Installation and operating instructions Barriers ES 25 – ES 80 Part 2
Contents
1. Past 18 SubnetmaskByte2 P232 18 SubnetmaskByte3 P233 18 SubnetmaskByte4 18 Socket port number ten thousands digit thousands digit 18 Socket port number hundreds digit tens digit units digit 11 MO 64 Main Sub Starting sequence sequence page Pe fl Return to main sequence to P300 RP scmateSotie onan automatic closure on off P302 20 Setting pre waming before opening P303 20 Setting pre waming before closing Papp _ Return to main sequence to P400 Paoo Setting of counters P 21 Setting maintenance interval P42 21 Displaylerase service counter Pao 21 Counting function setting lower limit Pan 21 Counting function setting upper limit Return to main sequence to P500 Ps00 Various operating modes 22 Operating mode for multi functional relay 1 Multi 1 22 Operating mode for multi functional relay 2 Multi 2 22 Operating mode for multi functional relay 3 Multi 3 22 Operating mode for multi functional relay 4 Multi 4 22 Operating mode for multi functional relay 5 Multi 5 22 Operating mode for multi functional relay 6 Multi 6 23 Red traffic light RtApl in end position CLOSED 23 Red traffic light RtApl at pre warning before opening 23 Red traffic light RtApl at pre warning before closing Red traffic light RtApl during opening Red traffic light RtApl during closing 23 Red traffic light RtApl at intermediate stop 23 Red traffic2. P701 P724 Setting the loop logic for loop A B or C The following table shows which parameters can be selected for the free configuration of the loop logic for loop A B or C Description Sequence Sequence Sequence sequence point point for pointfor point for loop A loop B loop C Activation deactivation loop P701 P711 P721 deactivated 1 loop activated Function during 0 no function P702 P712 P722 driving on the oka 3 opening and safety 4 closing Function when leaving Beto antenna f2 ronson P703 P713 P723 Presence ae P704 P714 P724 reporting presence blocking presence Table 26 P730 P748 Setting directional logic 1 and directional logic 2 The signals Loop occupied of two loops each can be evaluated by the directional logic 1 or 2 Thus it is identifiable if a vehicle has driven on the two loops from a certain direction or if a vehicle has driven over the two loops from a certain direction The following steps have to be set for a directional logic e Induction loops which are to be combined with a directional logic have tobe activated under 2 2 7 1 P701 P 724 Setting the loop logic for loop A B or C e Then select under P730 or P740 which induction loops shall be evaluated by the directional logic e Now it can be configured what effect these signals shall have on the controller The message driving on the loop can e g be used for the presence detection The message p
3. barrier is kept open by the first vehicle on loopA When the first vehicle leaves loop A a closing command is issued In order to prevent the barrier from closing also safety on loop B has to be activated Then safety by loop A and B When leaving loop B a closing command is issued Yet the barrier remains open since safety through loop A is active 47 MO 64 When leaving loop A the barrier closes Table 33 Behaviour when a vehicle drives backwards The vehicle drives to the barrier When driving on loop B the barrier opens The vehicle stops The barrier remains open The vehicle drives backwards When leaving loop B the barrier closes Table 34 48 ELKA MO 64 2 4 4 Mode 4 Presence safety and closing with two loops Table 35 The vehicle drives to the barrier The vehicle stops on loop B The barrier controller reports the presence to the ticket dispenser The barrier is opened by an external command The vehicle can pass When leaving loop B a closing command is issued but safety through loop A is active The second vehicle can drive up When the first vehicle leaves loop A a closing command is issued Loop B reports the presence to the ticket dispenser The ticket dispenser can issue an external opening command The barrier remains open 49 FILKA MO 64 2 4 5 Mode 5 Presence opening safety and closing with three loops Table 36 The vehicle drives to th
4. 2 4 7 Mode 7 Opening safety and closing with three loops Table 38 The vehicle drives to the barrier When driving on loop B the barrier opens The first vehicle passes the barrier When leaving loop B a closing command is issued Safety by loop A When the second vehicle drives on loop B an Opening command is issued Leaving loop A issues a closing command which is overwritten since safety by loop C is active When leaving loop B a closing command is issued When leaving loop C a closing command is issued The barrier remains open since safety on loop A is active When leaving loop A a closing command is issued But since safety by loop C is active the barrier remains open When leaving loop C the barrier closes The vehicle drives to the barrier When driving on loop B the barrier opens The vehicle stops Safety on loop B The vehicle drives back the barrier closes 52 FIKA MO 64 il The functions described above also apply to the opposite direction 53 ELKA 2 4 8 MO 64 Mode 8 Opening safety and closing with three loops Table 39 The vehicle drives to the barrier When driving on loop B presence is reported Remark The presence is reported to bothticket dispensers The ticket dispenser issues an opening command The barrier opens The vehicle passes the barrier Safety by loop A Leaving of loop A closes the barrier Loop C reports the presence Remark The pr
5. SEA or SEZ limit switch OPEN or limit switch CLOSED or both LEDs during an intermediate position e LED Vp supply voltage P101 Learning the barrier running time force photoelectric barrierfunction When activating this sequence point the display shows L rn and the following points are carried out e When photoelectric barrier testing is activated the number of photoelectric barriers connected is learned e The barrier closes e The barrier opens and learns the running time to open e The barrier closes and learns the running time to close and the force required Now this point is completed and you return to sequence point P102 In sequence point P101 various errors can occur which might lead to a cancellation In order to start the sequence point again press PROG briefly To cancel the function and to return to the main sequence press and hold PROG for approx 5s OR When learning the running time the barrier only moves once in direction OPEN or CLOSED and then stops Possible reasons The motor is faulty or one of the motor leads OPEN CLOSE or N is not connected correctly An error occurred during learning of the photoelectric barriers LS Check the connection of the photoelectric barriers see page 27 2 2 1 2 MO 64 monitored When an error is detected the learning of the barrier running time is terminated and r n 5 is displayed Possible reasons The motor is faulty or one of the moto
6. The controller is faulty Er i6 amp f fehler_stopredundanz An error occurred in the control logic The controller is faulty cr i f_eeprom_defekt EEPROM error 1 The controller is faulty Er iB f eeprom_checksummenfehler EEPROM error 2 Reprogram the controller Table 29 If an error occurs its number will be displayed If several errors occur at the same time the numbers will be displayed successively The controller has a 10 step error memory With each change the current error status will be stored together with the operating hours counter as timestamp The error memory can be queried and analyzed via the bus system 44 2 4 2 4 1 MO 64 Examples with induction loops Following the examples are described for the preprogrammed induction loop functions of page 33 P630 Induction loop modelt is shown how the required function can be realized by induction loop detection and directional logic For the examples described the controller provides pre settings which can be selected via the mode number Mode 1 Safety and closing with one loop The vehicle drives to the barrier The vehicle stops in front of the barrier The barrier is opened by an external command push button radio remote control bus system etc The vehicle passes the barrier Safety by loop A After passing the barrier it closes The closing command is issued when leaving loop A Induction loops Safety P545 0 The b
7. closes the barrier when it is fully open Otherwise it will be opened When automatic closure is locked and the counting function is activated then BT only opens and the counter of the counting function is incremented Closing by BT is not possible Configured as BTA3 same function as BTA1 and BTA2 Configured as BTZ1B same function as BTZ1A Push button OPEN 1 and 2 when configured also BTA3 The inputs BTA1 BTA2 and if applicable BTA3 are being evaluated independently of each another An OPEN command flank is triggered when one of the contacts is being closed As long as one of the contacts is closed the barrier cannot be closed stay open function The stay open time of the automatic closure is not triggered a new via BTA1 to BTAS Push button CLOSE 1A and if configured also BTZ1B The two inputs BTZ1A and BTZ1B are evaluated independent of each other A CLOSE command rising edge is issued when one of the contacts is being closed When the barrier is completely closed and at least one of the contacts BTZ1A or BTZ1B is closed then the barrier cannot be opened locking function Push button CLOSE 2 A CLOSE command rising edge is issued when the contact is opened BTZ2 has no locking function in end position CLOSED Push button Stop 1 e g desk top panel Evaluated is the contact status When the contact is open the barrier stops Stored commands are deleted Automatic closure is locked until the next operating com
8. H Protection circuitry Galvanic isolation 1kV electrical strength Table 21 2 2 6 2 Induction loop detection The induction loop detection of the MO 64 consists of three detectors two directional logics and one vehicle counter Numerous operating modes are possible through different combinations For each induction loop A B and C a detector is available When a vehicle drives on the loop the loop s inductivity drops If thereby the switching threshold is exceeded then the detector reports Loop occupied 2 2 6 3 Frequency range Using a DIP switch the loop frequency can be switched between Hi and Lo for each induction loop The three loops of the MO 64 work in multiplex mode and do not interfere with each other However if nearby another external loop is operated which coincidentally works with the same frequency this may lead to disturbances In this case the operating frequency of the loop of the MO 64 can be changed using the dip switch Lo ON Hi L1_2_3 JOFF Drawing 5 pie Seting loop Freuen 31 ELKA MO 64 2 OFF High frequency Table 22 Low frequency B Low frequency 2 2 6 4 P601 P603 Sensitivity stages of loops A B C The sensitivity of the induction loops is adjustable in 8 steps Each loop can be adjusted individually The frequency of the induction loops is learned When a vehicle drives over a loop the frequency changes The more sensitive a loop detection is adju
9. Installation and operating instructions Barriers ES 25 ES 80 Part 2 Controller MO 64 Translation of original installation and operating instructions D ID V1_3 01 14 ELKA Torantriebe GmbH u Co Betriebs KG Phone 49 0 48 61 96 90 0 Dithmarscher Str 9 Fax 49 0 48 61 96 90 90 25832 T nning E mail info ELKA Torantriebe de Germany Internet www ELKA Torantriebe de Index of contents 1 1 1 1 1 1 1 2 1 3 2 2 1 2 1 1 2 1 2 2 1 3 2 1 4 2 1 5 2 1 6 2 1 2 2 2 2 1 2 2 2 2 2 3 2 2 4 2 2 9 2 2 6 2 21 2 2 8 2 3 2 4 2 4 1 2 4 2 2 4 3 2 4 4 2 4 5 2 4 6 2 4 2 4 8 Preface General notes Symbol explanation Copyright Information regarding installation instruction Controller MO 64 Connections der MO 64 Connection diagram 64 Inputs Outputs LED display Power supply Connection for RS485 system Connection for TCP IP module Learning sequence Sequence P100 Basic functions sequence P200 Configuration the bus system Sequence P300 Setting time Sequence P400 Setting of counters Sequence P500 Various operating modes Sequence P600 Induction loops basic settings Sequence P700 Induction loop free operating mode Sequence P800 Factory settings Error messages Examples with induction loops Mode 1 Safety and closing with one loop Mode 2 Safety and closing with two loops Mode 3 Opening safety and closing with
10. a An antenna with coaxial plug or blade terminal 2 8mm can be connected Table 1 2 1 3 Outputs 230Vac max 7A Uext 24V 24Vdc stabilized short circuit proof monitored Max 500mA in total with Uext 12V max 700mA Uext 12V 12Vdc stabilized short circuit proof monitored Max 500mA in total with Uext 24V max 700mA The multi functional relays Multi1 to Multi4 are potential free contacts With these contacts max 24V 1A can be switched The relay contacts are n o contacts During power failure the contacts are open For each relay the operating mode can be set individually See page 22 Multi5 The multi functional relay Multis can switch 230Vac max 120W It is not potential free The function of the red traffic light is configurable preset is the operating mode red traffic light See page 22 Multi6 The multi functional relay Multis can switch 230Vac max 120W It is not potential free The function of the red traffic light is configurable preset is the operating mode red traffic light See page22 Table 2 MO 64 LED display Mark _ Golour Function IS A red Is lit when the corresponding induction loop is IS B occupied IS C Funk red Is lit when the learned radio remote control code is received Display red Serves to set operating modes parameters and displays error messages Table 3 2 1 6 2 1 7 MO 64 Power supply Temin Function OOOO O Neutral conductor m
11. aaaresnnenttea 26 Photoelectric barrier mode 26 Photoelectric barrier testing 2 Power supply cccceeceece eee ees 8 Pre warning time closing 20 Pre warning time Opening 20 push button function 25 R radio remote control code 17 Radio remote control receiver Optional ccseceeeeees 4 RS485 Barrier address 18 FUNNING TIME ccceeeeeeeeeeeeees 16 Running time limitation 30 S Sensitivity stages of loops 32 Service COUNTET ecceeee sees 21 Setting a NUMbET ceee 10 Setting the loop logic 35 Socket for additional board 4 Socket for foil keypad 4 Socket for radio remote control ECONO sect cccorunientnebnevanaausntnnanendoon 4 Socket port number 18 Stay Open tiMe ceceeeee eee 20 Subnet MASK ccceccseeeeeeeeeees 18 Symbol explanation 00 3
12. ains connection 230V 50Hz Phase L1 mains connection 230V 50Hz Table 4 Connection for RS485 system terminal Function Bus terminal resistor for lead D a Bus terminal resistor for lead D Ground connection bus cable shielding Table 5 The bus interface is galvanically isolated from the controller Connection for TCP IP module Alternatively instead of the RS485 bus system a TCP IP module can be plugged on The module then has an RJ45 socket MO 64 Learning sequence lt lo D UP PROG DOWN Il lt Oo Drawing 2 To program the controller and to set the operating parameters a four digit7 segment display and a joystick 1 are available on the control board The joystick has the functions UP DOWN and PROG A foil keypad 2 with three keys can be connected optionally The three keys of the foil keypad correspond to the joystick functions UP DOWN and PROG In the following description the writing format below will be used Push the joystick upwards or press the upper key of the foil keypad Push the joystick downwards or press the lower key of the foil keypad Push the joystick down in the middle or press the central key of the foil keypad The Learning Sequence consists of the Main Sequence and the Sub Sequences During normal operation the display is switched off Only the decimal point of the units digit flashes as stand by indicator and the decimal poi
13. arrier opens when a vehicle drives on loop A during closing After passing the barrier it closes The closing command is issued when leaving loop A Induction loops Safety P545 1 After passing the barrier it closes The closing command is issued when leaving loop A The barrier stops when a vehicle drives on loop A during closing After driving backwards and clearing loop A the barrier closes 45 EIKA MO 64 Table 30 2 4 2 Mode 2 Safety and closing with two loops The vehicle drives to the barrier The vehicle stops The barrier is opened by an external command Safety by loops A and B When leaving loop B a closing command is issued but safety through loop A is active When leaving loop A a closing command is issued Table 31 46 ELKA 2 4 3 MO 64 Mode 3 Opening safety and closing with two loops Table 32 The vehicle drives to the barrier When driving on loop B the barrier opens The distance between loop B and A has to be less than the length of the vehicle When leaving loop B a closing command is issued Yet the barrier remains open since safety through loop A is active When leaving loop A the barrier closes Behaviour when a second vehicle follows When leaving loop B a closing command is issued Yet the barrier remains open since the safety loop A is occupied When the second vehicle drives on loop B an Opening signal is issued At the same time the
14. assing over the loop can e g be used for the vehicle counting 35 MO 64 The loops used for the directional logic may be placed max one vehicle length apart from each other Description sequence point Allocation of the inputs Opening or closing when passing from the left Opening orclosing whenpassing fromthe right Vehicle countingwhen passing from the left Vehicle counting when passing from the right Opening andclosing whenentering fromthe left Opening and closing when entering from the right oO deactivated P730 E Sequence point for directional logic 2 P740 Sequence point for directional logic 1 Set up Function left loop A right loop B 2 left loop B right loop A left loop A right loop C left loop C right loop A left loop B right loop C left loop C right loop B decrement counter 1 increment counter 1 decrement counter 1 P741 P742 P743 P744 P745 P746 Reporting or f0 no function P737 p747 36 blocking reporting presence presence when blocking presence entering from report the left Reporting or oO no function ec reporting presence presence pepening presence when blocking presence entering from report the right Table 27 37 2 2 8 1 2 2 8 2 MO 64 Sequence P800 Factory settings P801 ELKA factory setting V Cli
15. be set the currently selected numerical value is shown in the display Using UP the number can 10 MO 64 be increased 1 Using DOWN the number can be decreased 1 The number can scroll through when UP or DOWN is kept actuated e When UP is kept actuated after a delay of 1 3s the number will be increased by 10 every 0 3s e When UP is kept actuated further after another delay of 3s the number will be increased by 100 every 0 4s e When UP is kept actuated further after another delay of 4s the number will be increased by 1000 every 0 5s If the permissible maximum value is exceeded the numeric value is set to the permissible maximum value If the displayed number has a decimal place then this will be scrolled through set to zero during automatic increasing of the number The decreasing using DOWN happens in the same manner When the required number is set leave the Sequence point using PROG onunce somence pege sequence sequence page P100 Basicfunctions a a photoelectric barriers Piz 17 Radio remote control code PIPP _ Retum to main sequence to P200 P200 Configuring the bus system P 18 RS485 barrier address IP address Byte 1 gt Pam 18 PaddressByte2 P212 18 IP address Bytes Pas ia Paddress Bytes P 18 Gateway address Byte1 P21 18 Gateway address Byte2 P222 18 Gateway address Bytes P23 18 Gateway address Byte4 P230 18 SubnetmaskBytet
16. e barrier The vehicle stops on loop B The barrier controller reports the presence to the ticket dispenser The barrier is opened by an external command When leaving loop B a closing command is issued Safety by loop A When leaving loop A a closing command is issued but is not executed since by occupying loop C an opening command is issued and safety by loop C is active Leaving of loop C closes the barrier The vehicle drives to the barrier When driving on loop C the barrier opens When leaving loop C a closing command is issued but is not executed since safety by loop A is active When leaving loop A the barrier closes Loop B issues a presence report as long as the barrier is occupied but has no opening or safety function 50 ELKA MO 64 2 4 6 Mode 6 Opening with directional logic safety and closing with three loops The vehicle drives to the barrier The vehicle drives on loop C There is no Opening command issued yet The vehicle additionally drives on loop B Now an opening command is issued When passing loop C and B from the left side no closing command issued Safety by loop A Leaving loop A closes the barrier The vehicle drives to the barrier The barrier is opened by an external opening command Safety by loop A Leaving loop A closes the barrier When passing loop B and C from the right side no further commands are issued Table 37 51 ELKA MO 64
17. elete the counter and leave the sequence point push PROG for 5s To leave the sequence point push PROG briefly P630 Induction loop mode In chapter Examples with induction loops starting on page 45 eight examples for induction loops are described The settings of the loop logic for these examples are stored in the controller Only the number of the mode has to be set Alternatively you can adjust the loop logic manually as described in chapter Sequence P700 Induction loop free operating mode starting onPage 35 By activating of sequence point P630 it is checked if the current configuration of the loop logic corresponds to one of the predefined modes When it corresponds the number of the mode is displayed otherwise the number 9 is displayed Display Description See also 33 MO 64 o mosean i Mode 1 Safety and closing with one loop Page 45 Mode 5 Presence opening safety and closing with Page 50 three loops 1 Mode 6 Opening with directional logic safety and Page 51 closing with three loops Mode 7 Opening safety and closing with three loops Page 52 Mode 8 Opening safety and closing with three loops Page 54 Table 25 The set operating mode does not correspond to any of the predefined loop modes The set operating mode is not changed if the sequence is left at this point 34 ELKA 2 2 1 2 2 1 1 2 2 1 2 MO 64 Sequence P700 Induction loop free operating mode
18. em Display Function SSS sO Self holding function Table 18 The safety devices LS SLZ force and safety by induction loops are active during closing and cause stop 29 2 2 9 12 2 2 9 13 MO 64 For the function Dead man s mode a bridge between 5top and 5Sbottom has to be set at the terminal row X1 alternatively a switch with an n c contact P548 Running time limitation When a limit switch is faulty or misaligned and thus does not report that the end position has been reached then the controller switches the motor off after 125 of the learned running time Under P548 can be selected if the controller remains operable or if it interlocks Display Function No interlocking after switching off by running time limitation Interlocking after switching off by running time limitation Table 19 P549 Boom missing function Under sequence point P549 can be selected if an error message Boommissing is generated and the barrier stops when the boom missing contact is interrupted or if only the error message Boom missing is generated and the barrier can continue to be operated Display Function o ce No stop at boom missing message Stop at boom missing message Table 20 30 EIKA MO 64 2 2 6 Sequence P600 Induction loops basic settings 2 2 6 1 Technical data loop detectors Loop inductivity Permissible range 30UH to 450uUH Recommended range 50UH to 300U
19. em within CEN countries must also be conformant with the European safety relevant directives and standards We reserve the right to make technical improvements without prior notice 1 1 1 1 2 1 3 MO 64 Symbol explanation Remarks regarding the safety of persons and the gate opener itself are marked by special symbols These remarks have to be absolutely observed in order to avoid accidents and material damage DANGER points to an imminent dangerous situation which can cause death or serious injuries if it is not avoided WARNING points to a potentially dangerous situation which can cause death or serious injuries if it is not avoided ATTENTION points to a potentially dangerous situation which can cause minor or slight injuries if it is not avoided ATTENTION points to a potentially dangerous situation which can cause property damage if it is not avoided REMARK Important notice for installation or functioning Copyright The operating manual and the contained text drawings pictures and other depictions are protected by copyright Reproduction of any kind even in extracts as well as the utilization and or communication of the content without written release certificate are prohibited Violators will be held liable for damages We reserve the right to make further claims Information regarding installation instruction This document is to be used as installation instruction for
20. ent memory Production Configuration memory P802 TCP RS485 JE Drawing 6 When the controller is dispatched the configuration memory and the client memory are preset with the factory setting During operation the controller works with the parameters of the configuration memory During learning and configuring whether learning the running distance configuring by display and joystick or via bus the data in the configuration memory are changed and stored Only with a command via bus system the complete contents of the configuration memory can be transferred to the client memory Also data like motor running time will be transferred to the client memory However data like service counter maintenance counter or error memory etc will not be transferred Writing on the client memory via the learning sequence is not possible When resetting to factory settings it is distinguished between transferring the factory setting or the contents of the client memory into the configuration memory The transferring of the client memory to the configuration memory can only be realized via the learning sequence and not via the bus system P801 Reset to factory settings To reset the controller to the factory settings sequence point P801 is activated The display shows r Q Now press PROG for 5s The display shows UU D Q and the factory setting is re established After that the sequence point is left Is PROG pushed only br
21. esence is reported to both ticket dispensers i The functions described above also apply to the opposite direction 54 Index 4 4x7 display ccceecceeceseeceeeee eee 4 A Additional board for RS485 OPUN aaa 4 Additional board for TCP IP optional ccccsecceeeeseeeeeeeeeeees 4 Antenna socket 0cecececeeeeeees 4 Automatic CIOSUIE ce ecee 20 C Connection diagram 64 4 Connection for RS485 system 8 Connection limit switches 4 Connection motor mains etc 4 counting function cee 21 D Dead man s mode 0 000 29 DIP SWItCNES ccccceccececcacenees 4 directional lOQIC cccceeeee es 35 E Error messages 43 Examples with induction loops 33 45 F Factory settings ccccceeeeees 38 Foil keypad optional 4 Frequency range cceeeeeees 31 G Gateway address 06cceeee 18 H Hold time stages of loops 33 Induction loop mode 33 45 IP address wiz vsderniavertcanceseaeiwacteronan 18 MO 64 J JOY SUCK caconansenesrnanenesvontcuctianenroeunaes 4 L Learning Sequence 9 LED GIS OIA wcesaitned deocinceeiaraceane ss 7 Loop readjustment 00 33 M MICrOTUSE cas ceantrnsens ins isanne 4 multi functional relay 22 23 24 25 P Photoelectric barrier closing automatic cxsucetcucntvonaaneuna
22. frome C em fe fion reasuemencorer iona Jeet e reason conero C r Sa fiora conero C feo fe fearann reer frente man soqins 6 a0 Fm __ soe racion op ens mana ee Loop A function during entering the loop safety SS P703 Loop A function when leaving the loop I P704 Loop A presence o P71 Loop B switching on off Loop B function during entering the loop safety e P713 Loop B function when leaving the loop P714 Loop B presence P721 Loop C switching on off P722 35 Loop C function during entering the loop safety P723 Loop C function when leaving the loop P724 Loop C presence P730 Directional logic 1 input selection P731 35 Directional logic 1 opening and closing when passing from the left P732 35 Directional logic 1 opening and closing when passing from the right P733 35 Directional logic 1 vehicle counting when passing from the left P734 35 Directional logic 1 vehicle counting when passing from the right P735 35 Directional logic 1 opening and closing when entering the loop from the left P736 Directional logic 1 opening and closing 14 MO 64 Main Sub Starting sequence sequence page E when entering the loop from the right P737 Directional logic 1 reporting presence or blocking presence when entering the loopfrom the left P738 Directional logic 1 reporting presence or blocking presence when entering the loopfrom the right P740 35 00 Directional logic 2 input selecti
23. g can be set within the range of 0 0s to 655 0s With a value of 0 0s the pre warning time before closing is deactivated Factory setting 0 0s no pre warning time before closing 20 ELKA 2 2 4 2 2 4 1 2 2 4 2 2 2 4 3 MO 64 Sequence P400 Setting of counters P401 Maintenance interval With each barrier movement the service counter is incremented 1 A maintenance signal is issued when the service counter value is higher than the set maintenance interval The maintenance message can be signalled e g through a multi functional relay The setting range is 1000 to 9999000 inmultiples of 1 000 Factory setting 250 corresponds to 250 000 The controller features an operating hour counter Readout is possible via the bus system P402 Service counter Under sequence point P402 the value of the service counter can be displayed and deleted With each barrier movement the service counter is incremented 1 The service counter is displayed in multiples of 1 000 only Example The display 3456 stands for more than 3 456 000 and less than 3 457 000 movements To leave this sequence point push PROG briefly To delete the service counter and leave the sequence point push PROG for 5s P410 P411 Upper and lower limit of the counting function The barrier is controlled by a command counter Each OPEN command increments the counter 1 each CLOSE command decrements the counter 1 The switching of the pro
24. gram counter from 0 to 1 actuates the opening the switching of the program counter from 1 to O actuates the closing of the barrier The counter can be incremented to the upper limit and can be decremented to the lower limit The adjustment range for the lower limit is 9 to O and for the upper limit 1 to 9 Example lower limit 0 upper limit 3 With 3 consecutive OPEN commands the counter is set as follows 0 1 2 3 The barrier opens once and remains in position OPEN With 2 consecutive CLOSE commands the counter is set as follows 3 2 1 The barrier remains in position OPEN The switching from 1 to 0 and thus the closing of the barrier occurs only after another CLOSE command Factory setting upper limit 1 Factory setting lower limit O 21 ELKA 2 2 9 2 2 9 1 MO 64 Sequence P500 Various operating modes P501 P506 Operating modes for multi functional relay 1 to multifunctionalrelay 6 The controller features four potential free multi functional relays Multi1 to Multi4 which can switch 24V 1A as well as two multi functional relays Multi5 and Multi6 which can switch 230V 120W The operating mode of the six multi functional relays can be selected according to the following table message is ae piayen on the controller Maintenance The multi functional relay is activated when the service counter value is higher than the set maintenance interval Boom missing message The multi functiona
25. her a number within the range of 00000 to 65535 is set Factory setting 52719 0xcdef 19 ELKA 2 2 3 2 2 3 1 rss fms fs 2 2 3 2 2 2 3 3 MO 64 Sequence P300 Setting time P301 Stay open time Automatic closure The barrier can close automatically When automatic closure is selected the learned stay open time starts to run as soon as the barrier has reached the end position OPEN The barrier closes automatically when the stay open time has elapsed The stay open time for automatic closure can be set under P301 with a range of 0 0s to 655 0s With a value of 0 0s the automatic closure is deactivated Factory setting 0 0s no automatic closure When the barrier is open and a stop command is given the automatic closure is locked The automatic closure will only be unlocked again when a new command is given After power up or after completion of the learning a completely open barrier with automatic closure selected closes after the stay open time has elapsed The stay open time of the automatic closure is not retriggered via BTA1 to BTA3 P302 Pre warning time opening Under sequence point P302 pre warning time before opening can be set within the range of 0 0s to 655 0s With a value of 0 0s the pre warning time before opening is deactivated Factory setting 0 0s no pre warning time before opening P303 Pre warning time closing Under sequence point P303 pre warning time before closin
26. iefly the sequence point is left without changing the data P802 Reset to client s factory settings To reset the controller to the client s factory settings sequence point P802 is activated The display shows r Now press PROG for 5s The display shows UU D and the client s factory setting is re established After that the sequence point is left Is PROG pushed only briefly the sequence point is left without changing the data 38 ELKA MO 64 Only by command via the bus system the complete content of the configuration memory can be transferred to the client memory Therby also data like motor running time are transferred into the client memory Not transferred are data like service counter maintenance counter and error memory etc Writing into the client memory is not possible via the learning sequence 2 2 8 3 Factory settings 39 MO 64 P401 250000 MO 64 P542 0 MO 64 P730 0 Table 28 42 MO 64 Error messages Error messages may be acknowledged by pushing PROG briefly The barrier is operational again until the next error message is issued The controller monitors 18 different operating parameters and if an error occurs it generates and displays an error message Display Telegram description Corresponds to Er g i The contact boom missing is open f fehler_sea_defekt Limit switch OPEN is faulty misaligned Check the limit switch OPEN f fehler_sez_ defekt Limi
27. ight but can also be usedotherwise see P501 P506 Operating modes for multi functional relay 1 to multifunctionalrelay 6 The following table shows the possible operating modes for the green trafficlight Sequence point P520 P521 P522 P523 P524 P525 P526 Green traffic light in end position OPEN Green traffic light in end position CLOSED Green traffic light at prewarning before opening Green traffic light at prewarning before closing Green traffic light during opening Green traffic light during closing Green traffic light during intermediate stop isplay Operating Factory mode serne off on flashing off on flashing off on flashing off on flashing on flashing off on ere 24 ELKA MO 64 sting Table 10 2 2 5 4 P530 P536 Operating modes for warning light No separate relay is available for the warning light The warning light can be connected to a multi functional relay The multi functional relay has to be set to the operating mode warning light see P501 P506 Operating modes for multi functional relay 1 to multifunctionalrelay 6 The following table shows the possible operating modes for the warning light Sequence Operating Factory point mode setting P530 Warning light in end off O position CLOSED Display 0 ff 1 on 2 flashing P531 Warning light at 0 off on prewarning before opening 1 on 2 flashing P532 Warni
28. in end position CLOSED In end position OPEN it is deactivated In 2 2 5 2 MO 64 Display Operating mode Function Presence The multi functional relay is activated when the induction loop detection reports presence Occupied message loop A static The multi functional relay is activated when loop A is occupied Status message loop A The multi functional relay is activated when loop A is activated is not faulty and not occupied Occupied message loop A impulse the multi functional relay issues a pulse when loop A is being occupied Clearing message loop A impulse the multi functional relay issues a pulse when loop A is being cleared Occupied message loop B static The multi functional relay is activated when loop B is occupied 20 Status message loop B The multi functional relay is activated when loop B is activated is not faulty and not occupied 21 Occupied message loop B impulse the multi functional relay issues a pulse when loop B Is being occupied Clearing message loop B impulse the multi functional relay issues a pulse when loop B is being cleared Occupied message loop C static The multi functional relay is activated when loop C is occupied Status message loop C The multi functional relay is activated when loop C is activated is not faulty and not occupied Occupied message loop C impulse the multi functional relay issues a pulse when loop C is being occupied C
29. l relay is activated when the boom missing contact is opened Tandem operation The multi functional relay is activated when the barrier is not in end position CLOSED It is already active during pre warning before opening Red traffic light configuration see P510 P516 Operating modes for red traffic light Green traffic light configuration see P520 P526 Operating modes for red traffic light Warning light configuration see P530 P536 Operating modes for warning light between the positions it flashes End position OPEN The multi functional relay is activated when the barrier is open During pre warning before closing clearance time the relay is already deactivated End position CLOSED electromagnet The multi functional relay is activated when the barrier is closed During pre warning before opening the relay is already deactivated REMARK for the use with an electromagnet additionally the prewarning time before opening has to be set to min 1 5 seconds P302 Bus relay the multi functional relay is activated via the bus switching on and off 1 second pulse Photoelectric barrier testing the multi functional relay activates the supply for the photoelectric barrier transmitters during photoelectric barrier testing see 27 Presence The multi functional relay is activated when the induction loop detection reports presence 22 LED boom lighting The multi functional relay is activated
30. learing message loop C impulse the multi functional relay issues a pulse when loop C is being cleared Table 8 The multi functional relays work independent from each other Therefore it is possible to select the same function for more than one relay P510 P516 Operating modes for red traffic light The controller features two multi functional relays for 230V The multifunctional relay 6 is provided for a red traffic light but can also be used otherwise see P501 P506 Operating modes for multi functional relay 1 to multifunctionalrelay 6 The following table shows the possible operating modes for the red traffic light Sequencepoint Display Operating factory mode setting off on Red traffic light in end 0 position CLOSED 1 on 2 flashing P511 Red traffic light at 0 off flashing prewarning before 1 on 23 2 2 9 3 evening Table 9 Red traffic light at prewarning before closing Red traffic light during opening Red traffic light during closing Red traffic light during intermediate stop Red traffic light in end position OPEN 0 1 2 0 1 2 0 off 1 on 2 flashing 0 1 2 0 1 2 MO 64 fasting off flashing on flashing off on flashing on flashing off on flashing E H E P520 P526 Operating modes for red traffic light The controller features two multi functional relays for 230V The multifunctionalrelay 5 is provided for a green traffic l
31. light RtApl in end position OPEN 12 MO 64 Main Sub Starting sequence sequence page P520 Green traffic light GnApl in end position CLOSED 24 Green traffic light GnApl at pre warning before opening 24 Green traffic light GnApl at pre warning before closing P23 24 Green traffic light GnAp during opening P524 24 Green traffic light GnApl during closing 24 Green traffic light GnApl at intermediate stop 24 Green traffic light GnApl in end position OPEN e Warning light in end position Warning light in end position CLOSED Warning light at pre warning before opening Warning light at pre warning before closing P538 f25 Waring light during opening P534 25 Waring light during closing Ps5 f25 Waring light at intermediate stop o a Selection push button function BT BTA3 BTZ1B o da f P5a2 26 Photoelectric barrier mode _ P5as 26 Photoelectric barrier closing automatic Psa 27 Photoelectric barrier testing P5 29 Induction loops safetymode P56 29 Immediate closing Psa Deadman smode P5a s 3o interlocking after running time limitation P5 fso Boom missing function a ee PsPp__ Retur to main sequence to P600 Poo __ Induction loops basic settings Peon f32 Sensitivity stageLoopA P6eo2 j32 Sensitivity stageLoopB 13 MO 64 onunce somone pago sequence sequence page C e fe Sorens eo TT S CT e fe
32. mand Push button Stop 2 e g emergency release Evaluated is the contact status When the contact is open the barrier stops Stored commands are deleted Automatic closure is locked until the next operating command The Boom missing contact opens when the barrier boom brakes off When the contact is open the barrier shows the error message amp U on the display Via bus system it can be configurated if the barrier stops as long as boom missing is reported or if only the error EIKA MO 64 mpat Contact Funn message is issued A system of up to six photoelectric barriers LS whose contacts are connected in series The ual opens when the photoelectric barrier detects an obstacle The LS is not monitored during opening When LS reports an obstacle the barrier cannot be closed The stay open time of the automatic closure is not started a new retriggering Further functions photoelectric barrier testing see page 27 photoelectric barrier closing automatic see page 26 Limit switches OPEN and CLOSED The contact of the limit switch opens at the corresponding end position SEA SEZ 8 2kOhm Safety contact profile SLZ with 8 2kOhm resistor to secure the closing movement When SLZ reports closing is not possible When SLZ reports during closing stop and opening follows SLZ is tested before every closing movement When the test fails closing is not possible An error message is issued Antenn
33. ned which function shall be activated by the induction loop during safety mode Display 0 Stop and immediate opening Stop FREEZE i Table 16 The function and closing after clearance of the induction loop is realized by activating the function Closing when leaving the loop at the corresponding loop FREEZE Set the parameter P545 to 1 Additionally activate the function Closing when leaving the loop under the parameters P703 P713 and P723 at the corresponding loop 2 2 5 10 P546 Immediate closing Under sequence point P546 can be selected how the barrier should react if a closing command is issued during the opening movement The closing command is stored i e the barrier first opens completely and then at the end position OPEN executes the closing command 1 The closing command is executed immediately i e the barrier stops and then closes instantly Table 17 2 2 5 11 P547 Dead man s mode Under P547 is specified if the barrier shall work in dead man s mode or in self holding function In dead man s mode the barrier can only be opened andclosed by OPEN and CLOSE commands as long as the command is actually present OPEN commands are signals at the inputs BTA1 BTA2 and BTA3 additionally the command BUS_BA Pegel via the bus system CLOSE commands are signals at the inputs BTZ1A BTZ1B und BTZ2 additionally the command BUS_BZ Pegel via the bus syst
34. ng light at 0 off on prewarning before closing 1 on 2 flashing P533 Warning light during 0 off on opening 1 on 2 flashing Warning light during 0 off on closing 1 on 2 flashing Warning light at 0 off off intermediate stop 1 on 2 flashing Warning light in end 0 off off position OPEN 1 on 2 flashing Table 11 2 2 5 5 P540 Selection push button function BT BTA3 BTZ1B Only a mutual input is available for the functions BT BTA3 and BTZ1B Under sequence point P540 can be selected which function the input has BT push button with sequence logic The operating sequence of BT depends on the operating mode of the automatic closure and the counting function 1 BTA3 push button OPEN The barrier opens when the contact is closed 2 BTZ1B push button CLOSE The barrier closes when the contact is closed Table 12 25 FLKA MO 64 2 2 5 6 P542 Photoelectric barrier mode The controller monitors the photoelectric barrier input during closing of the barrier Under sequence point P542 can be set how the controller shall react when the photoelectric barrier reports Display Function O co Stop and immediate opening Table 13 The function and closing after clearance of the photoelectric barrier is realized by the use of photoelectric barrier closing automatic P543 2 2 5 7 P543 Photoelectric barrier closing automatic When the photoelectric barrier closing automatic is activated the photoelec
35. nt of the thousands digit is lit when a TCP socket connection is established Navigation in the Learning Sequence using the joystick and the foil keypad The Main Sequence is activated when PROG is pushed for a period of approx 2s The display then shows P i U You may navigate within the Main Sequence using the functions UP and DOWN When the required Main Sequence point is selected use PROG for activation Now you can reach the MO 64 Sub Sequence points e g P101 Using the functions UP and DOWN you may navigate within the Sub Sequence When the required Sub Sequence point is selected use PROG for activation Here the selected parameter can be set now Using function PROG you reach the next Sub Sequence point In order to leave the Sub Sequence use UP or DOWN to navigate to the exit e g P1PP and push PROG Now you automatically get to the next sequence point of the Main Sequence In order to leave the Main Sequence use UP or DOWN to navigate to the exit of the Main Sequence PPPP Using PROG saves the data in the EEPROM and ends the learning sequence Normal operation Learning function i l Setting a parameter or PPPP P2PP DOWN UF DOWN UP oo PROG oo DOWN UP DOWN UP DOWN UP PROG DOWN UP DOWN UP DOWN UP Drawing 3 Setting a number The input of a number in the menu is always carried out the same way and therefore is only described at this point When activating a Sequence point where a number shall
36. ntroller MO 64 up to 6 photoelectric barriers can be connected and tested Therefore all relay outputs of the receivers are connected in series The MO 64 has to learn how many photoelectric barriers are connected Therefore one resistor of 1kOhm has to be connected parallel to the relay contacts of each receiver Then the photoelectric barrier testing has to be activated and the running distance of the barrier has to be learned P101 Now each photoelectric barrier has to be tested for correct functioning 27 MO 64 Function example six photoelectric barriers are connected to the MO 64 supply voltage 24Vdc One 1kOhm resistor is switched parallel to the output of each photoelectric barrier The supply voltage of the photoelectric barrier transmitters is switched via the multi functional relay 1 s1 one B17 nni 27 3 T E k k d gt E S 3 VIS ai ene s6 E6 p GO E MULTI 4 24V GND MO 64 Drawing 4 S1 S6 Photoelectric barrier transmitter E1 E6 Photoelectric barrier receiver Under sequence point P544 can be selected if the photoelectric barrier testing is activated or deactivated Display Function S oO ooo Photoelectric barrier testing is deactivated Photoelectric barrier testing is activated Table 15 28 ELKA MO 64 2 2 5 9 P545 Induction loops safety mode One or more induction loops can have the function safety Under P545 is determi
37. on P741 35 Directional logic 2 opening and closing when passing from the left P742 35 Directional logic 2 opening and closing when passing from the right P743 35 Directional logic 2 vehicle counting when passing from the left P744 35 Directional logic 2 vehicle counting when passing from the right P745 35 Directional logic 2 opening and closing when entering the loop from the left P746 35 Directional logic 2 opening and closing when entering the loop from the right P747 35 Directional logic 2 reporting presence or blocking presence when entering the loop from the left P748 35 Directional logic 2 reporting presence or blocking presence when entering the loop from the right PPP _ Return tomain sequence to P800 Psoo Reset Peo fas Reset to ELKA factory settings _ P02 38 Reset toclient s factory settings Papp Return to main sequence toPPPP PPPP Storing the data and exiting the learning sequence Table 6 15 2 2 1 1 MO 64 Sequence P100 Basic functions WARNING During programming of sequence point P101 the motor and thus ALL moving parts starts moving INDEPENDENTLY Rotating and or linear movable components can cause serious injuries gt Do not reach into moving parts or handle any moving components during operation The following LEDs must light up during operational readyness of the barrier e LED BTS2 emergency release e LED Bm boom missing contact e LED
38. partly completed machinery according to machinery directive 2006 42 EG article 13 2 ELKA 2 1 2 1 1 11 12 D Om J G Controller MO 64 Connections der MO 64 Connection diagram 64 MO 64 The following drawing shows an overview of the controller a oon 7 it j a om 4 F 4 P a i Drawing 1 Connection induction loops LED for push button Connection push button LED limit switches etc Connection limit switches etc 4x7 display Joystick Socket for foil keypad Connection multi functional relays Connection DC power supply Transformer Connection motor mains etc 13 14 15 16 17 18 19 20 21 22 23 DIiP switches frequency change induction loops Socket 1 for additional board Socket 2 for additional board Socket for radio remote control receiver Antenna socket for coaxial plug Antenna socket for 2 8mm blade terminal Microfuse T6 3A Additional board for RS485 optional Additional board for TCP IP optional Radio remote control receiver optional Foil keypad optional 2 1 2 Inputs MO 64 Input conect Function BT BTA3 BTZ1B n O Configurable input BT or BTA3 or BTZ1B Preset is BT Configured as BT BT with sequential logic The operating sequence of BT depends on the operating mode of the automatic closure and the counting function When automatic closure is activated or when the counting function is deactivated then BT
39. r leads OPEN CLOSE or N is not connected correctly Table 7 P102 Learning and deleting the radio remote control code When activating this sequence point the display first shows if a radio remote control code is learned display H H H H no code display Learning the radio remote control code Push PROG briefly The display shows 5 E na Send the desired radio remote control code by activating the coded transmitter When a code is received g o o oa is displayed Now you return to the main sequence P1PP Deleting the radio remote control code Push and hold PROG The display shows 5 md After 5s the display changes to Nowrelease PROG The radio remote control code is deleted Now you return to the main sequence P1PP Cancellation without changing the radio remote control code Push PROG briefly The display shows 5 ne Push PROG briefly onceagain Now you return to the main sequence P1PP 17 ELKA 2 2 2 2 2 2 1 2 2 2 2 2 2 2 3 2 2 2 4 2 2 2 5 MO 64 Sequence P200 Configuration the bus system P201 RS485 Barrier address Here the RS485 bus address is set decimally Allowed are the addresses 16 0x10 to 254 OxFE Factory setting 16 P210 P213 IP address The 4 bytes of the IP address are set in decimal format under P210 to P213 Example for 192 168 0 200 perform the following settings e P210 192 e P211 168 e P212 0 e P213 200 Factory set
40. sted the smaller the frequency changes which can be detected Sequency Loop Setting range 2 4 Table 23 32 2 2 6 5 il il 2 2 6 6 2 2 6 7 MO 64 P610 P612 Hold time stages of loops A B C Is the barrier occupied for longer than the adjusted hold time a readjustment of the loop is performed Is the hold time infinite 2 selected no readjustment is performed ATTENTION If Closing when leaving the loop is selected under sequence point P702 P713 or P723 the barrier closes after readjustment independently Sequence Loop Setting range att ooo i omes 1 2 Ee Le Is the hold time set to infinite then through temperature drift while the loop is occupied the leaving of the loop cannot be detected anymore Table 24 Is a finite hold time selected and a vehicle stays on the loop then after expiry of the hold time a readjustment of the loop will be executed The loop will report not occupied even though a vehicle stands on the loop For passenger car traffic only and a lower sensitivity stage a longer hold time can be selected For a very high sensitivity stage a short hold time should be selected P620 P622 Loop readjustment counter display and deletion Each totally completed readjustment of each induction loop is counted The counter can count up to 9999 Sequence point P620 is for loop A P621 is for loop B and P622 is for loop C To d
41. t is built ELKA Torantriebe GmbH u Co Betriebs KG cannot recognise every possible source of danger in advance If the appliance is used other than in the recommended manner the user must ascertain that no danger for himself or others will result from this use He should also ascertain that the planned use will have no detrimental effect on the appliance itself The appliance should only be used when all safety equipment is available and in working order All faults which could be a source of danger to the user or to third persons must be eliminated immediately All warning and safety notices on the appliances must be kept legible All electrical periphery equipment which is connected to the appliance must have a CE Mark which ensures that it conforms to the relevant EEC regulations Neither mechanical nor electrical alterations to the appliance without explicit agreement of the manufacturer are allowed All alterations or extensions to the appliance must be carried out with parts which ELKA Torantriebe GmbH u Co Betriebs KG have defined as suitable for such alterations and be carried out by qualified personnel Please note that with any alteration of the product no matter whether mechanical or electrical the warranty expires and the conformity is revoked Only the use of ELKA accessories and original ELKA spare parts is allowed In case of any contravention ELKA disclaims liability of any kind INFORMATION The operation of the syst
42. t switch CLOSED is faulty shifted Check the limit switch CLOSED f fehler sea_sez_ gleichzeitig Both limit switches report at the same time Check the limit switches f uext 12v defekt Uext 12V is not within the permitted range overload Check the connection f uext 24v defekt Uext 24V is not within the permitted range overload Check the connection f schleife_a_ defekt The frequency of loop A B or C is m not within the permitted range u f_schleife_b_defekt Check the induction loop If f_schleife_ c defekt necessary change the frequency range iu f_Istest_fehler An error occurred during photoelectric barrier testing Check the photoelectric barriers gt rr an a ZJ ay f_ slztest_fehler An error occurred during safety contact profile testing Check the safety contact profile f uc_lern_fehler The reference value for the power reversal could not be learned Check motor and motor capacitor iJ f_relais_defekt An error in the power element was detected A relay is faulty the controller locks f triac_defekt An error in the power element was detected The triac is faulty the controller locks Remark In case one of the motor leads OPEN or CLOSE is not connected the controller also 43 j fm MO 64 detects a fault in the power element Please check first if the motor is connected correctly r 5 f fehler_registertest An error occurred in the control logic
43. ting 192 168 0 200 P220 P223 Gateway address The 4 bytes of the gateway address are set in decimal format under P220 to P223 Example for 192 168 0 1 perform the following settings e P220 192 e P221 168 e P222 0 e P223 1 Factory setting 192 168 0 1 P230 P233 Subnet mask The 4 bytes of the subnet mask are set in decimal format under P230 to P233 Example for 255 255 255 0 perform the following settings e P230 255 e P231 255 e P232 255 e P233 0 Factory setting 255 255 255 0 P240 P241 Socket port number The socket port number is a 16 bit number with a range of 0 to 65535 The port number is divided into ten thousands and thousands digit as well as hundreds tens and units digit The ten thousands and thousands digit is set under P240 The hundreds tens and units digit is set under P241 Example for 52719 perform the following settings 18 MO 64 e P240 52 e P241 719 When under P240 the number 65 is set then only values from 000 to 535 can be set under P241 When under P241 a number gt 535 is set then only values from 00 to 64 can be set under 240 Alternatively Under P240 you can select any number from 00 to 65 and under P241 any number from 000 to 999 When storing P240 the value in P241 is checked and if necessary automatically corrected and when storing P241 the value in P240is checked and if necessary automatically corrected so that for the port number altoget
44. tric barrier generates a closing command each time an obstacle leaves the photoelectric barrier Under sequence point P543 the photoelectric barrier closing automatic can be activated or deactivated 0 Photoelectric barrier closing automatic is deactivated Photoelectric barrier closing automatic is activated Table 14 26 2 2 9 8 MO 64 P544 Photoelectric barrier testing In order to perform a photoelectric barrier testing it is necessary that the supply of the photoelectric barrier transmitter s can be activated and deactivated by the controller e g Multi1 switches the supply voltage 24Vdc of the photoelectric barrier transmitter Also the multi functional relays 5 or 6 can be used when the photoelectric barrier transmitters are supplied with 230Vac The photoelectric barrier testing consists of two phases During the first phase the photoelectric barrier transmitter is deactivated and it is waited that the photoelectric barrier receiver reports an obstacle within 2 5s During the second phase the photoelectric barrier transmitter is activated again and it is waited that the receiver reports that no obstacle is present Only after that the closing starts When an error occurs during the first phase the photoelectric barrier is faulty error message r I0 When an error occurs during the second phase it is assumed that an obstacle is present The closing is interrupted An error message is not issued With the co
45. two loops Mode 4 Presence safety and closing with two loops MO 64 COCO CON OOH A A WO UOUN NN KR BH HH WWWNNDN gt NO oO nwona nhN 0 WO D 49 Mode 5 Presence opening safety and closing with three loops 50 Mode 6 Opening with directional logic safety and closing with three loops Mode 7 Opening safety and closing with three loops Mode 8 Opening safety and closing with three loops 51 52 54 MO 64 Preface General notes These operating instructions must be available on site at all times It should be read thoroughly by all persons who use or service the appliances Improper usage or servicing or ignoring the operating instructions can be a source of danger for persons or result in material damage If the meaning of any part of these instructions isn t clear then please contact ELKA Torantriebe GmbH u Co Betriebs KG before you use the appliance This applies to all setup procedures fault finding disposal of material care and servicing of the appliance The accident prevention regulations and applicable technical regulations e g safety or electrical and environment protection regulations of the country in which the appliance is used also apply All repairs on the appliances must be carried out by qualified persons ELKA Torantriebe GmbH u Co Betriebs KG accepts no liability for damage which is caused by using the appliance for purposes other than those for which i
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