byte DBB CNT TBB M4 1 and reload to 8 marker bit DBB ANZ8 LD DMMB Check 1st double point information ADD KH1 For 1st double point information add constant 1 to DMMB iS MB5 Store result in MB5 DA M4 1 Check 1st and 2nd DM inputs for DX M4 2 inequality SP ME11 If no malposition skip to label ME11 D
46. BB CNT 8 33 LD V20 34 E TSW1 35 LAB 36 LD IB1 3 37 HC VO 38 JT LAB 39 LD IB1 3 40 TBB Q4 9 41 DBB ONT 8 42 LD V20 43 ES TSW1 44 LAB BE 154 IL Blocks and Macros If yes copy to bit string output upper 4 bits to second 4 output module Write command output time in timer setpoint value Set code for cancelled commands Check if one of the commands 9 16 is set If yes output the 8 bits to the upper outputs of a 16 output module Write command output time in timer setpoint value Check if one of the commands 17 24 is set If yes output the 8 bits to the lower outputs of a 16 output module Write command output time in timer setpoint value 05 01 02 03 04 05 06 07 08 09 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 33 34 35 36 37 38 39 40 05 LAB LAB TBB DBB 2 pole command output IB1 1 Check if command 1 or 2 VHO3 is set VO LAB IB1 1 If yes copy commands to M4 1 bit string CNT 8 M4 1 Output command 1 to Q2 1 outputs 1 and 2 Q2 2 M4 2 Output command 2 to Q2 3 outputs 3 and 4 Q2 4 V03 Write command output time in TSW1 timer setpoint value IB1 1 Check if command 3 or 4 VHOC is set VO LAB IB1 1 If yes copy command to M4 1 bit string CNT 8 M4 3 Output command 3 to Q3 1 outputs 1 and 2 Q3 2 M4 4 Output command 4 to Q3 3 outputs 3 and 4 Q3 4 K300 Write command out
47. BEF MAC Check No return information for cancelled command UN M1 5 U M1 3 UN M1 7 SPZ LAB1 U K64 O ABk v z ABk y LAB1 s Lines 1 and 2 are only generated by PRO 7 U120 if setpoint value output was configured Lines 3 31 only if command output was configured Lines 3 to 7 are generated directly by PRO U120 The macro T BEFAUS MAC is read in for lines 8 to 14 The macro VERKL MAC is read in for lines 15 to 21 and the variable t is replaced with the cancel link time The macro F ABEF MAC is read in for lines 22 to 29 and variables k y are replaced with the address of the 1st KOS output byte Lines 30 and 31 are again generated directly by PRO U120 Note Lines 6 and 7 as well as 15 to 29 are only generated if actively cancelled commands are configured 05 IL Blocks and Macros 131 6 3 4 Program Block PB4 01 LBB 18 1 Load inputs 1 to 8 02 DBB CNT8 03 QB1 3 and assign KOS output byte kkk 04 LBB 18 9 Load inputs 9 16 05 DBB CNT8 06 QB1 4 and assign next KOS output byte kkk BE Macro file MELD MAC Transfer 8 MELDUNGEN items of monitored information to KOS LBB Ex y DBB ANZ ABa b kkk Monitored information is always assigned byte by byte The variables x y are replaced by the addresses of the particular input modules variable a with the KOS slot address and variable b with the AB pointer Note Real time information is handled like normal monitored information in the IL
48. DM I O module EZM F byte GRW KOS MW NLQ PV Number UST ALU 200 201 Address byte in SEAB 1F Subaddress byte in SEAB 1F Automatic selection Instruction list Subrack 1st 4th data byte in SEAB 1F Double point information Input output module Real time information Function byte in SEAB 1F Limit value KOS 201 210 Measurand Near Letter Quality Process variable number Outstation 05 Objectives This description is intended for configurers of Geadat U120 outstations The configurer is then able to 00200030 install the programming device install the software configure with the software document the configuration pass the parameters obtained transfer the generated IL to the controller and start it Arrangement of This Guide Part I Part Il Part Ill Part IV Part V Part VI Part VII 05 Check list how to proceed in order to start operations with an outstation Description of the main menu PRO FWT This part describes how to configure the Geadat U120 outstation with PRO U120 This part describes how to parameter the KOS 201 210 directly or with PRO gt U120 File Structures contains the index contains the user comments and the list of addresses xi Relevant documentation Geadat U120 User Manual Dolog AKF 7 A120 User Manual Validity This description is valid for the Software PRO 7 U120 Version 5 0 Dolog AKF A120 Version 5 0 Basic software ver
49. Ill 68 Pulse width modulator Part Ill 94 R Reserve command direction Part Ill 73 05 Reserve monitoring direction Part Ill 73 Restart Part Ill 65 67 S Several KOS per OS Part Ill 88 Special function Geadat VEN Part Ill 85 Subrack select Part Ill 79 Supplement Part Ill 65 67 Survey Assigniment KOS I O area Part Ill 82 Current input Part Ill 82 Number of data points Part III 82 Unused I O points Part III 82 System marker KOS Part Ill 123 T Three position controller Part Ill 93 Timing Cancel link time Part Ill 70 Cancel supervise time Part Ill 71 Command duration Part Ill 84 Command runtime Part Ill 84 Delay time for persistent commands Part III 73 Malposition suppression time Part Ill 71 Transfer IL to Dolog AKF A120 Part III 107 Transient information Part Ill 49 Two position controller Part Ill 93 Z ZOOM Part IlI 83 89 Index 231 232 Index 05 Part VII Appendix 233 234 05
50. KOS interface to zero MB1 QB1 1 D2 byte of the system information A1 0 QB1 2 D1 byte of the system information A1 0 QB1 3 D2 byte of the system information A1 1 QB1 4 D1 byte of the system information A1 1 i QB1 5 D2 byte of the system information A1 2 kkk LBB SM10 DBB ANZ2 SHL K6 0 QB1 2 QB1 2 l kkk CA SM32 Error in module at slot 3 2 JF LAB if not check next module DA V2 Enter slot 2 in organization information e QB1 1 CA MB1 Increment error counter INC MB1 kkk 126 IL Blocks and Macros 05 25 26 27 28 29 30 31 32 LAB 33 34 35 36 37 38 lt gt zp o ic r iw cv 7 39 40 41 42 43 44 45 LAB 46 47 48 49 50 51 52 LAB lo so g 0 so EN OD UJ m 05 SM33 LAB V3 QB1 1 QB1 MB1 MB1 V1 LAB KH20 QB1 1 QB1 1 SM2 1 SM32 LAB Y2 QB1 3 QB1 3 SM3 1 SM33 LAB V4 QB1 3 QB1 3 Error in module at slot 3 if not check next module Enter slot 3 in organization information Increment error counter Error counter larger than 1 if not skip to end of network if yes set bit 25 in organization information Module failure n of 18 Set second bit for slot 2 Set third bit for slot 3 IL Blocks and Macros 127 Macro file VERW MAC Organization information module failed 1 of 18 A SMy SPZ LAB U Kx QBk y U MB1 INC MB1 LAB fk Macro file KARTAUS MAC Organization information mod
51. KOS must be equipped with the AWD 001 interface module A postal modem MDB 1200 is also required for connection to the network 196 Handling 05 All the necessary parameters for the outstation and the master station are interrogated in this menu The connection can be made with four lines whereby there can be one master station with four lines or four different master stations The outstation itself however can only introduce a connection with lines 1 and 2 The master stations can only set up the connection with lines 3 and 4 Of course it is also possible to work with only one line A file containing the calling number of the outstation and the parameters for the master station may be specified for each of these lines The master stations can use these files for their own parameter assignment If several outstations are operating on the same line the same file name must be entered each time This ensures that the calling number of the individual outstations are collected in a master station file If the cursor is faded into a file input field existing file names can be selected from a window with F1 When an existing file is read there is a plausibility check of the paramters entered in the menu and the file contents If these do not correspond the appropriate remark appears on the screen and you can decide which data are valid There are rules governing the file names for a Z300M since these depend on the slot of the PC AWD S
52. Marker 1 1 is overwritten in der macro file 6 3 10 Program Block PB10 01 LD IB1 3 Load KOS input byte 02 TBB Q3 1 and output to outputs 1 8 03 DBB ONT 8 kkk 04 LD IB1 4 Load KOS input byte 05 TBB 03 9 and output to outputs 9 16 06 DBB ONT 8 kkk BE Macro file DISW MAC Digital setpoint values L EBe b TBB AX V DBB ANZ 8 kkk A digital 16 bit setpoint value is processed using two networks A KOS input byte is reloaded on 8 outputs in each network Variables e b are replaced with the KOS slot address and the IB pointer Variable x y s replaced with the address of the 1st or 9th module output 142 IL Blocks and Macros 05 6 3 11 Program Block PB11 01 LBW IB1 5 Load two KOS input bytes 02 DBB CNT2 03 is QW7 1 and reload to an analog output rar BE Macro file ANSW MAC Analog setpoint values LBW EBe b DBB ANZ 8 AWXx y kkk An analog setpoint value is read in from two KOS input bytes and output to one analog output Variables e b are replaced with the KOS slot address and the IB pointer Variable x y is replaced with the address of the corresponding analog output o5 IL Blocks and Macros 143 6 3 12 Program Block PB12 01 DA VO Reset command counter 02 CE MB1 s kkk 03 BC FB7 Call 1 of n check for 04 NAME UP1AUSN command otuput 05 INPU IB1 001 Transfer KOS input byte 06 OUTP MB1 Transfer command counter 5 kkk 07 BC FB7 08 NAME UP1AUSN 09 INPU IB1 002
53. Measurand 128 Converted measurand x 2 left justified Negate converted measurand again and reload to two KOS output bytes FB6 Load the 2 ABs of the measurand and store in the marker word Load the 2 ABs of the minimum value and store in the marker word Load the 2 ABs of the maximum value and store in the marker word Is marker word smaller than minimum value If no jump to maximum value comparison If yes store measurand as minimum value 05 LABEL ENDE 6 4 7 NAME BEZ BEZ LAB1 LAB2 LAB3 05 DBB LD JF LD TBW DBB BE Function Block CNT2 MW 1 MW 3 ENDE MW 1 MAX CNT3 UP1AUSN INPU IBL OUTP MBR ki ck LD VH1 E MB4 DA INPU DA MB4 122 KHO JF LAB2 DA MB4 E KH80 JT LAB3 DA MB4 SHL VH1 E MB4 DA INPU A MB4 KHO JT LAB1 LD OUTP ADD VH1 OUTP SP LAB1 BE Is measurand greater than maximum value If no jump to end of network If yes store measurand as maximum value FB7 Set 1st bit in marker byte MB4 Compare transferred command byte with UND operation If agreement skip to label LAB2 Check if last bit in marker byte is already set If yes skip to end of block If no set next bit in MB4 Compare MBA and transferred command byte with UND operation If no agreement skip to Label LAB1 and check next bit Load error counter byte laden and increment by 1 IL Blocks and Macros 173 6 4 8 NAME BEZ BEZ BEZ BEZ
54. Menu Reset PADT Memory Bottom up confi guration Switch monochrome color End of processing Level 6 Level 7 Figure 1 Figure 1 FI Common parameter F2 Input SEAB parameter KOS parameter F3 Figure 2 List of Assignment ES Input Automatic Polling F5 Service Figure 3 Figure 2 Input Read F1 Save Figure 4 E Delete file Monitoring direction Change drive Control direction F3 Setpoint value input Figure 3 P P F4 Parameter list Counted measurand from KOS processing F5 Parameter list Ring buffer to KOS handling Sean iL oyee tie Realtime Information F5 Figure 4 Edge Detection Printer Output Selection of Printers F8 Figure 5 Printer output Input to file Figure 5 Read Parameter EPROM Figure 6 Program Parameter EPROM Select Read Firmware EPROM Program Firmware EPROM Read Firmware File EPROM blank check Generate export file Delete PV num list Overview How To Work 43 3 3 Directory Structure The TOOL directory PRO U120 is set up in the main directory PRO FWT during installation The individual programs EXE files and the system information for PRO U120 are stored there The subdirectories MACRO and TEXTE are also set up These contain the macros for the IL generation or the files with the menu and help texts the l
55. NZ 2 kkk These are generated as for 8 bit measurands but two KOS output bytes must be transferred for reloading Since these are signed measurands the conversion is carried out in a different function block FB5 than for 8 bit measurands 05 IL Blocks and Macros 139 6 3 9 01 02 03 04 05 06 07 08 09 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 140 NAME NAME Program Block LD V30000 ers MW2 LD V29990 E MW3 LD V1 BS MB4 BC FB11 GRW 11B M1 2 QB1 005 CNT2 MW2 MW3 QB1 007 MB4 es LD V 1000 Eum MW2 LD V 990 HE MW3 LD V2 nz MB4 BC FB11 GRW 11B M1 1 QB1 005 CNT 2 MW2 MW3 QB1 007 MB4 Ce dels LD V240 MI MB3 LD V235 ES MB4 LD V4 mE MB5 IL Blocks and Macros PB9 Copy upper limit to marker word Copy limit less hysterese to marker word Copy code for monitored information bit to marker byte Call limit processing for 11 bit measurands Transfer code for upper limit Transfer converted measurand from KOS area 2 bytes for 11 bit MW KOS output byte for limit information Copy lower limit to marker word Copy lower limit plus hysterese to marker word Copy code for monitored information bit to marker byte Call limit monitoring Transfer code for lower limit of converted measurand from KOS area KOS output byte for limit information Upper limit to marker
56. Outstation is copied If you answer step 3 with N Cr the system EXAMPLE outstation No 0 is not copied but EXAMPLE U005 000 is opened as the new station Note If the station EXAMPLEXOSTS already exists the corresponding message appears on the screen You can now decide whether the archived data should be overwritten or loaded into user memory In the same way you can copy EXAMPLE U000 000 to TEST U003 000 by overwriting the system names and the outstation number You can then modify and supplement the corresponding menues 68 Handling 05 5 2 2 General Outstation Data E2 B1 rf Data input General outstation data F1 F2 The values set in this menu are valid for the entire outstation IL in Monitoring Direction The information is transmitted in monitoring direction to both KOS modules in each IL scan The 128 output bytes of the 1st KOS are copied in a program block to the 128 output bytes of the 2nd KOS Bytes which are not used a re also copied IL in Control Direction To prevent setpoint values from two master stations from colliding with each other a control command defines whether the data of the 1st or 2nd KOS are to be processed in the IL This command message is transmitted in input bytes 1 and 2 to the IL and must set the 1st bit in the IB x 1 The IL checks these bytes in each scan The commands and setpoint values of the last master station to send this control command are
57. PRO gt U120 User Manual A91M 12 271956 06 0894 PRO gt U120 Type PRO U120 Version 5 1 Configuration Instructions DOK 276566 06 0894 Part of Software Package E No 424 275117 Overview 05 Part Part Il Part Ill Part IV Part V Part VI Part VII Part VIII Part IX Notes Table of Contents How to proceed Main Menu PRO FWT Configuration Instructions KOS 201 Parameter assignement File Structures Index Appendix 05 Notes Table of Contents vi 05 Notes Application Note A Caution The relevant regulations must be observed for control applications involving safety requirements For reasons of safety and to ensure compliance with documented system data repairs to components should be performed only by the manufacturer Training AEG offers suitable training that provides further information concerning the system see addresses Data Illustrations Alterations Data and illustration are not binding We reserve the right to alter our products in line with our policy of continuous product development If you have any suggestions for improvements or amendments or have found errors in this publication please notify us by using the form on the last page of this publication Addresses The addresses of our Regional Sales Offices Training Centers Service and Engineering Sales Offices in Europe are given at the end of this publication
58. Part VII File Structures 219 File Structures lu pis 221 Bottom Up Filen seii iri panie cna cece eee eee 222 Indek our oos ret d o E 227 Index i A e qe ke b ea 229 Appendix sec obe x Reed s 233 Table of Contents xix XX Figure 1 Figure 2 Figure 3 Figure 4 Figure 5 Figure 6 Figure 7 Figure 8 Figure 9 Figure 10 Figure 11 Figure 12 Table 1 Table 2 Table 3 Figures Components for configuration and programming 2 pole command output on DAP 204 212 and 216 Assignment of Cancelled Commands and Return Information Rie v lb MARRIED Time diagram for actively cancelled commands Time diagram for malposition suppression Delay time for persistent commands Data point assignment 00 e eee eee eee Equipment suggestion for command output modules isss terren cece ees Limit monitoring of measurands s Excerpt of the data point list Insert Adaptor ADP 004 LLLLL eee Insert EPROM 27C256 SMD in the Adaptor Tables Configuration Limits esaesa 0 ee eee eee Keyboard Definition US Keyboard Time Parametering U120 in Different Configurations y sa ere xk Table of Contents 05 Part How to proceed 05 Chapter 1 Check List Step by step procedures for 9 configuration O parametering and programming o system start up of a Geadat U120 outstati
59. S 201 to the ALU 200 201 control direction x is the KOS slot reference Note Since the SEAB 1F has a 16 bit structure 2 bytes are always combined for one data type In the following text the term word will therefore always be used The 1st word in the monitoring direction is reserved for system information This means that only 63 words are available for the data transmission The clock time can be transmitted with the corresponding parameter assignment of the KOS 201 using the last 4 words in the control direction In this case only 60 words are available for the data transmission 48 Configuration 05 4 2 Definition of the Data Types 4 2 1 Monitored Information Configurable at DEO 216 DEP 208 DEP 216 DEP 296 DEP 297 DAP 212 DAP 220 DAP 292 Allocation In groups of 8 inputs each Processing No special processing Two input groups are allocated to one word and passed to the KOS 201 Note Transient information must be assigned parameters as real time information If no DCF receiver is connected to the KOS and no time telegram is sent by the master station the real time information is transmitted with the fine time FFFFH and without course time telegrams 4 2 2 Double point Information Configurable at DEO 216 DEP 208 DEP 216 DEP 296 DEP 297 DAP 212 DAP 220 DAP 292 Allocation In groups of 8 inputs each Processing The inputs 1 and 2 3 and 4 5 and 6 7 and 8 of an input group are checked for a ma
60. You are asked for the name of the file which is to contain the printer output The drive identifier and path commands may be entered The file is opened in APPEND mode so that all output is written to the same file This file is only closed when the printer menu is left If you want to create a file with the same name again you must first delete the old file in the DOS level as the output is otherwise appended to the end of the file Note All the printer control characters are written to this file Output to a file is advisable if for example the data point list is to be processed with another editor You can also use parts of the PRO U120 documentation in other documentation systems Note The individual IL blocks are not printed under PRO U120 The IL as generated by PRO U120 has a special format and contains control characters which are again eliminated during reading in Dolog AKF A120 For this reason the IL blocks should be printed using the corresponding functions with Dolog AKF A120 Handling 207 05 2 6 EPROM Menu E6 B5 2 6 1 EPROM 27C256 SMD 2 6 1 1 Inserting the EPROMs With this EPROM 27C256 SMD an adaptor ADP 004 must be inserted between the Textool socket and the EPROM To insert the adaptor carry out steps Step 1 to Step 6 see also Figure 11 To insert the EPROMs follow Step 1 to Step 5 see also Figure 12 Step1 Turn the lever of the Textool socket upwards Step2 Set the adaptor to the Textool socket
61. ailure 1 of 28 Part Ill 128 Module failure information Part Ill 74 Module failure n of 18 Part Ill 128 Module select Part Ill 80 Modules ADU 204 Part Ill 84 ADU 205 Part Ill 84 ADU 206 Part Ill 84 DAO 216 Part Ill 84 DAP 212 Part Ill 84 DAP 216 Part Ill 84 DAP 220 Part Ill 84 DAP 292 Part Ill 84 DAU 202 Part Ill 84 DAU 208 Part Ill 84 DEO 216 Part Ill 84 DEP 208 Part Ill 84 DEP 216 Part Ill 84 DEP 296 Part Ill 84 DEP 297 Part Ill 84 KOS Part Ill 88 N Number of data points Part Ill 75 78 O Organization block Part Ill 125 Organization information Part Ill 128 Outstation number Part Ill 68 05 P Printer output Part Ill 108 118 Bill of materials Part III 108 Control blocks Part Ill 113 Data point list Part III 111 General outstation data Part Ill 112 Hardware configuration Part IIl 108 Instruction list Part Ill 116 Loading Part Ill 112 Output to file Part IIl 116 Printer selection Part II 113 Program Blocks PB15 Part Ill 152 Program blocks PB1 Part Ill 126 PB10 Part Ill 142 PB11 Part Ill 143 PB12 Part Ill 144 PB13 Part Ill 146 PB14 Part Ill 148 PB16 Part Ill 153 PB2 Part Ill 129 PB3 Part Ill 129 PB4 Part Ill 132 PBS Part Ill 133 PB6 Part Ill 136 PB7 Part Ill 137 PB8 Part Ill 139 PB9 Part Ill 140 Project data Part Ill 67 68 Comments Part Ill 67 Operator Part Ill 67 Outstation Part Ill 67 Outstation number Part
62. ans that the corresponding key should be pressed Cr Press RETURN key Alt Ctrl Del Warm restart all three keys are pressed simultaneously F1 F3 the function keys F1 and F3 are pressed one after the other A Caution US keyboard German keyboard Esc Eing l sch gt lt Ctrl gt lt Strg gt lt Home gt lt Pos1 gt lt End gt lt Ende gt lt Prtsc gt lt Druck gt lt PgUp gt Figure f gt lt PgDn gt lt Figure gt Ins lt Einf gt lt Del gt lt Entf gt oder lt L sch gt lt Return gt lt bernahme gt auch Enter oder lt gt Function keys The individual submenues are selected with the function keys There is always a return to the previous menu level with F9 Help is always called with lt F10 gt 05 Overview And General Information 35 Arrow keys cursor keys The parameters are selected or modified in some menues with these keys A Caution If your PUTE does not have a separate cursor block make sure that the key Num Lock is switched off as otherwise the number block is active Return key The input in the line editor is terminated or the selected parameter is accepted with this key Esc key There is a return to the previous menu level with this key Toggle Different settings can be selected by pressing the Return key repeatedly 36 Overview And General Information 05 2 4 Mouse operation The right mouse key corre
63. arallel to each monitored information byte This is necessary to prevent the same malposition from starting the timer for the suppression time again in the next IL scan A bit is reserved for each group of two in this marker byte The corresponding bit is set as soon as a malposition is recognized When the function block FB1 is called there is a check whether the double point information marker byte is 0 0 means that no bit is set i e no malposition If this is the case or if the timer for the suppression time has expired marker M 1 11 1 the monitored information is restored in the function block FB2 The information byte the KOS output byte and the double point information marker byte are transferred to the function block FB2 The marker byte is reset in the FB and the information byte is transferred to the KOS Lines 1 to 4 were generated directly by PRO gt U120 Lines 5 to 24 were generated using the macro DOPPEL MAC and lines 25 to 33 using the macro T STOER MAC 05 IL Blocks and Macros 135 6 3 6 Program Block 01 BC FB3 02 NAME ZAEHLWER 03 EIN 12 9 04 FLA M2 1 05 OUT QB1 11 06 CNT CNT2 s kkk 07 BC FB3 08 NAME ZAEHLWER 09 EIN 12 10 10 FLA M2 2 11 OUT QB1 13 12 CNT CNT 2 kkk BE Macro file ZAEHL MAC Counter measurands BA FB3 Ex y Mv ABa b ANZ 2 kk PB6 Call counter measurand processing Transfer counter measurand input to FB3 Marker for edge detection
64. arametering program without PRO U120 it can be started directly from the operating system level with the call C PRO U120 KOS201P If the data model is generated by PRO U120 and transferred when the KOS parametering is called the tables data for control direction and data for monitoring direction as well as the general parameters are already filled in The KOS and SEAB parameters are set to the initial values see Chap 2 7 The setpoint values are initialized to 0 and the pulse thresholds for measurands to 255 For monitored information and measurands the code A for set transfer bit is already entered The edge detection for real time information is set so that both edges are transferred as result You can change these default values or make further specifications regarding ring buffer handling if required Of course you can also change the default values of PRO U120 for the KOS parametering Note Keep in mind that changes in the data field for control and monitoring direction QBx 1 QBx 128 IBx 1 IBx 128 must also be taken into consideration in the instruction list No other changes have any effect on the instruction list The changed parameters are stored in the file Uxxx yyy KOS UST No Line number or slot reference if KOS 201 P is started directly XXX yyy Before the KOS main menu appears there is a query whether the KOS parameters should be newly created or whether the old data should be maintained
65. cancelled is reset after expiration of this timer 70 Handling 05 Cancel supervise time E3 B2 Setting range 100 msec to 99 9 sec Standard setting 30 sec As soon as a command with active cancellation is output the timer for the can cel supervise time is also started If the return information does not arrive the command output is reset after expiration of this timer If this case occurs bit 26 in the organization information word is set E L TV aec TO ER L A L E Input of return information TV Cancel link time TU Cancel supervice time A Command output Figure 4 Time diagram for actively cancelled commands Malposition suppression time E3 B2 Setting range 100 msec to 99 9 sec Standard setting 20 sec The transmission of the malposition is suppressed for this time span for double point information If both monitoring information inputs have the same state the timer for the malposition supervision time is started If a further malposition occurs during the timer execution time the timer is reset and started again immediately After expiration of the timer the malposition is transmitted to KOS 201 If the malposition is corrected i e the monitoring information input changes its state the timer is reset The information change is immediately transmitted to KOS 201 05 Handling 71 If several malpositions occur at the same time the timer can only be reset by
66. carried out if the particular data type or function was configured 104 Handling 05 The contents of a program block explained using the information processing for 64 items of monitored information The macro file for information processing is read 8 items of information are processed in one macro The macro is copied to the user memory of the PUTE depending on the number of items of monitored information This is 8 times for 64 items of information The symbolic addresses x y and a b are then replaced with the actual addresses The symbolic address a is replaced with the KOS slot number and the address b with the contents of the KOS output byte counter These counters are incremented by 1 after each allocation The port addresses are found in the file Uxxx 000 HW First monitored information with the supplement index 0 is searched for The search always starts with the first module If a monitored information group is found the symbolic address x y is replaced with the corresponding port address The search is continued until either all the symbolic addresses are replaced or the last module is reached The search begins again with the 1st module once the last module has been reached and not all the symbolic address were replaced This time monitored information with the supplement index 1 is searched for then monitored information with supplement index 2 etc At the end all the addresses are replaced and the block is written t
67. ch arrive during the command runtime are lost Three possibilities exist for processing the above mentioned command types Oo Pulse commands commands whose output time can be parametrized 0 Persistent commands o Actively cancelled commands The type of processing can be assigned to an output group of 8 outputs DAO 216 DAP 216 or by module DAP 204 DAP 208 DAP 212 DAP 292 4 2 11 Pulse Commands The output time can be assigned parameters depending on the output group A timer with the parametrized output time is set and started as soon as a command is output The command output is reset when the timer has expired 4 2 12 Persistent Commands One time for spanning the telegram runtimes is parametrized for each outstation A timer with the parametrized time is set and started as soon as a command is output The command output is reset when the timer has expired In contrast to the pulse commands the timer is repeatedly reset and restarted by sending the same command 05 Configuration 55 4 2 13 Actively Cancelled Command A cancel supervise time and a cancel link time is parametrized for each outstation A command is output until the assigned return information arrives or the cancel supervise time has expired The command is not immediately reset after arrival of the return information but only after expiration of the cancel link time If a command was not cancelled by its return information but was reset after expira
68. ched on and off with lt F6 gt DRU 096 E3 B9 Printer output Printer selection DRU 96 F4 F7 F3 DRU 096 DINA3 Cartridge printer 114 Handling 05 DRU 1200 E3 B9 dem Printer output Printer selection DRU 1200 F4 F7 F4 DRU 1200 DINA4 Laser printer PRT 294 295 d Printer output Printer selection PRT294 295 F4 gt F7 gt F5 PRT 294 DIN A4 Printer PRT 295 DINA3 Printer Near Letter Quality can be switched on and off with lt F5 gt Near Letter Quality E3 B9 Printer output Printer selection Near Letter Quality FA F7 F6 The matrix printers can also be switched to Near Letter Quality mode However the printer output is then somewhat slower 05 Handling 115 Printer output to file E2 B4 h a Printer output Printer output to file F4 D You are asked for the name of the file for the printer output Drive identifier and path commands can be entered The file is opened in APPEND mode so that all output is written into the same file This file is only closed when the printer menu is left If you want to newly create a file with the same name you must first delete the old file in the DOS level because otherwise the output is appended to the end of the file Note All the printer control characters are written into this file Output in a file only makes sense for example if you want to process the datapoint list with another editor You can also use parts of the PRO
69. column price per unit As of position 28 you cannot skip directly to the column price per unit If you want to skip a column press only Cr 100 Handling 05 5 3 Data Archive E1 B1 Read data E2 B2 Data archive Read data F2 F1 All the systems processed so far are listed in alphabetical order in a window The arrow marking the selected system can be shifted with lt sfand lt gt The lines are scrolled at the start and end of the window if more systems exist than can be displayed in the window The selection is confirmed with Cr and the previously processed outstations of this system are then listed The outstations are selected according to the same principle as described above If an outstation selection was confirmed with Cr it is loaded into user memory The windows can always be left with Esc or F9 without a new station being loaded Save data E2 B2 Data archive Save data F2 F2 A station is saved on the drive currently set First a subindex is opened containing the name of the system if it does not yet exist All previously generated files are then saved in this subindex see also Chap 3 3 Several stations can be saved on one diskette 05 Handling 101 Delete file E2 B2 gt Data archive Delete file F2 F3 As for read data all the previously processed systems and then all outstations are listed in a window If the selection of an outstation
70. cro file MESS8 MAC and lines 19 to 26 by the macro file MW_ZAEHL The measurands from the ADU must first be converted in the IL This is done in the FB4 for 8 bit measurands without a sign In order to keep the IL runtime as short as possible only the measurands of one module are converted in one IL scan Marker byte MB2 is used to ask which measurand module should be converted and reloaded In the example there is a skip to the next module between lines 12 and 13 In fact this location contains the networks for the measurands 6 3 6 4 Constant k in the macro is replaced with the reload counter The counter is incremented by one for each new module The variables x y are replaced with the measurand input and variables a b with the KOS slot address and the KOS output byte 138 IL Blocks and Macros 05 The module counter is interrogated in lines 19 to 26 If the last module was converted and restored the counter is again set to zero NULL otherwise it is incremented by 1 The constant k in the macro is replaced with the reload counter of the last mea surand module 6 3 8 Program Block PB8 01 LD MB2 Marker for measurands to be converted 02 E V1 Interrogate 1st ADU 03 BCC FB5 04 NAME QDU205 05 IW IW6 1 Transfer measurand 06 OUT QB1 15 Transfer two KOS output bytes for one 07 CNT CNT2 11 bit measurand kkk Macro file MW11 MAC 11 bit measurands sign L MB2 KK BAB FB 5 EWX y ABa b A
71. de modules which were assigned data points during previous processing are not deleted or overwritten The module which is set in the subrack can be marked for copying with lt Alt gt lt M gt This is displayed with a at the lower edge of the module A marked module including the data point assignment can be copied to the set subrack slot with lt Alt gt lt C gt 05 Handling 81 Survey d Data input Module and subrack assignment Survey FI F5 gt F8 The number of configured data points as well as the assignment of the KOS I O area unused words in monitoring and control directions are displaved in a window Similarly unused digital and analog inputs and outputs are displayed If digital inputs of counter measurand data type were assigned to a group of 8 and a value less than 8 was specified as number these unused digital inputs are marked specially as unused counter measurand inputs The computed load of the 5V and 24V power supply is displayed in a second window which appears when a key is pressed Similarly the maximum load of the 5V power supply defined by the ALU 200 or DNP 205 is displayed If one of the provided mains DNP 220 DNP 260 BAC 224 was configured the maximum load of the 24V power supply is also displayed Note This summary can also be called from the ZOOM menu with lt F8 gt or from the main menu with lt ALT gt lt U gt 82 Handling 05 ZOOM on off E4 B3 ws Data input Module and
72. e i MW 1 set to zero UMSP LD MW 1 Reload measurand in bit string TBW M 4 1 DBB ANZ 16 LBB M 4 8 Load one byte with offset from DBB ANZ 8 bit string and relocate as 8 bit OUT measurand in KOS output byte kkk BE 05 IL Blocks and Macros 177 6 4 12 Function Block NAME ADU206 BEZ EIN IW BEZ OUT B2 BEZ CNT ONT RK L EIN C MW 1 i VO XT NEG LD MW 1 gt V 32000 JF UMSP LD V 32000 MW 1 JI UMSP NEG LD MW 1 lt V 32000 JF UMSP LD V 32000 MW 1 UMSP LD MW 1 TBW OUT DBB CNT 178 IL Blocks and Macros FB13 L R R Load measurand If measurand is negative Call negative value processing Check pos measurand for overrange If no overrange relocate measurand If overrange limit measurand to maximum value Check neg measurand for overrange If no overrange relocate measurand If overrange limit measurand to minimum value Relocate measurand to KOS output bytes B 05 Part IV KOS 201 Parameter assignment The parameter assignment of the KOS 201 with the configuration aid PRO gt U120 or with KOS 201 P ist described in this part 05 179 180 05 Chapter 1 General Information General Information 181 There are two ways to input parameters for the KOS 201 a Input of the KOS 201 data model by the user in the corresponding menues rj Transfer of the data model generated in PRO gt U120 to the KOS 201 parameters If you want to use the KOS p
73. e other However this does not mean that a bus extension cable must be used If you configure a bus extension cable it will be displayed as a connection between the upper and middle subrack The 3rd top hat rail should enable the user to configure additional power supplies or interface relays etc No I O modules may be entered there because the ALU can only address a maximum of 4 subracks with 18 I O slots There is a window with the I O modules the communications processor module and the power supply on the left side of the screen The Helptext for the selected module to the left in the window can be called with lt H gt The individual modules are selected with lt f gt and lt gt the subrack slot is selected with lt gt and lt gt An arrow indicates the current position The set module is entered in the selected subrack slot with Cr A plausibility check whether this entry is valid is carried out If this is not the case a message is output and the entry is not made Furthermore the power load of the 5 V and 24 V power supply is monitored If for example the maximum of 700 mA with which the 5 V power supply of the ALU 200 can be loaded is exceeded the appropriate message is output In this case you can only use the ALU 201 together with the power supply DNP 205 max 2A 80 Handling 05 The module can be deleted from the marked slot with Del Note If you are working in supplement mo
74. ed in Limits The table contains only the measurands for which limits are to be monitored The limits are output sorted according to the slot references of the measurands Note Limits included at a later time in extension mode are not sorted into the table but are appended to the end of the table The order of the virtual events is thus maintained The table has two parts o Information data o SEAB message address o KOS address o Measurand data o Slot reference n Limit a Hysteresis 110 Handling 05 Printout of the data point list E2 B4 Printer output List of Data points F4 7 F4 After calling the data point list printer function vou can specifv the modules for which the data point list should be printed Inputting means that the data point list is printed for all configured modules This is also the initial state after calling the function If you only want to print certain modules enter the slot addresses delimited by commas Printer output begins after Cr The module type is printed as a header The data point list consists of the SEAB telegram address the KOS address the data type the module link slot and the comment edited in the comment data point list menu 05 Handling 111 Oo oO Telegrammaddress oO oO A F At Dn SU SD Bit Slot Data Typ Comment Wiring O Dez Hex Hex 2n o O 03 0
75. emory resident programs or operator interfaces the remaining main memory may not be sufficient for Dolog AKF In this case the functions Read in ASCII IL and Call cannot be executed Leave PRO FWT and remove the call of these programs from the AUTOEXEC BAT or the CONFIG SYS and make a warm restart lt Ctrl gt lt Alt gt lt Del gt Th en start PRO FWT and select Read in ASCII IL or Call again 1 3 1 Read in ASCII With this call the particular AKF reads in a control file generated by PRO Tool AKF12 CMD or AKF25 CMD The AKF station is set up using this control file and the ASCII IL generated by PRO Tool is read in The station which was last processed with a PRO Tool by the function Set up PC Station or Generate ASCII Import Files for AKF is always processed 05 Operating 15 1 3 2 Call Dolog AKF can be started directly by PRO FWT with this call All the Dolog AKF functions can be executed If you only use the standard IL of PRO and have no special IL blocks you can limit yourself to the following function calls ga set up link to PLC oO boot basic software does not apply to ALU 200 a link IL g load IL into RAM of ALU and start or a program IL on EPROM o print out IL The exact instructions can be found in the Dolog AKF A120 A250 user manual A Caution The PRO Tools assume Dolog AKF A120 version 5 0 16 Operating 05 1 4 Tele Tools These tools can be used togeth
76. ent commands were configured lines 11 to 23 are generated by the macro file BEF2 AUS MAC It contains the call for a check for persistent command output If no persistent commands were configured the macro BEF1 AUS MAC is read in and lines 15 to 20 are omitted A command is only output if the output of the command output timer is zero NULL i e any previous command output has been terminated lines 11 to 14 If a command is transferred by the KOS PB14 checks whether it is a persistent command and whether it was already output If this is the case the command output timer is again started Since this is only possible with an edge change at the timer input one must ensure that the input marker was 0 in the last IL scan lines 17 19 and 20 The command output is called in lines 21 to 23 6 3 13 Program Block PB13 01 DA VO 02 IR M1 3 03 M1 7 Reset input marker timer 2 kk link time 04 LD VO 05 TBB Q4 1 Reset outputs 06 DBB ONT 8 E kkk 07 LD VO 08 TBB Q4 9 Reset outputs 09 DBB ONT 8 kkk 10 LD VO 11 TBB Q8 1 Reset outputs 12 DBB CNT 4 kkk BE 146 IL Blocks and Macros 05 Macro file BE1 RSET MAC Reset commands on 4 output modules L KO TBB Ax y DBB ANZ 4 kk Macro file BE2 RSET MAC Reset commands on 16 output modules L KO TBB Ax y DBB ANZ 8 kkk Lines 1 to 3 are generated by PRO 7 U120 The macro BE1_RSET MAC is read in to reset the command output for modules with 4 outputs lin
77. ent cursor position with Alt C The previous line contents are overwritten A line or line block can be copied with Alt C until a new block or new line is marked A mark can be deleted by placing the cursor in front of the block and pressing Alt E gt Note Line blocks can only be marked and only copied within an I O module i e the target module need not be identical with the module in which the block was marked but it cannot be copied past the last port of the target module Correct Copy port 1 1 to 1 4 to port 1 16 Copy port 1 1 to 1 22 to port 2 1 Incorrect Copy port 1 1 to 1 16 to port 1 18 Copy module 1 complete to port 2 10 The copy is aborted as soon as the last port of an I O module is reached during copying 05 Handling 97 Defining Key Macros The keys F1 to F8 can be assigned a text of up to 20 characters in the line editor with lt Ctrl function key After the call an edit field for the macro text appears in the lowest line of the screen The text is assigned to the particular function key with Cr The macros can be redefined at any time with lt Cirl function key Calling Key Macros The particular macro text is entered in the line editor starting with the current cursor position with F1 to F8 Any existing text is overwritten If a macro text cannot be completely stored because the line reaches the end it is truncated 98 Handling 05 5 2 8 Edit Library E3 B8
78. enu is passed to all KOS with the first call of the parameter assignment program You can change this as well as the other parameters as you wish It is also possible to supplement or delete data type assignments in the Data for monitored direction or Data for control direction menues gt Note You must impelement the processing of the 2nd or 3rd KOS in a separate IL part 88 Handling 05 Special remark for equipping command output modules 2 types of modules are provided for command output relay modules with 4 outputs each and semiconductor modules with 2 x 8 outputs each If it should be necessary to drive a combination of 4 output and 8 output modules in one station they should be sorted before entering in the subrack In order to avoid gaps in the commands the relay modules should be entered following the semiconductor modules The 4 outputs are combined when the input bytes of the KOS are assigned and thus in the data model but an 8 output module is not taken apart and stored in different input bytes For reasons of clarity it is recommended that cancelled command output on semiconductor modules and the associated return information modules be adjacently equipped lO D D 4 ma DAP DAP DAP DEP DAP DEP DAP DAP DAP DAP 204 216 216 216 212 2 PUCOCACOPUCO SPIR CACO SPIR CACO PUCO CACO PUCO 4 8 8 8 4 8 8 8 4 4 CACOPUCO SPIR SPI SPIR CACQPUCO SPI 8 8 8 8 8 8 8 8
79. er with special PC plug in cards to simulate master stations and outstations Teleview For Modnet 1F 1N together with PC V24 PC GDUE PC WT TELOO1 For Modnet 1F 1N and AWD together with PC AWD1 TELO02 For Modnet 1W together with PC AWD1 05 Operating 17 1 5 Desktop Language You can switch directly between German and English Screen PRO FWT can run as required in graphic mode or in text mode with an EGA or VGA card For all other screen adaptors there is an automatic switch to text mo de and this setting cannot be changed In graphic mode you can also define whether PRO FWT should work with icons or only with pulldown menues You can choose one of three color representations both in graphic and in text mode For clarity you should choose two tone representation for some PCs The pulldown menues have a light background for black and white and a dark background for inverse black and white Version numbers The current data part number version date are entered in a version file when the individual PRO tools are installed The file is displayed on the screen with this function The display is in a scroll box i e it can be shifted up down with the cursor or by clicking the cursor fields with the mouse cursor 18 Operating 05 AKF Program Path In order to be able to work with different AKF versions the program path of the required AKF12 and AKF25 version can be entered here The default entries used by
80. es 10 to 12 Since commands for modules with 16 outputs can be assigned bytewise they are also reset bytewise Macro BE2_RSET MAC is read in for this purpose lines 4 to 9 05 IL Blocks and Macros 147 6 3 14 Program Block PB14 Check for 1 pole command output 01 LD VO 02 TBB M4 1 03 DBB ONT 8 Ark 04 BC FB8 05 NAME DAUERBE 06 INPU IB1 001 Check KOS input byte for 07 MERK M1 2 08 AUS Q4 1 agreement with 8 outputs 09 CNT CNT8 of an output module s kkk 10 BC FB8 11 NAME DAUERBE 12 INPU IB1 002 Transfer KOS input byte 13 MERK M1 2 M 1 2 means 1st to 4th bits in IB 14 AUS Q5 1 are compared with 4 outputs 15 CNT CNT 4 kkk 16 BC FB8 17 NAME DAUERBE 18 INPU IB1 002 Transfer KOS input byte 19 MERK M1 1 M 1 1 means 5th to 8th bits in IB 20 AUS Q6 1 are compared with 4 outputs 21 CNT CNT 4 s kkk BE Macro file DAUERBEF MAC Check whether persistent command should still be output BA FB8 EBe b M1 m AX V ANZ z Jk 148 IL Blocks and Macros 05 Each input byte of the KOS in which persistent commands are transferred is compared with the corresponding outputs This is done in function block FB8 Since only half a byte is compared in 4 output modules an additonal marker which shows whether the 1st to 4th or 5th to 8th bits are meant must be transferred to the function block The 5th to 8th bits are shifted right by 4 positions in the function block Th
81. es and Subrack F5 B Assignment 5 Special Processing F6 of Data Points m B6 Figure 1 i A F7 Data Input FI List of Data Points m B7 B F Data Archive Edit Library B8 Generation of IL F3 Figure 2 and Transfer F4 ne Data i ave Data Printer Output Delete File x x Change Drive Display the Bill of F6 Materials on the Screen Figure 3 Start IL Generation GE witch Niencehrame ecler Start IL Generation EN Create PC Station and Return to PRO FWT Copy ASCII IL Main Menu Figure 4 Printer Output Selection of Printers F9 B9 Printer Output to File Figure 6 Output Overview How To Work 41 Level 3 Level 4 Level 5 Figure 1 BI Input B2 Figure 2 B3 s B4 Input Figure 1 B5 Figure 3 Input Presetting B6 Data Point Input pi ure i Input B7 Figure 4 p Select B8 4 Figure 3 Figure 5 Input of Data Points Module Selection F1 5 Data Point Allocation KOS parametering BI Figure 6 Measurand Processin Input Two Position Controller Three Pos Controller Pulse Width Modulato Input BI Figure 7 Input Input Figure 8 Input Input Figure 9 Select 42 Overview How To Work Level 5 Figure 1 B1 05 Configure parameter lists Archive Transfer Printer output EPROM
82. esetting o Data point input PRO U120 determines the required number of subracks and I O modules us ing the input and preset data PRO U120 makes an equipment suggestion which you can change in the menues subrack select and module select Note t is recommended that you take this sequence of suggestions into consideration in the initial system concept and then not change it 05 Handling 75 Presetting E4B1 lan Data input Number of data points Presetting F1 F8 F1 Note You can display Helptext about all interrogations in this menu by selecting the corresponding line or setting and calling the Helptext with lt F10 gt Central processing unit You can toggle the ALU types ALU 200 and ALU 201 If ALU 201 is set the power supply DNP 205 is automatically taken into consideration in the slot assignment Output voltage You can toggle between 24 V and 60 V peripheral voltage If the peripheral voltage is 60 V the commands are automatically output to the relay module DAP 212 Note The display for Output via relay cannot be changed if there is 60V peripheral voltage Additional Power Supply If a 24 V input power supply is not available you can include additional power supplies PRO U120 provides the following three modules DNP 220 DNP 260 BAC 224 The setting is made by toggling 76 Handling 05 Output with relays You can choose whether or not commands should be output via relays f
83. f block instruction BE is always appended automatically after the last network by PRO U120 are the network separators 01 A EB3 1 Was control command sent by 2nd KOS 02 A V1 03 JF LAB1 04 A V1 If yes set switching flag to 1 05 M 1 14 06 LAB1 A EB2 1 Was control command sent by 1st KOS 07 A V1 08 JF LAB2 09 A VO If yes reset switching flag 10 M1 14 11 LAB2 UN M1 14 Call copy commands and setpoint values 12 BCC PB17 EBs from 1st KOS 13 A M1 14 Call copy commands and setpoint values 14 BCC PBI18 EBs from 2nd KOS 15 BC PB1 Call module check 16 BC PB2 Call process monitoirng direction 17 BC PB3 Call process control direction 18 BC PB19 Call copy ABs for 2nd KOS BE o Lines 1 14 and 18 are only generated if the IL was generated for 2 KOS modules g Line 15 is always generated o Line 16 is only generated if data was configured in monitoring direction o Line 17 is only generated if data was configured in control direction 05 IL Blocks and Macros 125 6 3 6 3 1 01 02 03 04 05 06 07 08 09 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 LAB The program blocks Note The end of block instruction BE is always appended automatically after the last network by PRO U120 are the network separators Program Block PB1 uA VO Set marker 1 to zero Ge M1 1 A V1 Set marker 2 to one MES M1 2 x kkk DA VO Set first byte of
84. g diskettes into disk drive O Always keep in mind on xiv 20 Table of Contents Part I Chapter 1 1 1 1 2 1 3 Part Il Chapter 1 1 1 1 2 1 3 1 3 1 1 3 2 1 4 1 5 Part Ill Chapter 1 1 1 1 2 1 2 1 1 2 2 1 3 1 4 1 4 1 1 4 2 1 5 05 How to proceed 1 Check List ener eurem REEL 3 Check list configuration 2 222222 aranaren 4 Check list parametering and programming 5 Check list system start up 22222222 7 Main Menu PRO FWT 9 Operating sis e 11 General Information 000 ellus 12 Expert system PRO LL 14 Dolog AKF iod xv ERR 15 HeadimASCIl rl 442 SAPE xg Ph s 15 Gallien ae ad celal een nenne ale la 16 Tele Tools oci en tea en an 17 Desktop 4 anp ra eat 18 Configuration Instructions 21 Introduction sse 23 Program package PRO U120 24 System requirements 000 00 25 Hardware i 2 2 niei er iva sera bea EI d 26 Software x oi due aueh ee eo Re ke a eae 26 Installation xm een en e i E Ss 27 New Features scio 200 4220 pe Band 28 Compared to PRO U120 V 4 0 05 28 Compared to PRO U120 V 5 0 005 29 Update Version usse su pie cece pag mfi Gd 30 Table of Contents XV xvi Chapter 2 2 1 2 2 2 3 2 4 2 5 Chapter 3 3 1 3 2 3 3 Chapter 4 4 1 4 2 4 2 1 4 2 2 4 2 3 4 2 4 4 2 5 4
85. gt U120 documentation in other documentation systems Note The individual IL blocks are not printed with PRO U120 The IL as generated by PRO U120 has a special format and contains control characters which are eliminated again when read into Dolog AKF A120 For this reason the IL blocks should be printed in Dolog AKF A120 using the corresponding functions 116 Handling 05 5 6 Display Bill of Materials on the Screen E1 B1 This function can give you a fast overview of the scope and price of a planned outstation In order to determine the prices the price per item for the individual components must be entered in the menu change library You can work with different library files After entering this menu a window in which all the existing libraries are listed alphabetically appears The arrow marking the selected library can be shifted with lt T gt and al gt The lines are scrolled at the start and end of the window if more libraries exist than can be displayed in the window The bill of materials is set up from the configured modules and subracks Furthermore all the library positions for which a number of pieces was entered are included If a bill of materials was already made for an outstation there is a query whether this should be displayed or whether a new bill of materials should be created A Caution If a new bill of materials is to be created remember that the current settings of the supplementary
86. hinged side flush to the bottom Step3 Press the lever downwards Now that the adaptor is inserted you can place the EPROM in the adaptor 208 Handling 05 Figure 11 Insert Adaptor ADP 004 Step4 Open the adaptor ADP 004 Press the opener upwards and lift the cover see also Figure 12 Step5 Insert the EPROM in the adaptor see also Figure 12 3 The long contact strip on the underside of the EPROMs must be adjacent to the marking in the adaptor Step6 Close the adaptor The EPROM is now inserted and ready for the tranmission 05 Handling 209 lower side Figure 12 Insert EPROM 27C256 SMD in the Adaptor 210 Handling upper side 05 2 6 1 2 Removal of the EPROMs To remove the EPROMs you must take the following steps Warning The EPROM may not be removed as long as the LED on the EPS 2000 is blinking Step 1 Open the adaptor ADP 004 Step2 Remove the EPROM from the adaptor Step3 Close the adaptor ADP 004 Step4 Turn the lever of the Textool socket upwards Step5 Remove the adaptor 2 6 2 KOS Firmware and Parameter EPROM The firmware and parameter EPROM are programmed with this menu Only the EPROM programming station EPS 2000 can be used The connection is made with the serial interface COM The different firmware versions are supplied on diskette in the form of INTEL HEX files You can decide with which firmware the KOS should be
87. ibrary and the firmware file The files set up by PRO U120 are stored as follows c TEST PRO FW U001 000 HW U001 000 DPL U001 000 DPT U001 000 EST U001 000 RT1 U001 000 RT2 U001 000 RT3 UOO1 REG AWL IL for control block U001 000 AWL U001 000 EX U001 000 MES U001 001 KOM U005 002 KOM U001 001 KOS U005 002 KOS AWD names are defined by the user EXAMPLE PRO 44 Overview How To Work FW U122 000 HW 05 Explanations about Uxxx yyy HW etc XXX Master station no 000 126 yyy Line number 001 999 The number 000 is used for files which contain the data for the whole master station and which are not assigned to a certain line The names of the system directory and the outstation numbers are entered in the configuration data menu see chapter 5 2 1 The line numbers are entered in the ZOOM function 05 Overview How To Work 45 46 Overview How To Work 05 Chapter 4 Configuration Configuration 47 4 1 Definitions of the Communication Ports The outstastion is linked to the master station with the KOS 201 It is the link between the ALU 200 201 and the serial bus SEAB 1F The KOS 201 is treated like an I O module 128 bytes are provided in each direction for communications with the ALU 200 Output byte QB x 1 QB x 128 transports data from the ALU 200 201 to the KOS 201 monitoring direction Input byte IB x 1 IB x 128 transports data from the KO
88. ing U120 in Different Configurations 600 Baud 1 200 Baud S2 Lead time 15 T 30 T S2 Trailer tim 4T 4T S2 Pause time 16 T 26 T Quit LT 60 T 84 T M5 Lead time 20T 35T M5 Trailer time 20T 30 T Caution f the standard values are to be changed data loss can occur if the parameters are not suitable for the system 05 Handling 187 2 2 3 KOS Parameters for SEAB 1F E7 B3 md Configure parameter lists KOS parameters F1 gt F3 o The deviation time integral AZI for 8 bit measurands and 11 bit measurands in the range from 1 16000 is specified The standard setting is 5000 o There is a query after how many event entries a buffer overflow warning should be output A maximum of 4095 8192 events can be entered in the ring buffer Standard setting 3072 The quantity of the ring buffer depends on the firmware version and the hardware FWM 001 275 125 KOS 201 202 4K RB FWM 002 275 126 KOS 201 202 4K RB FWM 007 261 541 KOS 202 8K RB FWM 008 261 542 KOS 202 8K RB Standard setting is 3072 in relation to the 4k RB version o One can specify whether reading the ring buffer should be activated after short polling KA or only after general polling GA Standard setting KA Setting with the keys J and N or by toggling o One can choose between two analog value scalings A range from 0 2047 is set standardly but can be switched to 0 2000 This scaling factor is valid for the analog setpoint values and the
89. ing on the parameter assignment A 1 at the input cancels the assigned command 50 Configuration 05 4 2 4 Real Time Information Configurable at DEO 216 DEP 208 DEP 216 DEP 296 DEP 297 DAP 212 DAP 220 DAP 292 Allocation In groups of 8 inputs each Processing The real time information is transmitted to the KOS 201 like normal information It is stamped there with the time and stored in the ring buffer 4 2 5 System Information Configurable at Cannot be configured virtual information Allocation Is always assigned to the 1st word in the monitor direction and has the subaddress A1 byte O Processing The system information contains the following information Module disturbed 1 18 binary coded bit 20 to 24 More than one module failed bit 29 1 No return information for last actively cancelled command bit 26 1 gt Note You can also transmit the faulty or disturbed modules n of 18 coded to two further system information telegrams This system information has the subaddress 1 slots 1 to 16 and subaddress 2 slots 17 and 18 This information is configured in the menu General Outstation Data 05 Configuration 51 4 2 6 Counted Measurands Configurable at Allocation Processing DEO 216 DEP 208 DEP 216 DEP 296 DEP 297 DAP 212 DAP 220 DAP 292 In groups of 8 inputs each The number of inputs actually required is also specified The counter measurands are formed in the IL Counter pulses of
90. ion can be selected o Main connection Extension T1 without exchange call Extension T2 7 exchange call with O Extension T3 7 exchange call with O wait Extension T4 7 exchange call with groundkey Extension T5 7 exchange call with groundkey wait 000000 Extension T1 is only possible if the master station and the outstation are connected to the same extension network For extensions T3 and T5 the postal modem does not wait for the dial tone for the exchange call but continues dialing after a defined waiting time 198 Handling 05 Since the outstation and the master station can have different dialing methods and connection types they can be set separately Receiving delay time You can set the length of time for which the call acceptance should be delayed separately for the outstation and the master station Times between 0 and 30 seconds can be defined Number of dialing attempts You can set how often the outstation should repeat dialing if no connection is made 0 255 repetitions are possible Repeat dialing attempt after how many minutes You can also define the intervals at which these repetitions should occur Settings from 0 to 255 minutes are possible At failure try 2 call number for master If the outstation cannot make a connection with the 1st number of the master station the connection is attempted again with the 2nd number Break after short messages 0 The master station tells the APS driver with a
91. ion should really be carried out A confirmation with lt J gt starts the transfer Once the transfer has ended the KOS firmware part number including the modification index is displayed Parameter List to KOS Transfer Parameter lists to KOS F3 gt F2 Before the data are transferred from the PUTE to the KOS there is another query whether this function should really be carried out A confirmation with lt J gt starts the transfer During the transfer no data are accepted in the data model and in the ring buffer of the KOS The current date is passed to the parameter RAM of the KOS during the data transport In this way you can always determine the last time that the data were transferred to the KOS RAM A comment on the screen shows whether the data transfer is still running or whether it is terminated The corresponding message appears on the screen if there is an error 05 Handling 203 Scan IL Cycle time en Transfer Scan IL Cycle time F3 7 F3 This KOS firmware determines the current IL cycle time It also notes the longest IL cycle since the start of the outstation These two cycle times can be interrogated and displayed online 204 Handling 05 2 5 Printer Output E6 B4 The printer output is used to list the input parameters The output is made in DIN AA format The following lists can be printed m Printer output Common parameters F4 FI Printer output Data Model Monitoring D
92. irection F1 gt F4 F2 The data type and group number are selected and entered exactly as for data for monitoring direction 192 Handling 05 The following data types are processed Single commands Digital setpoint values Analog setpoint values Organization commands oO 256 o 16 o 32 g 16 max 16 words max 16 words max 32 words max 1 word A total of only 64 words can be transmitted If the KOS clock time is transmitted to the PLC this is done with the last 4 words or 8 bytes EBx 121 EBx 122 EBx 123 EBx 124 EBx 125 EBx 126 EBx 127 EBx 128 Year Month Weekday Day Hour Minute Special character Second The entry is in BCD code If the clock time in the KOS was set by a clock message by the master station bytes 123 and 127 are set to 0 since the message does not contain any information for them If the time in the KOS is set by the DCF receiver these bytes are defined as follows Byte 123 05 etc Monday Tuesday Handling 193 Definition of the special characters for byte 127 1st bit Switch to reserve antenna 2nd bit Notification of ST WT switchover is set 1 hour before switchover 3rd bit Summer time 4th bit Winter time 5th bit Switchover second 6th bit Start bit for time information Setpoint default value E8 B3 gt Configure parameter lists Assignment lists Setpoint default value F1 F4 F3 If setpoi
93. irection control Direction F4 gt F2 Print tput Default Set Point Value m rinter output Default Set Point Value F4 gt F3 E Printer output Counter Measurand Processing F4 gt F4 Print tput Ring Buffer Handling m rinter output Ring Buffer Handling F4 F5 e db Printer output Automatic Polling Service F4 F6 Printer output All Lists F4 gt F7 05 Handling 205 Selection of Printer E7B6 an Printer output Selection of Printer F4 gt F8 One can select one of the printers DRU 096 DRU 120 DRU 292 DRU 293 DRU 1200 PRT 294 and PRT 295 Near Letter Quality NLQ can be set with F5 for DRU 120 DRU 292 DRU 293 PRT 294 and PRT 295 Note The printers must bed set to IBM graphic character set 2 If the printer is not ready the corresponding output appears on the screen The printer output uses the Centronics interface LPT1 An output to the serial interface is not advisable since this is already used for the connection to the operating interface of the ALU the EPROM programming device and the mouse CP Expert If you want to use a printer with serial interface nevertheless you can change the output to the COM1 or COM2 using the MODE commands in the DOS level before starting the KOS parametering You can find the necessary commands in the DOS manual 206 Handling 05 Printer Output to File E6 B4 a Printer Output Printer Output to File F4 D
94. is permits a direct comparison with the outputs The shift is carried out by transferring the marker 1 1 is always set to O lines 16 to 21 If the first half byte or a whole byte are to be checked marker 1 2 is transferred lines 4 to 15 Check for 2 pole command output 01 LD VO 02 TBB M41 Set marker string from M4 1 to 4 8 03 DBB ONT 8 to NULL zero kkk 04 DA Q2 1 Save 1st command output 05 M4 1 to marker 4 1 06 DA Q2 3 Save 2nd command output 07 e M4 2 to marker 4 2 08 BC FB8 09 NAME DAUERBE 10 INPU IB1 1 11 MERK M1 2 12 AUS M4 1 13 CNT CNT 8 i kkk 14 DA Q3 1 Save 8rd command output 15 x M4 3 to marker 4 3 16 DA Q3 3 Save 4th command output 17 pE M4 4 to marker 4 4 18 BC FB8 19 NAME DAUERBE 20 INPU IB1 1 21 MERK M1 2 22 AUS M4 1 23 CNT CNT 8 b kkk BE 05 IL Blocks and Macros 149 Macro file DAUERBE1 MAC Check wether persistent commands should stll be output 2 pole DAP 208 L K 0 TBB M 4 1 DBB ANZ 8 U A x y z M AZ U A x y M 4 z U Ax y M 4 z U Ax y M 4 z BA FB8 EB e b M1 2 M4 1 ANZ 8 kkk Macro file DAUERBE2 MAC Check whether persistent command should still be output 2 pole DAP 204 U Ax y u M4 z U Ax y M4 z BA FB8 EBe b M1 2 M4 1 ANZ 8 xk If 2 pole command output was configured the macro file DAUERBE2 MAC is read in for the check for a persistent command for the 4 output modules DAP 204 and DAP 212
95. iver Part Ill 74 Delay time for persistent commands Part Ill 73 F Funciton block FB1 Part Ill 165 FB4 Part Ill 170 Function block FB10 Part Ill 175 FB11 Part Ill 175 FB2 Part Ill 169 FB3 Part Ill 169 FB5 Part Ill 171 FB7 Part Ill 173 FB8 Part Ill 174 Index 229 G Geadat VEN Part Ill 85 Generation of IL and Transfer Part III 103 107 I I O module select Part III 80 89 IL blocks Part Ill 121 K Keyboard table Alt A Part Ill 97 Alt C Part Ill 81 97 Alt E Part Ill 97 Alt G Part Ill 103 Alt K Part IIl 87 Alt M Part Ill 81 97 Alt U Part Ill 82 KOS System marker Part III 123 L Level Figure E1 B1 Part Ill 101 103 108 117 E2 B1 Part Ill 75 79 80 E2 B2 Part Ill 101 102 E2 B3 Part Ill 101 107 E2 BA Part Ill 108 111 112 113 116 E2 B5 Part Ill 103 E3 B2 Part Ill 70 71 73 75 E3 B3 Part Ill 77 E3 B4 Part Ill 79 E3 B5 Part Ill 80 E3 B6 Part Ill 90 95 E3 B7 Part Ill 96 E3 B8 Part Ill 99 E3 B9 Part Ill 114 115 E4 B1 Part Ill 76 E4 B2 Part Ill 77 E4 B3 Part Ill 83 E4 B5 Part III 93 E4 B6 Part Ill 93 E4 B7 Part Ill 94 Level figure 230 Index EO B1 E1 B1 Part Ill 65 Part IIl 67 69 E2 B1 Part Ill 67 E3 B1 Part Ill 67 E3 B3 Part Ill 70 Level Image Ex By Part Ill 38 Level image E3 B2 Part Ill 71 Library Part Ill 99 118 Limits Part Ill 59 M Malposition suppression time Part Ill 49 71 Modification of data points Part III 67 Module f
96. k for 2 pole command output 01 BC FB10 02 NAME P ABEF 03 AUSG Q9 1 one command output 04 CNT1 CNT 1 05 EING 19 1 is compared with the 06 CNT2 CNT 1 corresponding return information kkk 07 BC FB10 08 NAME P ABEF 09 AUSG Q9 3 one command output 10 CNT1 CNT 1 11 EING 19 2 is compared with the 12 CNT2 ONT 1 corresponding return information kk BE The basis of the cancellation check is the macro file P ABEF MAC also for 2 pole command output However since the 1st and 2nd as well as the 3rd and 4th outputs always form one command in the 4 output modules a 1 1 compari son with the inputs is no longer possible For this reason only one output is compared with one input per network whereby the number of networks is doubled 6 3 16 Program Block PB16 1 pole command output 01 DA IB 1 1 Check if one of the commands 02 DA VH OF 1 4 is set 03 MES VO 04 JT LAB 05 LD IB 1 1 If yes output to first 06 TBB Q2 1 4 output module 07 DBB ONT 4 08 LD VOS Write command output time in timer 09 nE TSW 1 setpoint value 10 LAB 11 DA IB 1 1 Check if one of the commands 12 DA KHFO 5 8is set 05 IL Blocks and Macros 153 13 VO 14 JT LAB 15 LD IB1 1 16 TBB M4 1 17 DBB CNT 8 18 LBB M4 5 19 DBB CNT4 20 TBB Q3 1 21 DBB CNT4 22 LD V300 23 tie TSW1 24 DA V1 25 M1 3 26 LAB fi 27 LD IB1 2 28 tx VO 29 JT LAB 30 LD IB1 2 31 TBB Q4 1 32 D
97. l Dolog AKF A120 Part lI Chap 1 3 2 oO Program the programmable controller online or o Generate a PC EPROM Note At the first startup of an ALU 201 the basic software have to be loaded to the ALU 6 Check List 05 1 3 Check list system start up o Insert the KOS firmware and parameter EPROM Oo Insert the ALU EPROM or the EPROM module rj Check whether the switches or jumpers of the individual modules are set cor rectly g Insert and wire modules The KOS and the ALU can also be parametered or programmed online with the PADT The KOS must in any case be equipped with the firmware EPROM Further information about system start up can be found in the Geadat 120 user manual 05 Check List 7 8 Check List 05 Part Il 7 Main Menu PRO FWT 10 05 Chapter 1 Operating Operating 11 1 1 General Information The PRO FWT main menu enables you to choose individual software packages required for starting up a Geadat telecontrol station without having to return to the DOS level Note Of course only the software packages which were installed can be called Note This main menu is always installed with the individual softwa re packages PRO It is started from the operating system level with the call PRO FWT 12 Operating 05 Operation You can select one of two kinds of operator interface a Pulldown menues Oo Icons The interface can be set with the Desktop Both in
98. l gt or 1 The marked file in the user memory is read in with Cr The function is aborted with F9 or Esc EPROM Blank Check Wb a EPROM menu EPROM Blank Check F5 gt F6 The function EPROM Blank Check can be used to check whether the EPROM to be programmed is empty Before each access to the EPROM there is a check whether it was correctly inserted If this is not the case the corresponding comment appears on the Screen An EPROM is read in or programmed in steps of 256 bytes The processed range is displayed on the screen Only an empty range can be programmed 05 Handling 213 2 7 Reset of PADT Memory E5 B1 After calling Reset of PADT memory there is another query whether you are sure that this function should be carried out If this is confirmed all the data are deleted and the standard parameter values are set Standard parameters SEAB version Outstation number Baudrate Lead time Trailer time Pause time Quit LT M5 lead time M5 trailer time DTI for MW8 DTI for MW11 Ring Buffer overflow warning at Read ring buffer only after GA DCF receiver SEAB 1F telegrams with 4 data bytes Start conditions Analog value scaling Transfer time and date to IL 214 Handling SEAB 1F 0 600 Bd 5 tBit 5 tBit 5 tBit 60 tBit 12 tBit 12 tBit 5000 5000 3072 no no yes Hot restart 0 2047 yes 05 2 8 Bottom Up Configuration Export E6B6 m
99. l time information 256 Bit Counter measurands 63 Word Measurand 8 Bit 64 Byte Measurand 11 Bit 63 Word Organization information 48 Bit 1 pole 2 pole commands 256 128 Bit Digital setpoint values 16 Word Analog setpoint values 32 Word The specified numbers are single limits The total limits result from the sytem limits such as the capacity of the communications port EB AB each 128 bytes and the equipment conditions 05 Configuration 59 4 4 Special Features 60 The KOS 201 can only be used in the central subrack Clock antenna DCF77E can only be used for KOS 201 Gaps can occur in the module addressing if a bus extension cable is used Only DTA 201 can be used as a secondary backplane if a bus extension cable is used Use for measurand processing ALU 201 or backup battery control gear PRO U120 does not support the measuring range spread set with a control byte and the setting of unipolar measurands possible with the ADU 206 The name KOS 201 refers to the mode resp ident code of the KOS KOS 201 ID Code 90 128 I O bvtes However you can also use the KOS 202 as hardware With the FWM 007 008 you have to use the KOS 202 as hardware a variant with 8 kB ring buffer store Configuration 05 Chapter 5 Handling Configurating parametering and programming with PRO U120 is described in this chapter This chapter is a reference manual for the person configuring Its structure corresponds to that of the men
100. ll the data you can specify separately for general outstation data and balance of current whether these should be printed Only input of J for the particular query results in a printout of the data Printout of the control blocks E2 B4 e Printer output Control blocks A list of the configured parameters preset by PRO gt U120 is printed for each control block Printout of all lists E2 B4 Printer output All lists F4 F6 aw All the lists which exist are printed Printer selection E2 B4 A printer output is only possible using the parallel standard interface LPT1 with PRO U120 Output using the serial interface is not recommended since this is already used for the link to the PLC the EPROM programming panel and the mouse 05 Handling 113 NO Expert If you want to use the printer with a serial interface nevertheless you can direct the output in the MS DOS level using MODE commands before PRO U120 is started The necessary commands can be found in the DOS manual gt Note IBM character set I must be set in the printers DRU 292 293 E3 B9 b Printer output Printer selection DRU 292P 293P FA F7 FI DRU 292 DIN A4 Matrix printer DRU 293 DIN A3 Matrix printer Near Letter Quality NLQ can be switched on and off with lt F6 gt DRU 120 E3 B9 Printer output Printer selection DRU 120P FA F7 F2 DRU 120 DIN A4 Matrix printer Near Letter Quality can be swit
101. lot 1 gt LINIE_1 and LINIE_2 Slot 2 gt LINIE_3 and LINIE_4 Slot 3 Exe LINIE 5 and LINIE 6 etc The Z300M reads the AWD files from diskette with a load function This assumes that the file are available on one diskette for each master station The user must carry out the copy process required here himself in the DOS level Example COPY C ANLAGE PRO FW LINIE_1 AWD A see also Chapter 3 3 Part III 05 Handling 197 Handling First press Cr to activate the line editor for the input fields The input is also terminated with Cr The input and toggle fields are selected with the cursor keys The file selection window is called with F1 when the cursor is in the file field of the master stations You can switch between master stations 1 2 and 3 4 with F2 Password The password comprises max 15 characters letters digits or special charcters The slash is not permitted Capital letters are distinguished from small letters The password is valid for the outstation and the master station Calling number The calling number of the outstations and the master station has a maximum of 15 digits The area code and calling number are entered without a gap A calling number for the second master station is not required However at least one of the master stations 1 or 2 must be configured Dial Mode You can choose pulse selection or tone selection by toggling Connection Mode 6 different types of connect
102. lposition If there is a malposition same state at both inputs the transfer to the KOS 201 is suppressed for a certain length of time This time can be parametered per outstation see also Chap 5 2 2 05 Configuration 49 Note Inputs which are not used should be assigned alternately 0 V and 24 V as otherwise malpositions are constantly recognized 4 2 3 Return Information Configurable at DEO 216 DEP 208 DEP 216 DEP 296 DEP 297 DAP 212 DAP 220 DAP 292 Allocation In groups of 8 inputs each The first parametered return information counted starting with slot 1 is allocated to the 1st cancelled command etc For reasons of clarity input and output modules with return information and cancelled commands should be inserted next to each other but this is not absolutely necessary see Chap 4 2 13 Figure 3 Note The assignment is made by entering lt R gt and data type selection single point information or double point information DEP 208 DEP 216 DEP 296 DEP 297 For a DAP 212 DAP220 or DAP 292 the inputs are automatically interpreted as return information if the outputs are parametered as cancelled commands Of course these inputs may not be assigned parameters as counter measurands in this case The inputs of a DAP 212 DAP220 or DAP 292 cannot be used as return information for other output groups Processing Return information is treated as single point informations or double point information depend
103. mation PB5 Process double point information PB6 Process counter measurand PB7 Process 8 bit measurands PB8 Process 11 bit mesurands PB9 Limit monitoring PB10 Process digital setpoint values PB11 Process analog setpoint values PB12 Check commands 1 of n PB13 Reset command PB14 Check persistent command PB15 Check command for cancel PB16 Command output PB17 Copy EBs from 1st KOS to output marker PB18 Copy EBs from 2nd KOS to output marker PB19 Copy data in monitoring direction PB20 Call control blocks PB21 Call extreme value computation PB22 Standardize extreme values FB1 Check double point information for malposition FB2 Store double point information on KOS FB3 Process counter measurand FB4 Process 8 bit measurand FB5 Process 11 bit measurand FB6 not used FB7 1 of n check for commands FB8 Output persistent command FB9 not used FB10 Check commands for cancellation FB11 Limit monitoring FB12 8 bit measurands ADU 206 FB13 11 bit measurands ADU 206 FB14 FB15 Two position controller FB16 Three position controller FB17 Pulse width modulator 05 IL Blocks and Macros 121 6 1 2 List of the Markers Used Marker Explanation M1 1 set to 0 M1 2 set to 1 M1 3 1 cancelled command running 0 pulse command or persistent command running M1 4 1 start timer command output time M1 5 1 output timer command output time M1 6 Edge detection for command output M1 7 1 start timer link ti
104. mation with malposition suppression Kk MBO 4 BA FB1 Ex y ANZ 8 MBm MB 0 4 L MBm K 0 M1 13 UN M1 11 U M1 12 O M1 13 BAB FB2 Ex y ANZ 8 ABa b MBm seek Macro file T STOER MAC Timer for malposition suppression U M1 11 M1 12 U M1 9 SA T3 DZB 100MS L Kt A M1 10 R T3 M1 11 E BE 134 IL Blocks and Macros The markers which start or stop the malposition timer are reset in lines 1 to 4 If a malposition is recognized marker M 1 9 is set to 1 and thus starts the timer in the last network If the malposition no longer exists the marker M 1 10 is set to 1 and thus stops the timer in the last network If the timer expired or stopped the monitored information is transferred to the KOS Each byte contains 4 x 2 items of monitored information which are checked for malposition Each group of two has a code from 0 to n The code for the first group within the monitored information byte is passed to the function block The first monitored information byte contains the groups 0 1 2 and 3 so that a 0 is transferred The second monitored information byte contains the groups 4 to 8 so that the 4 is transferred etc The code is necessary to find out which malposition last started the timer because the timer may only be reset when this malposition no longer exists In order to find out whether a malposition was already recognized there is a double point information marker byte p
105. me M1 8 Output timer link time M1 9 1 start timer malposition suppresion M1 10 1 reset timer malposition suppression M1 11 Output timer malposition suppression M1 12 Edge detection output malposition timer M1 13 Intermediate marker for double point information processing M1 14 Switching flag for 2KOS operation M2 1 to M3 32 Edge detection measurands M4 1 to M4 8 Intermediate marker for double point information check Select commands and 8 bit measurands Controller If controllers are parametered PRO U120 reserves for each two or three position controller an additional marker starting with marker 5 1 4 additional markers are required per pulse width modulator MB1 MB2 MB3 MB4 MB5 MB6 MB7 to MB40 Bit counter for 1 of n check intermediate store for persistent commands Measurand processing pointer Intermediate marker auxiliary byte Marker for last double point information with malposition Marker for 34 double point information byte malposition MB43 MB168 Output bytes into which the EBs from 3 128 are copied MW1 MW2 MW3 MWA MW10 and MW11 MD1 and MD2 Transfer word right justified measurand controller Transfer word limit controller Transfer word hysterese value controller Controller Controller Pulse width modulator 122 IL Blocks and Macros 05 Timer 1 Timer 2 Timer 3 If two or three position controllers are parametered one additional timer is needed for Comma
106. n and set up program block PB1 Step5 Set up program blocks PB2 for processing monitored direction Step 6 Set up program blocks PB3 for processing control direction read in timer macros Step 7 Read macro for monitored information and real time information processing and set up program block PB4 Step 8 Read macro for double point information processing and set up program block PB5 05 Handling 103 Step 9 Step 10 Step 11 Step 12 Step 13 Step 14 Step 15 Step 16 Step 17 Step 18 Step 19 Step 20 Read macro for counter measurand processing and set up program block PB6 Read macro for 8 bit measurand processing and set up program block PB7 Read macro for 11 bit measurand and set up program block PB8 Read macro for limit monitoring of measurands and set up program block PB9 Read macros for command output and set up program block PB16 Read macros for 1 of n check of the commands and conditional command output and set up program block PB12 Read macros for reset command output and set up program block PB13 Read macro for persistent command output and set up program block PB14 Read macro for command cancellation and set up program block PB15 Read macro for digital setpoint value output and set up program block PB10 Read macro for analog setpoint value output and set up program block PB11 Read file with Control IL and append to file USTx AWL Steps 5 to 20 are of course only
107. nd and limit 05 IL Blocks and Macros 175 D GREN JF LAB1 SA MELD 0 BIT m MELD SP ENDE LAB1 DA MW1 Br HYST JF ENDE DA BIT x VHFF ne BIT DA MELD A BIT 3 MELD SP ENDE U GR A MW1 I lt GREN JF LAB2 DA MELD 0 BIT DE MELD SP ENDE LAB2 DA MW1 HE HYST JF ENDE DA BIT x VHFF l BIT DA MELD A BIT ES MELD ENDE BE 176 IL Blocks and Macros If limit exceeded load information byte and set information bit for limit violated Skip to end of block Check if measurand reached the threshold limit minus hysterese If no skip to end of block If yes load information bit of limit and invert Reset information bit for this limit violation Skip to end of block Compare measurand and limit If limit underflow load information byte and set information bit for limit underflow Skip to end of block Check if measurand reached the threshold limit minus hysterese If no skip to end of block If yes load information bit of limit and invert Reset information bit for this limit overflow 05 6 4 11 Function Block FB12 NAME 206 8BoV BEZ EIN IW L BEZ OUT QB R RK LD EIN Load measurand i MW 1 I lt VO Is measurand negative JT zNEG Jump to negative value processing LD MW 1 D V 32000 Check if measurand has overrange JF UMSP _If no jump to relocate LD V 32000 f yes limit measurand to maximum MW 1 Jl UMSP NEG A VO If measurand is negativ
108. nd output time Cancel link time Malposition suppression time each controller Two additional timers are required for the pulse width modulator PRO U120 assigns these starting with timer 5 The markers marked with may in no case be used in blocks other than those for which they are planned Definition of the KOS system marker byte Syntax 1st bit 2nd bit 3rd bit 4th bit bth bit eth bit 7th bit 8th bit SMB x1 KOS slot KOS at wrong slot SEAB communications disturbed Minute pulse missing Clock time not valid KOS not parametrized not defined u not defined not defined The system marker SM x 1 node disturbed is set as soon as the SMB x 1 is not equal to 0 05 IL Blocks and Macros 123 6 1 3 List of the Macro Files Macro File Meaning FBS MAC Contains all function blocks VERW MAC Generate organization information subaddress 0 KARTAUS MAC Generate organization information module error n of 18 MELD MAC Single point and real time information processing DOPPEL MAC Double point information processing ZAEHL MAC Counter measurand processing MESS8 MAC Processing of 8 bit measurands MW11 MAC Processing of 11 bit measurands with sign MW ZAEHL MAC Counter block for measurand processing MESS GR MAC Limit monitoring for measurands BE1 AUS MAC Command to group of 8 outputs BE2 AUS MAC Command to group of 4 outputs bits 0 3 BES AUS MAC Command to group of 4 outputs bits 4 7
109. nformation is always entered in the ring buffer as an event For this reason the query event in ring buffer can be omitted here You can define whether a transfer bit U should be set for relocated counted measurands One can switch between yes and no in the individual queries by pressing the keys A lt G gt U E or lt Z gt For each allocation with there is an automatic check whether the selected group number is still available and whether the maximum value for the individual data types is not exceeded If this is the case the corresponding remark appears on the screen 05 Handling 191 The following data types are processed o 64 Measurands 8 bit max 32 words Oo 63 Measurands 11 bit max 63 words Oo 63 Counted measurand max 63 words o 256 Monitored information max 16 words oO 256 Transient information max 16 words Oo 256 Real time information max 16 words rj 48 System information max 3 words A total of only 64 words can be transmitted These limits are partly defined by the capacity of the KOS interface and partly by the hardware requirements A Caution The acquisition time of transient information depends on the IL cycle time The average cycle time is 20 ms The exact cycle time of an outstation can be scanned online with the KOS see Chap 2 4 Only the rising edges are acquired Data for control direction E8 B2 ns Process parameter lists Assignment lists Data for control d
110. nt values were entered in the menu for control direction these are also set in the menu for setpoint values You can assign the relevant data words a value between 32767 and 432767 The value parametered here is output by the KOS after a power failure until a new setpoint value has arrived from the master station Basic setting O 194 Handling 05 Counter measurand processing E8 B4 E Configure parameter lists Assignment lists Counter measurand processing F1 gt F4 gt F4 If counter measurands were entered in the menu for monitoring direction these are also set in the menu for counter measurand processing If you want to define pulse thresholds for the individual counter measurands enter a decimal number between 0 and 255 The input must be terminated with Basic setting 0 o Example In the menu Data for monitoring direction set transfer bit was set for a counter measurand The pulse threshold was set to 100 The counter measurand is always transmitted after a short call if the difference between the last transmitted counter measurand and the current counter measurand is 100 counting pulses Ring buffer handling E8 B5 m Configure parameter lists Assignment list Ring buffer handling F1 gt F4 gt F5 If it was defined in the menu for monitoring direction that data should be written into the ring buffer cyclically you can define in this menu when this entry should occur Times of 1 5 10
111. o the file Uxxx 000 AWL 05 Handling 105 Start Generation of the IL English E2B3 mn Generation and transfer of the IL Start IL generation English F3 gt F2 The German IL as described above is the basis for the English ASCII IL This IL is again translated into English i e commands or operands which have a different name in English are replaced In this way special English macro files are not required gt Note An English ASCII IL cannot be read by a German AKF12 and vice versa 106 Handling 05 Install PLC station and copy the ASCII IL E2 B3 Generation of IL and Transfer Create PLC station and copy ASCII IL F3 F3 The IL generated by PRO U120 is passed to Dolog AKF A120 Step 1 PRO U120 sets up the AKF station directory Uxxx in the system directory ANLAGE PRO Step2 PRO U120 sets up the equipment list and writes it to the station directory Step 3 The file USTxxx 000 AWL is copied to the station directory under the name PRO AWL Step4 The AKF control file AKF12 CMD for this outsttion index is created and stored in the subdirectory PRO FWT Step5 The main setup file of Dolog AKF A120 is set so that the station just installed in the PRO FWT main menu is processed after leaving PRO U120 and selecting the read ASCII IL function Warning If you again transfer a station to Dolog AKF A120 remember that the PBs or FBs generated by PRO U120 and the OB are overwritten If
112. og setpoint values 8 M Measurand 8 Bit 9 Measurand 11 Bit A Caution f you made changes or extensions with the menues subrack select or module select you should not select this function again PRO U120 overwrites your entries with its suggestion 78 Handling 05 5 2 4 Subrack select E2 B1 sf Data input Subrack select Fi Fa Selection E3 B4 The selected subracks are displayed inversely You can change the setting with lt T gt or lt x If an existing selection is reduced any I O modules are deleted You are informed if this is the case so that you can retract the change You can set whether or not a bus extension cable should be used with lt gt or lt lt gt Note f a bus extension cable and 2 or 3 subracksare used the slot distribution is not continuous Gaps occur in the addressing The subracks are displayed appropriately in the menu module select When leaving the menu with F9 or Esc the selected subracks are included in the configuratino of the station 05 Handling 79 5 2 5 Module and Subrack Assignment E2 B1 4 Data input Module and subrack assignment F1 F5 Selection E3 B5 The subracks are displayed graphically according to the setting in the menu subrack select or with the preset values in the menu number of data points Since not all the subracks have room on the screen next to each other they are displayed in two rows one below th
113. on are defined here using check lists 05 Check List 3 1 1 Check list configuration Before you begin configuration of your U120 outstation with the software pack age PRO 7 U120 you should look at the following check list and read the de tained information in the corresponding chapters a Check whether the required softwre environment is available for the configu ration aid PRO U120 Part IIl Chap 1 2 a Check whether the hardware environment fulfills the requirements Part III Chap 1 2 a Install the configuration aid PRO gt U120 o Familiarize yourself with the functions of the operating keys and with mouse operation Part IIl Chap 2 3 and 2 4 Oo Start the configuration aid via the main menu PRO 7 FWT Part Il Chap LEERER MERKER and Part Ill Chap 5 1 2 a Go to the data input level Part Ill Chap 5 2 rj Enter the system names and the outstation numbers in the menu project data Part IIl Chap 5 2 1 rj Check whether the basic settings in the menu general outstation data agrees with your requirements If necessary make modifications Part Ill Chap 5 2 2 o Enter the required number of data points and let PRO U120 make an equipment and assignment suggestion Part Ill Chap 5 2 3 or o Select a subrack and define the equipment and data point assignment your self Part IIl Chap 5 2 4 and 5 2 5 4 Check List 05 If necessary enter the limit values for monitoring the measurands
114. or a peripheral voltage of 24 V If the peripheral voltage is 60 V output is always via relays The setting cannot be toggled in this case Measurands You can set whether the measurands should be input isolated or non isolated Data point input E4B2 ndi Data input Number of data points Data point input F1 F3 F2 Input E3 B3 The input must be decimal and terminated with Cr The following upper limits are monitored o Maximum number of I O modules o Capacity of ALU KOS interface exceeded o Maximum number of data points for this data type If one of these limits is exceeded the corresponding message is output on the Screen and the input is not accepted The number of reserved slots is displayed at the lower end of the screen Similarly the free slots are displayed based on the maximum configuration of 18 slots Note The selection of I O modules is limited for this function to ADU 205 ADU 206 DAU 202 DEP 216 DAP 216 DAP 212 05 Handling 77 Since information and commands only can be reserved in groups of 8 or 4 it is automatically rounded up when you leave the menu Don t be surprised therefore if your definitions have been changed when you select this menu again When assigning the data points to the I O modules PRO U120 proceeds as follows 1 Pulse commands 2 Single point information 3 Double point information 4 Realtime information 5 Measurands 6 Digital setpoint values 7 Anal
115. output After a cold restart the 1st KOS left is taken as default KOS until a corresponding control instruction is set by one of the master stations PRO U120 offers the next free group as command group The first command of this group is the control command The group number however can be changed in the KOS parametrization in the Data for Control Direction menu The command is computed from group number 16 1 Example IB 2 1 BE 02 control comand byte IB 2 3 BE 00 single commands IB2 5 BE 01 single commands Command 33 is the control command in this example 05 Handling 69 A Caution Make sure that a master station may only send a con trol command when it is ensured that all the setpoints in the particular KOS have the current state Command type E3 B2 One can choose 1 pole or 2 pole command output by toggling For 1 pole command output a command from the master station controls one output of an output module For 2 pole command output a command from the master station controls one output each of the upper and lower output groups for the DAP 216 Outputs 1 and 9 2 and 10 3 and 11 etc thus each form a 2 pole command For the DAP 204 and DAP 212 the outputs 1 and 2 as well as 3 and 4 each form a 2 pole command Cancel link time E3 B2 Setting range 100 msec to 99 9 sec Standard setting 200 msec The arrival of the return information starts the timer for the cancel link time The command output to be
116. plement mode these data also have write protection 5 2 1 Project data E2 B1 Data input Project data FI gt Ft The last date of station processing is displayed The user cannot change this line System E3 B1 An input of at most 8 characters is required The system name is at the same time the name of the subindex in which the data of the outstation are archived see Chap 3 3 For this reason only characters which are permitted as index names under DOS may be input Outstation Comments Operator A maximum of 16 characters may be input All characters which can be displayed may be used see Chap 5 1 1 The specifications define more exactly an outstation They are printed in the documentaiton in the form of a header 05 Handling 67 Outstation number It is also called the outstation address or A Byte for the SEAB 1F An outstation number between 0 and 126 must be entered It is also used to identify the individual files during archiving see Chap 3 3 Note You can copy the station set by overwriting the system name or the outstation number First however it must be stored with the data archive menu Example System EXAMPLE and outstation No 0 are loaded and should be copied to EXMAPLE U005 000 Step 1 Overwrite UST No 0 with a 5 Step2 Leave menu with lt F9 gt or lt Esc gt Step 3 Interrogate if outstation should be copied Answer with J Cr Step 4
117. put time in TSWI timer setpoint value K1 M1 3 Set code for cancelled commands IB1 2 Check if one of the commands VO 9 16 is set LAB IB1 2 If yes output parallel to the Q4 1 outputs 1 8 and CNT 8 IL Blocks and Macros 155 41 TBB 04 9 outputs 9 16 42 DBB CNT 8 41 LD V20 Write command runtime in 42 E TSW1 timer setpoint value 43 LAB BE Macro file BE1_AUS MAC Output command to 8 outputs L EBe b KO SP LAB L EBe b TBB AX y DBB ANZ 8 Kt E TSW1 LAB k k Macro file BE2_AUS MAC Output commands to 4 outputs LOW U EBe b U KHOF ET VO SP LAB L EBe b TBB Ax y DBB ANZ 4 L Kt TSW1 LAB eere 156 IL Blocks and Macros 05 Macro file BE3 AUS MAC Output commands to 4 outputs HIGH LAB Fkk EBe b KHFO KO LAB EBe b M4 1 ANZ 8 M4 5 ANZ 4 Ax y ANZ 4 Kt TSWI Macro file BE1 AUS2 MAC Output command to 2 x 8 outputs 2 pole L SP L TBB DBB TBB DBB L LAB Fkk 05 EBe b KO LAB EBe b Ax y ANZ 8 Ax y ANZ 8 Kt TSWI IL Blocks and Macros 157 Macro file BE2_AUS2 MAC Qutput command on 4 x 2 outputs 2 pole U EB e b U KH h KO SP LAB L EB e b TBB M 4 1 DBB ANZ 8 U M 4 m A x y A x y U M 4 m A x y A x y U M 4 m A X V A x y U M 4 m A x y A x y L Kt TSW 1 LAB Macro file BE4 AUS2 MAC Output command to 2 x 2 outpu
118. r are valid b Note Further information about the controllers can be found in the software package Loop CRTL A120 AKF Ordering code 424 271 575 05 Handling 95 5 2 7 Comment Data Point List E3 B7 a Data input Comment data point list FI gt F7 The data point list consists of the columns 1 A Byte Outstation number 2 F Byte Function byte 3 A1 Byte Subaddress 4 D1 D2 Byte Data bytes 5 Address of the ALU KOS interface 6 Datatype 7 Module connection 8 Comments Columns 6 and 7 are defined by the configuration of the modules and the data point assignment The remaining columns except for the comments are computed from these two definitions A maximum of 58 characters can be edited as a comment This could be for example PV numbers or wiring remarks Columns 1 5 on the screen are not displayed for space reasons The complete data points list can be output with the printer menu The requirements of the line editor are valid for editing 96 Handling 05 It is possible to copy single lines or complete line blocks oO You can mark the line containing the cursor for copying with Alt M The line is displayed blue or inverse o A line block is marked as follows Cursor to 1st line to be copied and Alt A Cursor to last line to be copied and Alt E The block is displayed blue or inverse o The marked line or line block is copied starting with the curr
119. r each component in the last column and create several files with different customer reductions 05 Handling 99 It is also possible to store library files having a certain combination of components as standard files The individual libraries contain 120 positions which are divided into 3 categories Positions 1 28 are the subracks and the modules whose number is defined by the configuration see Chap 5 2 2 5 2 4 and 5 2 5 Only the price per unit can be edited here in the last column Positions 29 113 are hardware and software components for which you can define whether and how often they should be included in the bill of materials This is done by entering the required number in the first column Positions 114 120 are at your free disposition You can enter for example special modules or the costs for installation and configuration The costs per item entered here are included in the calculation and in the bill of materials If an entry was made in one fo the lines 114 120 it is then handled as lines 29 113 Only the number and price per unit can be changed However the whole line can be deleted with Del if the cursor is at the start of the line You go to the previous or next line with lt f gt and lt gt if the cursor is at the start of the line You go to the first possible input position with lt gt The line editor is valid wihtin an input field From the column number you always go first to
120. re need only be a limitation to 32000 4 2 9 1 Pole Commands Configurable at DAO 216 DAP 204 DAP 208 DAP 216 DAP 212 DAP 220 DAP 292 Allocation Depending on outstation Processing A command from the master station controls an output 05 Configuration 53 4 2 10 2 Pole Commands Configurable at DAO216 DAP204 DAP208 DAP 212 DAP216 DAP220 DAP292 Allocation Depending on substation Processing DAO 216 DAP 216 A command from the master station controls 2 outputs of a DAO 216 or DAP 216 Output 1 and 9 2 and 10 3 and 11 etc form a 2 pole command A Caution The 2 pole output is only possible by connecting an interface relay between the end relay and the output module Processing DAP 204 DAP 212 A command from the master station controls 2 outputs Output 1 and 2 3 and 4 each are one 2 pole command Processing DAP 208 A command from the master station controls 2 outputs Outputs 1 and 2 3 and 4 5 and 6 7 and 8 each are one 2 pole command DAP 204 212 292 DAP 208 DAP 216 o e o ES I Command 1 o o _ we Command 1 o o BEES Command 1 e i Command 2 s Command 2 MES Command 3 ji el o o CN e r o Command 3 o Command 2 o T M Command 4 o Figure 2 2 pole command output on DAP 204 212 and 216 54 Configuration 05 Note A 1 of n check is made before each command output No further command can be output as long as one command is running Commands whi
121. reached and the standardization of the extreme value is called Note The time is transferred from the KOS to the IL in IBs 121 to 128 This time is used to compute the time interval in the IL This ensures that the extreme value standardization and the ring buffer entry are carried o ut synchronously in the KOS Measure minimum values in 2 hour interval 01 BA FB 6 02 NAME EXTREM 03 MESS QB 2 5 04 ONT1 CNT 2 05MIN OB 2 27 06 CNT2 CNT 2 07 MAX MB 3 Two auxiliary bytes are 08 CNTS CNT 2 transferred for the maximum value 09 geek 10 LD IB 1 128 Check seconds 11 VH 1 12 M 4 1 13 BEZ 14 LD IB 1 126 Check minutes 15 i VH 0 16 M 4 1 17 BEZ 18 LD IB 1 125 Check hours 19 DIV VH 2 20 MB 1 21 A SMB 1 162 IL Blocks and Macros 05 22 VO 23 BCC PB 22 24 paises BE Both extreme values are always computeed in the FB If only one extreme value is required two auxiliary bytes and no KOS output byte are transferred for the others If only maximum values are computed both auxiliary bytes are trans ferred in line 5 and the output byte for the maximum value is entered in line 7 In this way it is possible to manage with only one function block 6 3 21 Program Block PB22 01 LBW OB 2 5 Store current measurand in ABs 02 DBB CNT 2 03 TBW QB 2 27 for minimum value 04 DBB CNT 2 05 TBW AB 2 29 and maximum value 06 DBB CNT 2 RK BE or 01 LBW QB 2 5 Store measurand oniv in ABs 02 DB
122. rocessing kkk 02 BC PB11 Call analog setpoint value processing D kkk 03 DA VO 04 inue M1 4 Input marker Reset command output timer kkk 05 BC PB12 Call Check command 1 of n 06 DA M1 3 If marker 1 07 BCC PB15 Check command for cancellation kkk 08 DA M1 4 If marker 1 09 TEP T1 Start command output time 10 DTB 100MS 11 L TSWI 12 DA M1 8 If timer output link time 1 13 DR T1 Reset timer command output time 14 M1 5 0 Command output time expired 05 IL Blocks and Macros 129 B kkk TA M1 7 TS 15 16 T2 17 DTB 100MS 18 LD V2 19 AN M1 5 20 R T2 21 M1 8 kkk 22 AN M1 5 23 ESA M1 3 24 AN M1 7 25 JF LAB1 26 A V64 27 O QB1 1 28 iS QB1 1 29 LAB1 30 AN M15 31 BCC PB13 BE Macro file T BEFAUS MAC If marker 1 Start timer link time Link time 200 msec variable If command output time expired Reset timer link time 1 link time expired Command output time expired 1 cancelled command Link time expired If not skip to LAB1 7th bit in organization information A1 0 Set i e no return information for cancelled command If command output time expired Call reset command output Timer for command output time 130 U M1 4 SV Tt DZB 100MS L TSW1 U M1 8 R T1 M1 5 kkk IL Blocks and Macros 05 Macro file VERKL MAC Link time for cancelled commands U M1 7 SS T2 DZB 100MS L Kt UN M1 5 R T2 M1 8 ck Macro file F A
123. rs were assigned to function keys Shift F1 lt Shift gt lt F2 gt lt Shift gt lt F3 gt lt Shift gt lt F4 gt lt Shift gt lt F5 gt lt Shift gt lt F6 gt lt Shift gt lt F7 gt lt Shift gt lt F8 gt lt Shift gt lt F9 gt lt Shift gt lt F10 gt va amp O m Co Additional columns can be set up in the comments part of the data point list with lt Shift gt lt F8 gt Note The complete set of characters can be edited with lt Alt gt lt ASCll keyboard code gt The number sequence may only be entered using the numeric block The corresponding tables can be found in the PUTE user manual or in the printer manual Example The letter A should be input with the keyboard code Press the Alt key and then the digits 1 4 and 2 one after the other Release the Alt key and the A appears on the screen 64 Handling 05 5 1 2 Start of PRO U120 EO B1 PRO U120 is started from the main menu PRO gt FWT A header which de fines the current version of the operating software appears once after the call The main menu PRO U120 appears after any key is pressed and you can begin configuration PRO U120 loads the last processed system and station into user memory af ter the call Caution The system NONAME and the station U000 000 are set by the installation routine during the first start U If the loaded station is to be processsed one must decide whether
124. s located in the root directory Example COPY CAPRO FWT EXE CAPRO EXE The old versions can now be selected by calling PRO Data will be saved in a new path and under a new name see chapter 3 3 If you want to be able to edit stations created by PRO Z120 versions 1 3 using version 4 you have to install the conversion program included in the package and start it Installation instructions Insert the disk with the conversion program into drive A or B and start the installation with A INSTAL or B INSTAL The program will be installed in the root directory and can be started from there by entering KONVERT The conversion only has to be performed once 30 Introduction 05 Chapter 2 Overview And General Information E Overview And General Information 31 2 1 Summary of Features PRO 7 U120 supports the user in the configuration and start up of the Geadat U1 g 32 20 outstation A subrack including the module assignment is automaticallv determined bv specifving the data points A selected hardware subrack and I O modules and their data point assign ments can be selected Special features can be assigned to the data points Control blocks can be defined An instruction list IL is generated based on the parameters entered Transfer of instruction list to Dolog AKF A120 Transfer of generated parameters to KOS 201 210 with EPROM or by transfer to KOS RAM Files can be generated for a bottom up configuration
125. s pseudo A1 byte always describes 16 commands O command 1 16 1 command 17 32 2 command 33 48 etc The structure struct pv is generated for each message and corresponds to one line in the file KOM The length of the file KOM varies because of the variable number of data points The last line contains only ZEROES as en d code List of the PV attributes 128 Monitored informations 129 Real time informations 130 Transient information 131 Measurand 11 bits with sign 132 Measurand 8 bits without sign 133 Counted measurand 134 Relocated counted measurand 135 Commands 136 Analog setpoint values 137 Digital setpoint values 138 System informations 139 System commands 224 File Structures Example File U020 001 KOM PRO U120 04 00 28 05 1992 2 00600 015 005 016 w e j s z 00060 020 020 000 1 00301 00600 s s af ae zz 7 zy AE ju zy je 80012D140A00 80013D140A01 80014D140A02 85015D142A00 85015E142A01 85015F142A02 850160142A03 850161142A04 850162142A05 850163142A06 850164142A07 830165144A00 830166144A01 830167144A02 830168144A03 810169145A00 05 File Structures 225 8A0179147A00 870189149B00 870199149B01 8901A914CBOO 8901AA14CB01 8801AB14CB02 8801AC14CB03 000000000000 This is a file of an outstation A file with the same structure is generated for the slave KOS of a substation Different A bvtes are entered in the file however in transparent mode
126. sions ALU 200 276 689 00 ALU 201 276 690 00 Firmware package KOS xxx FPM 001 containing FWM 001 FWM 002 FWM 007 FWM 008 xii 277 782 01 275 125 06 SEAB 275 126 01 APS 261 541 00 SEAB 8k RP 261 142 00 AWD 8k RP 05 Handling 3 1 2 Diskettes No cleaning of diskettes Insert diskettes correctly Don t move the metal slide Store diskettes in protective a containers and boxes Temperature 10 to 60 C Humidity 8 to 80 No heavy objects on diskettes Diskettes tolerate no heat Label diskettes at the sunshine right spot No diskettes near mag netic fields No forcing diskettes into disk drive ya d Always keep in mind SF 20 xiii Handling 5 Diskettes No diskettes near mag netic fields Insert diskettes correctly No erasing on diskettes Touch only protec of diskettes O Store diskettes in protective containers and boxes No bending or folding of diskettes Diskettes tolerate no heat sunshine No painted pencils for writing on diskettes Label diskettes at the right spot Temperature 10 to 50 C Humiditv 8 to 8096 No heavv objects on diskettes No forcin
127. sponds to ESC or F9 Menu call Set the mouse cursor to the red inverse function key fields and click with the left key Selection within the menu Set the mouse cursor to the desired input line or selection field and click with the left mouse key Set the module or slot location in the menu I O module selection in this way and then delete or set by clicking the red inverse function fields A selected module can also be entered by twice clicking a subrack location File selection window Select the system or file with the mouse cursor and click with the left mouse key If the mouse cursor is set to the upper or lower free line in the window and clicked the scroll function is carried out if necessary Setting the mouse cursor to the text RETURN and clicking activates the corre sponding RETURN function 05 Overview And General Information 37 2 5 General information 38 The following symbol specifies how to select the described function Counting always starts with the main menu The brackets contain the function keys which must be pressed in the main menu Example Data input Subrack selection F1 gt F4 The specifications Ex By in the titles are also included in the lower right cor ner of the screen pages They display the menu level and menu image In this way the relevant chapter for a particular screen page can easily be found using a cross reference list Remark window If an incorrect inpu
128. steresis 0 1 edge 0 1 edge 2 information 1 information 1 0 edge 1 0 edge 2 information 1 information Figure 9 Limit monitoring of measurands Input of the limits The current input field is displayed inversely One reaches the next or previous input field with stacked drop layout with Tab and Shift Tab One reaches the next or previous input field of a line with Ctrl gt and Ctrl lt gt Otherwise the requirements of the line editor are valid A message appears on the screen if a value less than 32000 0 or greater than 32000 250 is input and the value must be corrected Analog Extreme Values E4 B5 al Data Input Special Processing of Data Points Analog Extreme Values F1 gt F6 gt F2 All the configured 11 bit measurands are listed in this submenu The software address with which a measurand is addressed under Dolog AKF is specified This does not correspond to the hardware address The definition 03 01 05 Handling 91 specifies the 1st measurand of an ADU at slot 3 4 hardware connections of Pin 3 6 are assigned to this measurand You define the measurand for which extreme values should be determined by toggling with Cr There is also a query whether a maximum or minimum extreme value is required It is also possible to determine both extreme values This means however that both extreme values are determined and transmitted to the KOS for all the selected mea
129. subrack assignment ZOOM on off F1 F5 F1 Once the I O modules have been allocated they can be assigned data points Zooming is possible here i e an I O module can be displayed enlarged The I O module marked to the right in the subrack is displayed to the left in the figure In order to display another module the slot in the subrack must only be changed with or lt gt gt You need not leave the ZOOM function The relevant I O module is displayed graphically in the window which was opened by the ZOOM function The valid data point types are listed to the right of it see Chap 4 2 These are Single point information Double point information Real time information Counter measurands Measurands 8 Bit Measurands 11 Bit Actively cancelled commands Persistent commands Pulse commands with command runtime Digital setpoint value output Analog setpoint value output 330000000030 The individual modules are displayed subdivided into data groups Monitored information and counter measurands are assigned in groups of 8 inputs Commands are assigned by module or in groups of 8 outputs Analog and digital setpoint value output as well as measurands are assigned by module 05 Handling 83 DEP 208 subdivided into 1 x 8 DEO 216 subdivided into 2 x 8 DEP 208 subdivided into 1 x 8 DEP 216 subdivided into 2 x 8 DEP 296 subdivided into 2 x 8 DEP 297 subdivided into 2 x 8 DAO 216 subdivided into 2 x 8 DAP
130. succession release the transfer of the corresponding meassage The transfer of the meassage can be suppressed by parameterization a Definition of running reserve If the synchronization of the internal clock is not possible because there is no valid minute pulse from DCF 77E or time meassage from the master station a corresponding meassage is send to the master station after a parameterizable time After this time the internal clock is stopped an realtime informations are written to the ring buffer with the fine time FFFFH Other data are written to the ring buffer not any more Values of 1 26 and 50 hours are possible 05 Handling 189 2 2 4 Note If you use synchronization via DCF 77E and a running reserve of 26 hours it may occur that the internal clock can be no longer synchronized if the DCF signal has failed for more than 10 hours Synchronization is only possible after the 26 hours have elapsed The selection of a running reserve of 50 hours is not allowed with DCF 77E Assignment Lists for SEAB 1F E7 B4 Configure parameter lists Assignment list F1 F4 A menu appears from which vou can call the individual submenues The inverselv displaved fields alwavs show which specifications are active Note 2 bytes of the KOS interface are always defined simultaneously due to the 16 bit homogenity of the SEAB 1F telegrams For this reason the term word or data word was used in the subsequent text You can select the da
131. surands One time interval which is also interrogated in this menu is valid for all extreme values Time interval Minutes 1 2 3 4 5 6 10 12 15 20 30 Hours 1 2 3 4 6 8 12 24 Extreme values are transmitted like normal measurands in the SEAB 1F Identification is thus with the A1 byte To prevent overlapping in extensions the extreme values are sorted in decreasing order starting with A1 63 The extreme values are displayed with MWE in the menu Data Monitoring Direction of the KOS parameter assignment Processing The measurand the the relevant extreme values are compared in the IL in each scan If the measurand is greater than the upper or smaller than the lower extreme value it is transmitted to the KOS as the new extreme value Caution If analog extreme values are to be determined the clock time must be transmitted to the KOS The clock time passed to the KOS by DCF signal or time message is transmitted in the EB area of the KOS This time is used by the IL to standardize the temporary extreme value storage synchronously with the KOS 92 Handling 05 Two position controller E4 B5 Data input Special processing of data points Two position controller F1 F6 gt F2 If the difference between the setpoint value WE and the actual value XE exceeds half the hysteresis value HYS the output YA is set depending on the sign of the deviation The controller can be released with the release enable EF 1
132. suring range of 1V or 10V can be selected for each of the 4 measurand inputs The selection window can be called with lt gt You can identify single point or double point information as return information for actively cancelled commands by entering R before the Cr The information group is entered in the window with ME R or DMER The setting R is maintained until the data type or module is changed gt Note Special function for linking to master stations Geadat VEN An 8 input monitored information group can be specially marked by entering lt N gt N new subaddress so that it can be assigned to a specific new SEAB telegram This monitored information group is dis played in the window with SPIN The setting N is maintained until the data type or module is changed A Caution When assigning counter measurands measurands and analog setpoint value outputs one should make sure that there are no gaps in the assignment 05 Handling 85 ADU ADU ADU ADU 204 204 204 204 ME8 ME8 ME8 ME8 2 3 4 1 wrong correct Figure 7 Data point assignment You can process unused counter measurand inputs measurand inputs and analog outputs in a separate IL part if necessary This is not valid for monitored information inputs and command outputs because these are always processed by the generated IL If these inputs and outputs are processed with one s own IL nevertheless one must make sure
133. t is made when configuring with PRO U120 or if a limit is exceeded this is displayed on the screen with the corresponding output In order to delete this remark window from the screen press any key You can then correct the input and continue with configuration Overview And General Information 05 Chapter 3 Overview How To Work B Overview How To Work 39 3 1 Flow Chart 1 C o Process new outstation Module selection Data point allocation 1 Comment data point list 1 1 1 Data input Measurand processing Archive outstation 1 1 1 Project data Svstem name and Edit controller Document outstation outstaion numbers must be entered 1 General outstation data 1 Enter number of data point 1 Generation of IL DologAKF A120 Generate EPROM 1 1 KOS parametrization enerate EPROM Insert EPROMs on KOS CRISS ERRO and ALU Set jumper on all modules Insert 1 moldules in subrack Transfer to Dolog AKF A120 Subrack Selection 40 Overview How To Work 05 3 2 Tree Structure of the Menues Level 0 Figure 1 Select Restart or Supplement 05 Level 1 Level 2 Figure 1 F1 Project Data m B1 General Datas of F2 B2 Outstation Number of Data Points F3 B3 Selection of Subracks FA B4 Modul
134. ta word in the table which you want to define with lt gt Tab or lt Shift gt lt Tab gt in all the submenues In order to redefine a word you must only select the corresponding word set the new data and enter The KOS interface is 128 bytes or 64 words large in both directions Since not all the data words can be displayed on the screen at one time one can page between two pages with PgUp and lt PgDn gt 190 Handling 05 Data for monitoring direction E8 B1 a Configure parameter lists Assignment lists Data for monitoring direction F1 gt F4 gt FI The data type can be changed with lt gt and lt gt Group numbers A1 byte are entered with the digit keys One can specify for each data type whether a transfer bit A should be set if it is changed Furthermore cyclic ring buffer entries lt Z gt can be made All data except for monitored information can also be entered in the ring buffer as an event E Monitored information for which each event is to be entered in the ring buffer must be parametered as real time information The following are defined as events oO Changes in monitored information 0 Reaching the pulse threshold for counted measurands rj Reaching the AZI for measurands You can configure for all types of data whether they should be transferred if there is a general interrogation G This is also valid for the processs state of the real time signals Real time i
135. terfaces can be used with the cursor keys and with the mouse The individual menues or functions are called by clicking with the left mouse key or with RETURN In pulldown menus the call can also be made using the refe rence characters which are displayed in a different color The menu window is closed with ESC or by clicking Passive functions are displayed in the pulldown menu without a reference charc ter and in a different color These cannot be selected or are skipped with the cursor Example The program is in graphic mode only a switch to text mode is now possible After switching the graphic mode function is active and the text mode function is passive 05 Operating 13 1 2 Expert system PRO The 120 series includes the expert systems o PRO U120 for outstations with Modnet IF o PRO UZ120 for submaster stations with Modnet IF o PRO Z120 for master stations with Modnet 1F oO PRO U121 for outstations with Modnet 1W in preparation The 250 series contains the expert systems o PRO U250 for outstations with Modnet 1F in preparation oO PRO UZ250 for submaster stations with Modnet 1F in preparation 14 Operating 05 1 3 Dolog AKF The two software products AKF12 and AKF25 are provided for programming the telecontrol stations The 120 series can be programmed with AKF12 The 250 series can be pro grammed with AKF25 Note The Dolog AKF software has large space requirements If you loaded m
136. tion Block cece eee ee 125 The program blocks eee eee eee eee 126 Program Block PB1 LLL eee eee eee eee 126 Program Block PB2 6 0020e cece eee 129 Program Block PB3 LL eee eee eee eee 129 Program Block PB4 LLLL eee eee eee eee 132 Program Block PB5 000e cece eee 133 Program Block PB6 LL eee eee eee eee 136 Program Block PB7 LLL eee eee eee 137 Program Block PB8 6 00200e eee eeee 139 Program Block PB9 LL eee eee eee eee 140 Program Block PB10 eee eee eee 142 Program Block PB11 0200 cece eee 143 Program Block PB12 0L0 eee eee eee 144 Program Block PB13 0 eee eee eee 146 Program Block PB14 6 0200 cece eee 148 Program Block PB15 cee eee eee eee 152 Program Block PB16 2 eee eee eee 153 Program Block PB17 20020e cece eens 159 Program Block PB18 eee ee eee eee 160 Table of Contents xvii 6 3 19 6 3 20 6 3 21 6 4 6 4 1 6 4 2 6 4 3 6 4 4 6 4 5 6 4 6 6 4 7 6 4 8 6 4 9 6 4 10 6 4 11 6 4 12 Part IV Chapter 1 Chapter 2 2 1 2 2 2 2 1 2 2 2 2 2 3 2 2 4 2 2 5 2 3 2 4 2 5 2 6 2 6 1 2 6 2 2 7 2 8 Program Block PB19 000 rennen 160 Program Block PB21 2 2 2222 cee rennen 161 Program Block PB22 22 222 2eeee rennen 163 The Funeiton Blocks esses 165 Funktion Block FB1
137. tion of the supervise time bit 26 in the organization information word is set Note Actively cancelled commands cannot be configured for the DAP 204 The return information is assigned as described in Chap 4 2 3 There is 1 1 assignment for 1 pole commands 8 information inputs of a DEP 208 or DEP 216 are used as return information for 2 pole commands on DAO 216 or DAP 216 The first two pieces of monitored information from the same module are used as return information for 2 pole commands on DAP 212 or DAP 292 56 Configuration 05 DEP 216 DAO 216 DEP 2 DAP 212 292 DAP 216 DEP 29 oe o e 9 9 o o 2 CACO CACO gt SPIR or DPIR e o e e oo e e C T Q el e CACO e SPIR or DPIR o z 23 U Figure3 Assignment of Cancelled Commands and Return Information 4 2 14 Digital Setpoint Values Configurable at DAP 216 DAO 216 Allocation Depending on module Processing No special processing The 16 bit value is output on 16 outputs 05 Configuration 57 4 2 15 Analog Setpoint Values Configurable at DAU 202 DAU 208 Allocation The number of setpoint values is configured Processing No special processing Note Make sure that the valid range of 32000 is not violated by the master station 58 Configuration 4 3 Configuration Limits Table 1 Configuration Limits Data type Number Structure Monitored information 256 Bit Rea
138. tional module is set by toggling If you do not want to call the parameter assignment program move the cursor in the subrack on by one slot However this is only possible if the cursor points to the uppermost line The KOS parameter assignment program can also be called from the main menu with Alt K If several KOS modules were equipped the KOS parameter assignment is called with the lowest slot reference Before the KOS main menu appears there is a query whether the KOS parameters should be newly defined or whether they should keep the old data If the KOS file is newly defined the standard settings are made for the transfer bit ring buffer entry edge detection etc If you made not changes to the data points you can call the KOS parameter assignment without generating a new file Your settings made in a previous call are not changed 05 Handling 87 Several KOS modules in one outstation Maximum number of KOS modules 3 KOS for central processing unit ALU 200 2 KOS for central processing unit ALU 201 If more than one KOS is configured in an outstation the KOS with the lowest slot reference is used for the generation of the IL However the same parameter as the IL KOS is passed to the other KOS modules The parameter assignment for the 2nd or 3rd KOS can only be called by selecting and zooming the corresponding module in the module and subrack assignment menu The outstation number entered in the project data m
139. ts 2 pole U EBe b U KHh KO SP LAB L EBe b TBB M4 1 DBB ANZ 8 U M4 m AX y Ax y U M4 m AX y 158 IL Blocks and Macros LAB m il kkk Ax y Kt TSW1 The corresponding macro is read in during generation of the IL depending on the command type 1 pole or 2 pole and the module type The constants for coding the command are included in the macros for 1 pole command output Variables x y are simply replaced with the output addresses variables e b with the input bytes of the KOS and variable t with the command output time For 2 pole command output to 4 output modules DAP 204 and DAP 212 variable h is also replaced with the constant for coding the commands Variable m is furthermore replaced with the marker which should approach the command output 6 3 17 Program Block 05 Pa gt il ts 4 TA aa IB 2 3 The input bvtes of the MB 43 1st KOS are loaded into IB 2 4 marker bvtes 43 to 168 MB44 IB 2 127 MB 167 IB 2 128 MB 168 IL Blocks and Macros PB17 159 6 3 18 Program Block PB18 ja TT IB 3 3 MB 43 IB 3 4 The input bytes of the 2nd KOS are loaded into marker bytes 43 to 168 MB 44 IB 3 127 MB 167 IB 3 128 MB 168 s E Dep 6 3 19 Program Block PB19 zs QB 2 1 The output bytes of the QB 3 1 1st KOS are copied into QB 2 2 the output bvte of the QB 3 2 2nd KOS PE QB 2 127 QB 3 127 QB 2 128 QB 3 128 mk CBE oe SE 160 IL
140. tteries is transferred in the two most significant bits of the management signal A1 O 8K ring buffer in U120 The firmware diskette contains two new firmware variants in which a ring buffer of 8K messages is implemented The hardware module KOS 202 E No 278 918 is required here part IV chap 2 2 3 9 FWM007 261 541 SEAB 1F Modnet 1F o FWMO008 261 542 AWD 28 Introduction 05 1 4 2 Compared to PRO U120 V 5 0 4 master stations for AWD operation The outstation can now be called with a maximum of 4 master stations part IV chap 2 2 5 GA bits A GA bit can be configured for each message part IV chapter 2 2 4 Running reserve The running reserve can now be set to 5 hours 05 Introduction 29 1 5 Update version If you have received an update version of the expert software PRO U120 you should pay attention to the following instructions prior to the installation As of version 2 0 the software is installed in the subdirectory PRO FWT PRO U120 Old versions 1 3 of the expert software will not be overwritten or deleted The main menu PRO FWT will be installed anew and will only call the new expert systems oO PRO U120 as of version 4 rj PRO Z120 as of version 2 0 PRO UZ120 as of version 2 If you also want to call the old versions of the expert systems from a main menu you have to save the program PRO FWT EXE already installed under a different name before the installation The program i
141. ues 05 Handling 61 5 1 General Information The individual menu points are described in the order listed below o g U U 62 Data input Data archive IL generation and transfer Printer output Screen output of the bill of materials Handling Chapter 5 2 Chapter 5 3 Chapter 5 4 Chapter 5 5 Chapter 5 6 05 5 1 1 The Line Editor The line editor is used for inputting project data commenting the data point list and extending the library file Table 2 Keyboard Definition US Keyboard Key Definition lt Backspace Delete character to the left lt Del gt Delete character above cursor Ins Insert overwrite switch is displayed to the right in the last screen line Home Cursor to first character of input line End Cursor to last character of input line lt gt Cursor one position to left lt gt gt Cursor one position to right 1 Cursor to start of previous input line i1 Cursor to start of next input line Cr Terminate input Only for data point list library and bill of materials lt PgUp gt Previous page lt PgDn gt Next page Only for data point list Alt M Mark a line to copy Alt A Mark line block start lt Alt gt lt E gt Mark line block end lt Alt gt lt C gt Copy marked line or line block to current cursor position 05 Handling 63 Since many computers are equipped with a US keyboard the special German lette
142. ule failed n of 18 U SMx 1 O SMy SPZ LAB U Kx O ABk v ABk y LAB Lines 1 to 16 are generated directly by PRO U120 Lines 9 11 are only gen erated if Module failure information n of 18 was configured Lines 17 to 32 are read in as a macro VERW MAC Lines 33 38 are generated by PRO 7 U120 The organization information module failure 1 of 18 is generated here The relevant slot is entered in the organization information A1 0 binary coded If several modules fail the last slot position is entered and in addition the sixth bit is set The module failure information is generated n of 18 in lines 39 52 Slots 1 16 are entered in the 3rd and 4th bytes of the KOS organization information A1 1 slots 17 and 18 in the 5th byte of the KOS organization information A1 2 The macro KARTAUS MAC is read in for this purpose 128 IL Blocks and Macros 05 6 3 2 Program Block PB2 01 BC PB4 Call single point information processing rar 02 BC PBS Call double point information processing kkk 03 BC PB6 Call counter measurand processing kkk 04 BC PB7 Call measurand processing 8 bit kkk 05 BC PB8 Call measurand processing 11 bit kkk The block is generated by PRO gt U120 Only those block calls are generated whose data type was configured If for example no 8 bit measurand was configured line 4 is omitted 6 3 3 Program Block PB3 01 BC PB10 Call digital setpoint value p
143. utput size resulting from the average value of the sampling rate can be used for example to approach a relatively inert path The pulse length is directly proportional to the control difference Xd the sampling rate and thus the proportionality of the PBR depends on the set pulse time The controller can therefore be described as follows yeff UK 10096 0 lt y eff lt 100 Xd x KR x dt TTK is directly specified in seconds dt results automatically with the 100 msec for all controllers The output of the YP YN pulses can be influenced with TMIN and TMAX If the controller reaction time computed by PBM is less than the value of TMIN no further pulse is output until larger pulse lengths are again computed If the computed controller reaction time exceeds the value TMAX the controller reaction time is limited to this value These first steps prevent actuating pulses which are too short e g for a valve the last steps prevent continuous control 94 Handling 05 Valid input and output parameters for all controller types 15 controllers can be configured per controller type Marker bit from M 8 1 to M 50 32 Marker words from MW 30 to MW 300 Constants from 0 to 32767 Inputs and outputs if the corresponding modules were entered in the subrack Editing the controller Home End toggle input and output parameters Pg Up call previous controller Pg Dn call next controller Otherwise the requirements of the line edito
144. with the name USTx y KOS x is the outstation number y is the KOS slot address in the subrack Note When a parameter list is saved there is a check whether a file with the same name already exists In this case a comment appears and there is a query whether the file should be overwritten The data are saved in Intel Hex format The program enters the current date in the parameter file before saving Several stations can be stored on one diskette Delete file gt Data Archive Delete file F2 gt F3 As for Read data all the previously processed systems are displayed in a window and then all the KOS parameter files are listed If the selection of a file is confirmed with Cr it is deleted The delete function can be aborted with Esc or F9 05 Handling 201 Change drive aw ya wa gt Data Archive Change drive F2 gt F4 Drives A to Z are offered for selection in a window The drive identifier can also be entered directly after calling the function with F4 The initial setting is the drive from which PRO U120 or KOS201P was started If this setting is changed e g from C to A drive A is addressed now for the functions Read File Save File and Delete File 202 Handling 05 2 4 Transfer E6 B3 Parameter List from KOS ie Transfer Parameter list from KOS F3 FI Before the data are transferred from the KOS to the PADT there is another query whether this funct
145. you changed these blocks you should first save them in another index or on diskette in order to in clude the changes at a later time 1 xxx outstation number 05 Handling 107 5 5 Printer Output E1 B1 Each printed page contains a header which includes Oo System name Oo Outstation designation o Date of generation oO Version index oO Comments ao Operator Printout of the bill of materials E2 B4 Printer output Bill of materials FA F1 A query is made whether a new bill of materials should be generated for the printout If yes all existing library files are offered for selection in order to determine the bill of materials If a library is selected with prices per unit you can specify whether the total price of the station should also be printed Printout of the hardware configuration E2 B4 Printer output Hardware configuration F4 F2 The selected subrack s including the equipment mounting are printed in graphic form The I O module slots are designated with 1 to 18 to correspond with their slot address The subracks are displayed in three rows The bottom row is only intended symbolically for optional modules and not for I O modules 108 Handling 05 The two upper rows contain the slots which can be addressed by the ALU Actually both rows shoudl be displayed sequentially if no bus extension cable is used This was not done so that the printout could be made in DIN A4 format A configured
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