Laboratory technical sales manual
Contents
1. C a Laboratory technical sales manual i ml f we Contents LKPv and LGPv laboratory appliances with Profi Controller Alarm memory and safety functions Temperature door open and power failure alarms Internal system alarms Internal memory functions special safety functions Temperature and alarm documentation External temperature and alarm monitoring connections External alarm contact connection Product temperature monitoring connection Safety feature table Temperature consistency and distribution according to NF X 15 14 Description of the NF X 15 140 test procedure Results according to NF X 15 140 LK U v LCv LK U exv LG U ex and LGT laboratory appliances with Comfort Controller Alarm memory and safety functions Temperature door open and power failure alarms Internal system alarm Internal memory functions special safety function Temperature and alarm documentation External temperature and alarm monitoring connection External alarm contact connection Product temperature monitoring connection Safety feature table Temperature consistency and distribution according to NF X 15 140 Description of the NF X 15 140 test procedure Results according to NF X 15 140 Loading plan low temperature chest freezers with kryo racks Pharmacy refrigerators compliant to DIN 58345 LKPv and LGPv laboratory appliances with Profi Controller Alarm memory and s2. D sensor Nr 3 E E Er E E m 2 ie Om Um _ x ee o sensor Nr 2 B Minimum value Measurement period tin min The gradient indicates the temperature distribution within the cabinets Especially in the laboratory sector optimum temperature distribution is crucial to guarantee the safe storage of samples or other products at any place within the unit The lower the gradient the better is the temperature distribution within the unit 11 LKPv and LGPv laboratory appliances with Profi Controller 2 Fluctuation The characterisation of the temperature fluctuation within the working space enables to determine the variation in maximum temperature at a measurement point of the working space during the measurement time Maximum fluctuation Value of the probe with the greatest difference between highest and lowest measured temperature The lower the maximum fluctuation the better is the temperature consistency within the units Example Fluctuation oin C E O Do ab E E Maximum s fluctuation D s m o E C O SSO OO Cee D Ee o O UNA Os O ES Fluctuation e of a sensor B Se o A B B B Duration of measurements tin min 12 LKPv and LGPv laboratory appliances with Profi Controller Results according to NF X 15 140 The evaluation of air temperatu
3. PA 28 0 c fe ZOO 24 0 C e Average probe temperature Set temperature Probes H Gradient Gradient HO 3 4 K 1 8K 1 6K from set temperature Max fluctuation 4 0 K Gradient HO 6 0K 2 6K 3 4 K from set temperature Max fluctuation 3 4 K 30 LK U v LCv LK Ujexv LG U ex and LGT laboratory appliances with Comfort Controller LGT 2325 tl t2 t3 t4 t5 t6 t7 Probes e Average probe temperature Set temperature If the cabinet is operated at 20 C it is recommended to reduce the predefined offset of 2 7 K to 1 0 K see user manual LGT 3725 Gradient HO 4 58 K 2 45 K 2 13K from to t9 set temperature Max fluctuation 1 8 K 42 5 C 43 0 C 43 9 C 44 0 C 44 5 C 45 0 C 45 5 C 46 0 C 46 5 C 47 0 C 47 9 C 48 0 C Probes e Average probe temperature Set temperature If the cabinet is operated at 20 C it is recommended to reduce the predefined offset of 2 7 K to 1 0 K see user manual max 0 Um mean value warmest probe expanded measurement uncertainty Gradient HO 3 23 K 0 82 K 2 41 K from set temperature Max fluctuation 0 5 K 31 LK U v LCv LK Ujexv LG Ujex and LGT laboratory appliances with Comfort Controller LGT 4725 42 5 C max 8 iz Um mean value warmest probe expanded measurement uncertainty 43 0 C 43 0 C 440 C H Gradient 44 5 C 45 0 C 45 9 C
4. ee A a a O ES 4 5 C 4 0 oC HO Gradient SoG 6 U mean value coldest probe exp tainty SN eee di 29C 20C Gradient HO 2 0K 0 5K 1 5K from tl t2 t3 t4 o to t t8 t9 set temperature Probes Max fluctuation 1 2 K e Average probe temperature Set temperature 14 LKPv and LGPv laboratory appliances with Profi Controller LKPv 1422 7 0 C max OF Um mean value warmest probe expanded measurement uncertainty 6 5 C _ ne H Gradient 55G 50 C 45 C AL OG min Qoz Un mean value coldest probe expanded measurement uncertainty JaC 30C ZO 2 Gradient HO 2 6K 1 5K 1 1K from tl t2 t3 t4 to to t t8 t9 set temperature Probes Max fluctuation 1 6 K e Average probe temperature Set temperature LGPv 6520 17 5 C max Gait Un mean value warmest probe expanded measurement uncertainty 18 0 C 18 5 C HO Gradient AOC ES O 20 0 C ABUSO 21 0 C AG 220C 23 0 C Gradient HO 3 0K 1 75 K 1 25K from tl t2 13 t4 ke to t t8 t9 Probes set temperature e Average probe temperature Set temperature Max fluctuation 3 6 K 15 LKPv and LGPv laboratory appliances with Profi Controller LGPv 8420 SG Ito 18 0 C 18 5 C SHG AISO 6 200FC SANA 210C Sele 22 0 C E 2229C 20C max Br Um mean value warmest probe expanded measurement uncertainty t1 2 13 t4 5 t6 t7 t8 t9 Gradient HO
5. 46 0 C 46 5 C 47 0 C 47 5 C Gradient HO 3 27 K 0 8 K 2 47 K from set temperature 48 0 C Probes Max fluctuation 1 1 K e Average probe temperature Set temperature If the cabinet is operated at 20 C it is recommended to reduce the predefined offset of 2 7 K to 1 0 K see user manual 32 LK U v LCv LK Ujexv LG U ex and LGT laboratory appliances with Comfort Controller Loading plan low temperature chest freezers with kryo racks height of kyo boxes 50 mm Interior dimensions W D H in mm Number of racks 140 140 604 mm Number of racks 140 140 222 mm Number of boxes 130 130 50 mm Maximum height of racks Maximum height of racks above the compressor Interior dimensions W D H in mm Number of racks 140 140 604 mm Number of racks 140 140 222 mm Number of boxes 130 130 50 mm Maximum height of racks Maximum height of racks above the compressor LGT 2325 889 41 0 630 8 2 96 630 mm 3 5 mm LGT 4725 1445 500 650 24 3 2 6 650 mm 380 mm LGT 3725 1170 500 650 18 3 210 650 mm 380 mm 33 Pharmacy refrigerators compliant to DIN 58345 Pharmacy refrigerators compliant to DIN 58345 In order to comply with the DIN 58345 standard the MKv and MKUv models have the following specifications 2 3 4 5 6 To avoid any unwanted manipulation the set temperature is fixed at 5 C to guarantee maximum safety Likewise the offset values of t
6. Zo Gradient HO 4 0K 2 0K 2 0 K from tl t2 t3 t4 to to t t8 t9 set temperature Probes 20C e Average probe temperature Set temperature Max fluctuation 3 3 K 26 LK U v LCv LK Ujexv LG U ex and LGT laboratory appliances with Comfort Controller LKUexv 1610 Cone max BT Um mean value warmest probe expanded measurement uncertainty 7 0 C 690 6 0 C 0G HOG 45 C 4 0 C Sone SORE HES AG 2 0 C Probes e Average probe temperature Set temperature LGUex 1500 17 0 C 175 C max oot Un mean value warmest probe expanded measurement uncertainty 18 0 C 23 0 C ao 6 24 0 C ti t2 t3 t4 b t6 t7 t8 t9 Probes e Average probe temperature Set temperature Gradient HO 4 1 K 1 6K 2 5K from set temperature Max fluctuation 3 0 K Gradient HO 5 7K 2 1K 3 6 K from set temperature Max fluctuation 0 80 K Zi LK U v LCv LK Ujexv LG Ujex and LGT laboratory appliances with Comfort Controller LKv 3910 e o rrr o EEE 8 0 C pert Bo 6 5 0 AOC AG Gore 30C 20 C 2 0 C ToC TOC W EF Gradient HO 3 0 K 1 25K 1 75K from tl t2 t t4 t5 t6 t7 t8 t9 set temperature Probes Max fluctuation 2 5 K e Average probe temperature Set temperature LKv 3912 O rrr o 8 0 C 75 C max 8 U_ mean value warmest probe expanded measurement uncertainty zoos M H Gradient 69C 6 0 C SoC SC 4
7. a 1 minute delay and can be adjusted between 1 and 5 minutes Power failure alarm All LK U v LCv LK U exv LG U ex and LGT models indicates a visual power failure alarm after the return of the power supply The power failure alarm remains until it is manually reset Internal system alarm The following alarm is related to internal self checks of the electronic controller probes While this might not be immediately relevant to the every day operation of the cabinets it does provide added security by warning probably before the air temperature probe registers an alarm condition Probe failure alarm As a self control system defective probes are registered and the controller causes an audio and visual alarm signal In case of an air probe error the controller has pre defined operating modes to maintain the internal temperature at 5 C 17 LK U v LCv LK Ujexv LG U ex and LGT laboratory appliances with Comfort Controller Internal memory functions Internal alarm memory This function stores to memory details of the last three temperature and power failure alarms Time and date of the start and the duration of the alarm conditions are registered Min max temperature memory After reaching the set temperature for the first time the Comfort controller begins continuously to store to memory the highest and lowest internal temperatures registered These minimum and maximum temperatures can be read out from the memory After reading
8. place a converter kit is available as an optional extra to convert the RS 485 signal to an RS 232 signal and allow connection to a PC or laptop The RS 485 bus connection is made using standard shielded data cables e g type LIYCY 2 x 0 14 mm The maximum possible length of the data lines depends on the quality of the components used The maximum range is 500 m A maximum of 20 appliances can be wired in series BUS line appliance 1 appliance 2 lappliance 20 Dedicated software is provided in the accessory package allowing visualisation analysis and export to other formats for storage The software reads the air probe temperature at 2 minute intervals and records alarm conditions When an alarm condition is registered the software will warn on the PC on which the software is running If this PC is not supervised e g at night or over weekends then the alarm signal might not be recognised In order to avoid unrecognised alarms the software includes an email function which sends an email in case of an alarm condition to predefined email addresses These emails can be easiliy checked with a smartohone Therefore the user will be warned without having direct access to a computer Networking Both laboratory appliances with Profi Controller as well as laboratory appliances with Comfort Controller can be networked using the same Liebherr accessory package RS 485 interface converter in
9. the min max memory the values can either be reset or left in the memory Normally the values would be noted by the user and the memory reset in order to define the next period to be registered The controller also registers the time elapsed since the last reset up to a period of 40 days Special safety function Electro mechanical 2 C safety thermostat for laboratory refrigerators with Comfort Controller In order to ensure maximum reliability the Comfort Controller has a heavy duty compressor relay thus reducing the possibility of burned relay contacts Should however a defect occur an additional safety ther mostat backs up the controller to prevent the product temperature from dropping below 2 C set 18 LK U v LCv LK Ujexv LG U ex and LGT laboratory appliances with Comfort Controller Temperature and alarm documentation Liebherr Mediline refrigerators and freezers with Comfort Controller help to protect your inventory These cabinets offer a variety of features and options designed both for external monitoring of the internal temperatures the product temperatures and alarm conditions to greatly reduce the risk of loss of contents External temperature and alarm monitoring connection RS 485 interface and optional signal converter All LK U v LCv LK U exv and LG U ex models have an integrated RS 485 interface If an RS 485 monitoring system is not already in place a converter kit is available as an optional extra
10. 00 air temperature probes positioned in accordance with NF X 15 140 Unless specifically stipulated the temperature probes are located at equal distances from the walls of 1 10 of each of the dimensions of the internal volume w h d The location of the probes used for characterisation forms a supposedly representative sample of the working space The characterisation is performed using nine probes one located at each corner one in the centre of the working space Location of the probes used for characterisation AO 1 10 B LA l 1 a 5 centred 1 0 H 10 LKPv and LGPv laboratory appliances with Profi Controller Cabinets are tested empty over a period of 24 hrs including defrost cycles Test criteria for characterising the temperature consistency and distribution 1 Gradient or homogeneity The gradient H8 is the maximum difference obtained in an achieved environment between the mean values of measurements hat increased by their expanded uncertainty U within the working space during the measurement time Gradient Distribution of temperatures within the chamber HO max 6 U_ min 8 U max mean value warmest probe expanded measurement uncertainty min mean value coldest probe expanded measurement uncertainty Example Gradient Homogeneity Bia E Maximum value Om Um 1 o V Om at Um 3 L Pu ee m al Bm 3
11. 3 52 K 2 0K 1 52K from Probes set temperature Max fluctuation 4 3 K e Average probe temperature Set temperature LGPv 1420 Gradient HO 3 5K 1 5K 2 0 K from set temperature e Average probe temperature Set temperature Max fluctuation 3 9 K 16 LK U v LCv LK Ujexv LG U ex and LGT laboratory appliances with Comfort Controller Alarm memory and safety functions Liebherr Mediline refrigerators and freezers with Comfort Controller help to protect your inventory These cabinets offer a variety of alarm memory and safety features designed to greatly reduce the risk of loss of contents Temperature door open and power failure alarms High and low temperature alarms All LK U v LCv LK U exv LG U ex and LGT models have integrated high and low internal air temperature alarms with both audio and visual signals The factory settings for the alarm limits are 3 3K in relation to the set temperature If the set temperature is altered to meet a specific storage temperature requirement then the alarm settings move in parallel and do not need to be adjusted separately There is a 15 minutes delay to avoid unwanted alarms due to e g door opening The alarm parameters can however be adjusted by the user to suit individual requirements Door open alarm All LK U v LCv LK U exv LG U ex and LGT models register when doors are left open or ajar and have an integrated audio and visual door open alarm This alarm has
12. 7 t8 t9 Probes e Average probe temperature Set temperature MKUv 1612 BoC soe IL AOA 01C 6 0 C Ho G 50C 4 5 C 4 0 C SL 6 30C 209C 2 0 C max 0 Um mean value warmest probe expanded measurement uncertainty ti t2 t3 t4 t5 t6 t7 t8 t9 Probes e Average probe temperature Set temperature Liebherr laboratory refrigerators or freezers do not comply with the German Institute for Standardisation norm DIN 58371 regarding the requirements for the storage of conserved blood and DIN 58375 regarding the requirements for the storage of blood plasma The MKv and MKUv models comply with the German Institute for Standardisation norm DIN 58345 which refers to the specification of pharmacy refrigerators All other Liebherr refrigerators and freezers in this catalogue do not comply with this standard Gradient HO 3 31 K 2 0K 1 31K from set temperature Max fluctuation 2 70 K Gradient HO 4 27 K 2 27 K 2 00K from set temperature Max fluctuation 4 00 K 36
13. 9 C 4 0 C 30 SO 29C 20C ToC 1 0 C Gradient HO 4 2 K 1 8 K 2 4 K from Probes Max fluctuation 3 7 K e Average probe temperature Set temperature 28 LK U v LCv LK Ujexv LG U ex and LGT laboratory appliances with Comfort Controller LKexv 3910 8 0 C One 7 0 C max BT Um mean value warmest probe expanded measurement uncertainty 63C 60C IoC SOG 49 C 4 0 C 39C 3 0 C ZS 3G Gradient HO 2 8 K 1 2K 1 6K from set temperature 20E Probes Max fluctuation 3 4 K e Average probe temperature Set temperature LGex 3410 SOG aL T0 TIL ISOC too 20 0 C ANG 210C AC 220C Sy 9 3 0 C Gradient HO 2 9K 1 4K 1 5 K from Probes set temperature Max fluctuation 0 40 K e Average probe temperature Set temperature 29 LK U v LCv LK Ujexv LG U ex and LGT laboratory appliances with Comfort Controller LCv 4010 Evaluation of refrigerator compartment max at Um mean value warmest probe expanded measurement uncertainty 9 0 C 8 5 C 8 0 C 9C 7 0 C Ge 6 0 C So 1G 30C 4 5 C 4 0 C 39C 3 0 C 29C 20C 19C 1 0 C e Average probe temperature Set temperature t5 t6 Probes LCv 4010 Evaluation of freezer compartment H Gradient o AE max 8 U_ mean value warmest probe expanded measurement uncertainty E T ae A RA EM RR o 057 E ee ee TR eee oe Er MA ee 51 5 c ne
14. afety functions Liebherr Mediline refrigerators and freezers with Profi Controller help to protect your inventory These cabinets offer a variety of alarm memory and safety features designed to greatly reduce the risk of loss of contents Temperature door open and power failure alarms High and low temperature alarms All LKPv and LGPv modells have integrated high and low internal air temperature alarms with both audio and visual signals The factory settings for the alarm limits are 3 2K in relation to the set temperature lf the set temperature is altered to meet a specific storage temperature requirement then the alarm settings move in parallel and do not need to be adjusted separately There is a 30 minute delay to avoid unwanted alarms due to e g door opening Door open alarm All LKPv and LGPv modells register when doors are left open or ajar and have an integrated audio and visual door open alarm This alarm has a 1 minute delay which can be adjusted Power failure alarm All LKPv and LGPv modells have a battery back up which operates an audio and visual alarm immediately upon power failure Both the integrated temperature data logger and the optional external temperature monitoring via the RS 485 interface continue to function during power failure for up to 72 hrs Internal system alarms The following alarms are related to internal self checks of the refrigeration system and the electronic controller probes While these might n
15. al air temperature as registered by the air probe or the temperature registered by the product probe Depending on this selection the temperature alarm limits are related either to the air probe or to the product probe In addition the product temperature can be monitored on an external documentation system via the RS 485 interface Whereas the air probe is in a fixed position the product probe will be located by the user e g in a phial or in a measurement package in order to simulate a product temperature The product temperature probe is water resistant and resistant to corrosion IP 68 and AISI 316 It complies with NSF standards Due to possible tolerances of the product temperature probe the temperature displayed can differ from the product probe temperature Using the calibration function the temperature displayed can be aligned with the product probe temperature The correction value for the compensation of the differences can be adjusted in 0 1 C steps Cal 5 0 C 0 5 C 2 LK U v LCv LK Ujexv LG U ex and LGT laboratory appliances with Comfort Controller Safety feature table Laboratory appliances LKUv 1610 LKUv 1612 LKUexv1610 LGUex 1500 LKv 3910 LKv 3912 LKexv 3910 LGex 3410 LCv 4010 with Comfort Controller Spark free interior No No Yes Yes No No Yes Yes No High Low temperature alarm au sig andivistial Yes Yes Yes Yes Yes Yes Yes Yes Yes Door open alarm audio and visual Yes Yes Yes Yes Yes Yes Yes Yes Yes
16. al infrared key All LKPv and LGPv models have an integrated temperature data logger which stores up to 2800 air probe temperature values recorded at 4 minute intervals which equals approximately 7 7 days In order to use this data an infrared device key is available as an optional extra The data is transferred from the infra red interface on the cabinet to the infrared key This key is then connected by cable to a PC or laptop and the data is transferred onto the dedicated software on the PC Only one set of data i e from one cab inet can be transferred at one time The optional kit includes all the necessary components key cable and software including manual The soft ware allows visualisation and analysis of the temperature data in various formats including a graph The data can also be exported to Excel Word and other standard formats for storage or further analysis Example visualisation of temperature data Internal temperature 16 07 2009 16 07 2009 17 07 2009 17 07 2009 17 07 2009 17 07 2009 18 07 2009 18 07 2009 18 07 2009 18 07 2009 19 07 2009 19 07 2009 19 07 2009 19 07 2009 12 00 18 00 00 00 06 00 12 00 18 00 00 00 06 00 12 00 18 00 00 00 06 00 12 00 18 00 LKPv and LGPv laboratory appliances with Profi Controller RS 485 interface and optional signal converter All LKPv and LGPv models have an RS 485 interface If an RS 485 monitoring system is not already in
17. cluding temperature monitoring software Example RS 485 network Ro 489 Optimum Pma OO shielded Twisted Pair 9 Ohm j Terminator 209 120 Ohm 8 Address 1 Address 2 Adaress 3 LKPv and LGPv laboratory appliances with Profi Controller External alarm contact connection Volt free contact All LKPv and LGPv models have an integrated volt free contact The relay contact can be wired into a warning system in the building which would advise e g Security personnel or a janitor outside of working hours Warning systems with audio or visual alarms are possible The following example shows a circuit with a visual alarm Either normal operation or alarm condition or both can be indicated Either AC or DC circuits are possible max AC 230 V 5 Amp Example visual alarm system using volt free alarm contact Normal operation Alarm condition e g green lamp e g red lamp indicating normal A indicating alarm opretaion X condition external power supply external power supply Alternatively if no internal warning system is in place and additional wiring inside the building is problematical the volt free contact can be used in conjunction with e g a GSM alarm dialler There are many different versions of GSM alarm dialers available on the market which either call a telephone number and or send a text message in case of an alarm Depending on the specification of the alarm dialler potentially many appliances can be co
18. ction stores to the memory the internal temperature profile at 4 minute intervals 2800 temperature logs are stored to memory which corresponds to approximately a 7 day logging period 30 C 16 07 2009 07 18 07 2009 12 00 18 00 00 00 06 00 12 00 18 00 00 00 06 00 12 00 18 00 00 00 12 00 Special safety functions Solid state relay for maximum reliability The LKPv and LGPv models all have a solid state relay guaranteed to gt 1 billion compressor start cycles As well as allowing very accurate temperature control this feature practically excludes the possibility of burnt relay contacts as a cause for extreme internal temperatures Double fan cooling All LKPv and LGPv modells have a double internal fan arrangement so that in case of one defective fan the cooling system continues to function at reduced capacity The highly reliable fans Liebherr uses are guaranteed to 80 000 hrs operating time LKPv and LGPv laboratory appliances with Profi Controller Temperature and alarm documentation Liebherr Mediline refrigerators and freezers with Profi Controller help to protect your inventory These cabinets offer a variety of features and options designed both for external monitoring of the internal temperatures the product temperatures and alarm conditions to greatly reduce the risk of loss of contents External temperature and alarm monitoring connections Infrared interface and option
19. e as registered by the air probe or the temperature registered by the product probe or both Also the temperature alarm limits as well as the temperature alarm delay for the product temperature probe can be adjusted by the user to suit individual requirements In addition the product temperature can be monitored on an external documentation system via the RS 485 interface Whereas the air probe is in a fixed position the product probe will be located by the user e g in a phial or in a measurement package in order to simulate a product temperature The product temperature probe is water resistant and resistant to corrosion IP 68 and AISI 316 It complies with all relevant NSF standards Due to possible tolerances of the product temperature probe the temperature displayed can differ from the product probe temperature Using the calibration function the temperature displayed can be aligned with the product probe temperature at as many as three temperature points The correction value for the compensation of the differences can be adjusted in 0 1 C steps 3 150 C 0 8 C LKPv and LGPv laboratory appliances with Profi Controller Safety feature table eee Gp US LKPv 6520 LKPv 6522 LKPv 8420 LKPv 1420 LKPv 1422 LGPv 6520 LGPv 8420 LGPv 1420 Profi Controller Spark free interior No No No No No No No No High Low temperature alarm audio and visual Yes Yes Yes Yes Yes Yes Yes Yes Door open alarm audio and visual Yes Yes Yes Yes Yes Yes Y
20. e Yes Yes Yes Probe failure alarm Yes Yes Yes 22 LK U v LCv LK Ujexv LG U ex and LGT laboratory appliances with Comfort Controller Temperature consistency and distribution according to NF X 15 140 The Liebherr laboratory cabinets are all tested in house to the NF X 15 140 test procedure Liebherr s modern R amp D facility has climate controlled test rooms which conform to EN 23953 Description of the NF X 15 140 test procedure The general test conditions are as follows Ambient temperature 25 C 60 relative humidity Refrigerator set temperature 5 C Freezer set temperature 20 C Low temperature freezer set temperature 45 C Measurements are made using 9 x PT 100 air temperature probes positioned in accordance with NF X 15 140 Unless specifically stipulated the temperature probes are located at equal distances from the walls of 1 10 of each of the dimensions of the internal volume w h d The location of the probes used for characterisation forms a supposedly representative sample of the working space The characterisation is performed using nine probes one located at each corner one in the centre of the working space Location of the probes used for characterisation 1 10 B 10T 1 0 H aE 1 5 centred 23 LK U v LCv LK Ujexv LG U ex and LGT laboratory appliances with Comfort Controller Cabinets are tested empty over a period of 24 hrs incl
21. es Yes A e HM alla Cece Yes Yes Yes Yes Yes Yes Yes Yes Volt free contact for external alarm signal Yes Yes Yes Yes Yes Yes Yes Yes RS 485 data transfer interface Yes Yes Yes Yes Yes Yes Yes Yes Infrared data transfer interface Yes Yes Yes Yes Yes Yes Yes Yes asa transfer key with data monitoring Accessory Accessory Accessory Accessory Accessory Accessory Accessory Accessory Ee on with data Accessory Accessory Accessory Accessory Accessory Accessory Accessory Accessory NTC product temperature probe Accessory Accessory Accessory Accessory Accessory Accessory Accessory Accessory Internal alarm memory Yes Yes Yes Yes Yes Yes Yes Yes Min Max temperature memory Yes Yes Yes Yes Yes Yes Yes Yes Access port for e g PT 100 probe Yes Yes Yes Yes Yes Yes Yes Yes Probe failure alarm Yes Yes Yes Yes Yes Yes Yes Yes Condenser and evaporator temperature alarms Yes Yes Yes Yes Yes Yes Yes Yes LKPv and LGPv laboratory appliances with Profi Controller Temperature consistency and distribution according to NF X 15 140 The Liebherr laboratory cabinets are all tested in house to the NF X 15 140 test procedure Liebherr s modern R amp D facility has climate controlled test rooms which conform to EN 23953 Description of the NF X 15 140 test procedure The general test conditions are as follows Ambient temperature 25 C 60 relative humidity Refrigerator set temperature 5 C Freezer set temperature 20 C Measurements are made using 9 x PT 1
22. he probes cannot be changed Also alarm limits cannot be changed from the default values 2 8 C An additional probe is positioned at the warmest point within the unit and this temperature is displayed on the controller The MKv 3912 has a load line to prevent pharmaceuticals being placed at the very top of the compartment In order to prevent product loss or detriment due to incorrect storage an integrated evaporator cover keeps products away from the cold surface of the evaporator 7 The integrated power failure alarm gives an acoustic warning immediately upon power failure em NA NA NA NA Otherwise the MKv and MKUv models have the same features as the LKv and LKUv equivalents Safety feature table Pharmacy refrigerators compliant to DIN 58345 MKv 3910 MKv 3912 MKUv 1610 MKUv 1612 Spark free interior No No No No High Low t t ig Low Eni ure alarm ves Ves De vee audio and visual Door open alarm audio and visual Yes Yes Yes Yes P fail ing iatel ower failure warming immediately T vee vs Yes upon power failure Volt f tact TEO Yes Yes Yes Yes for external alarm signal R S 485 data transfer Yes 7 ves 7 interface RS 485 RS 232 converter with A Accessory Accessory Accessory Accessory data monitoring software NTC product temperature probe Accessory Accessory Accessory Accessory Internal alarm memory Yes Yes Yes Yes Min Max ue Yes Yes Yes Yes temperature memory 2 C safety thermostat Yes Yes Yes Yes Access
23. iance 20 Terminator 120 Ohm Hp Terminator ooo 120 Ohm 8 Address 1 Address 2 i146 Address 3 19 LK U v LCv LK Ujexv LG U ex and LGT laboratory appliances with Comfort Controller External alarm contact connection Volt free contact All LK U v LCv LK U exv LG U ex and LGT models have an integrated volt free contact The relay contact can be wired into a warning system in the building which would advise e g security personnel or a janitor outside of working hours Warning systems with audio or visual alarms are possible The following example shows a circuit with a visual alarm Either normal operation or alarm condition or both can be indicated Either AC or DC circuits are possible max AC 230 V 5 Amp Example visual alarm system using volt free alarm contact Normal operation Alarm condition e g green lamp e g red lamp indicating normal indicating alarm opretaion condition external power supply external power supply Alternatively if no internal warning system is in place and additional wiring inside the building is problematical the volt free contact can be used in conjunction with e g a GSM alarm dialler There are many different versions of GSM alarm dialers available on the market which either call a telephone number and or send a text message in case of an alarm Depending on the specification of GSM alarm dialers potentially many appliances can be connected to one dialler Being GSM appliance
24. nnected to one dialler Being GSM appliances only a SIM card and a power supply are required The following example shows a circuit with a GSM dialler A change in relay setting activates the alarm function of the dialler and thus initiates either a telephone call or an SMS to pre defined numbers with a pre recorded message The dialler in the example has 6 addressed alarm inputs This could be 6 individual appliances or 6 rooms each with several appliances wired in series Example GSM dialler alarm system using volt free alarm contact Alarm inputs A1 6 Open or close A1 6 to GND Normal operation y na i y Y D 2 o aa 15 a7 im Any contractors normally open or closed In spite of all efforts to produce appliances of unequalled reliability Liebherr strongly recommends that the volt free contact is wired into some kind of independent and external warning system Please take a few moments to consider the value of the contents of the refrigerators and freezers under your supervision The cost of such a warning system is often negligible in comparison to the value of the contents T LKPv and LGPv laboratory appliances with Profi Controller Interface for optional NTC product temperature probe All LKPv and LGPv models have an integrated interface for connecting an optional available NTC product temperature probe to the Profi controller The controller can be set to display either the internal air temper atur
25. ot be immediately relevant to the everyday operation of the cabinets they do provide added security by warning probably before the air temperature probe registers an alarm condition They also provide a service engineer with valuable information thus allowing quicker intervention High condenser temperature alarm This integrated audio and visual alarm warns of excessive condenser temperatures possibly caused by e g high ambient temperatures or blocked air flow to or from the refrigeration system Low evaporator temperature alarm This integrated audio and visual alarm warns of low evaporator temperatures possibly caused by e g defective air circulation fan or blocked internal air flow This alarm will possibly warn much sooner than the high or low temperature alarm Probe failure alarm As a self control system defective probes are registered and the controller cause an audio and visual alarm Signal In case of an air probe error the controller has pre defined operating modes to maintain the internal temperature at 5 C LKPv and LGPv laboratory appliances with Profi Controller Internal memory functions Internal alarm memory This function stores to memory details of the last 30 alarms time and date of the start and the end of the alarm condition the type of the alarm condition and the maximum and minimum internal air temperatures measured during this alarm condition period are registered Internal temperature memory This fun
26. port for e g PT 100 probe Yes Yes Yes Yes Probe failure alarm Yes Yes Yes Yes 34 Pharmacy refrigerators compliant to DIN 58345 Results according to NF X 15 140 The evaluation of air temperatures of the MK U v models according to NF X 15 140 using a PT 100 temperature probe shows the following results MKv 3910 8 5 C 8 0 C ToC OAS 03C 6 0 C So O DoC 4 5 C 4 0 C JaC 30C 2o 20C min 6 U mean value cc 3 t4 t5 t6 t7 Probes tl t2 e Average probe temperature Set temperature MKv 3912 max 0 Um mean value warmest probe expanded measurement uncertainty robe expanded measurement uncerta ty t8 8 5 C max at Un mean value warmest probe expanded measurement uncertainty 8 0 C Loe 7 0 C Go 6 0 C SoC SOC 45 C 4 0 C So 0 30C 25 6 ZA t4 ifs t6 t Probes tl t2 t3 e Average probe temperature Set temperature t8 t9 t9 Gradient HO 4 20 K 2 4K 1 8K from set temperature Max fluctuation 3 10 K a Ep Tpm eo ee di EE cece oom k TEE CEET A a in Rii FR I TEU I i Af Gradient HO 4 46 K 3 1K 1 36K from set temperature Max fluctuation 3 60 K 35 Pharmacy refrigerators compliant to DIN 58345 MKUv 1610 8 5 C 8 0 C oC TOE 6C 6 0 C 50C S0C 4 5 C 4 0 C 3C 30C 209 20C max BaT Um mean value warmest probe expanded measurement uncertainty tl t2 t3 t4 t5 t6 t
27. pown falure vanny alter power Yes Yes Yes Yes Yes Yes Yes Yes Yes supply is returned visual i e Contact to extemmalalaim Yes Yes Yes Yes Yes Yes Yes Yes Yes RS 485 data transfer interface Yes Yes Yes Yes Yes Yes Yes Yes Yes RS 485 RS 232 converter with data monitoring software Accessory Accessory Accessory Accessory Accessory Accessory Accessory Accessory Accessory NTC product temperature probe Accessory Accessory Accessory Accessory Accessory Accessory Accessory Accessory Accessory Internal alarm memory Yes Yes Yes Yes Yes Yes Yes Yes Yes Min Max temperature memory Yes Yes Yes Yes Yes Yes Yes Yes Yes o For refrigerator 2 C safety thermostat Yes Yes Yes No Yes Yes Yes No compartment Access port for e g PT 100 probe Yes Yes Yes Yes Yes Yes Yes Yes Yes Probe failure alarm Yes Yes Yes Yes Yes Yes Yes Yes Yes Low temperature freezers LGT 2325 LGT 3725 LGT 4725 to 45 C Spark free interior No No No High Low temperature alarm J 7 ia Yes Yes Yes audio and visual Lid open alarm p i Yes Yes Yes audio and visual Power failure warning after power i mee Yes Yes Yes supply is returned visual Volt free contact Yes Yes Yes for external alarm signal RS 485 data transfer Yes Yes Yes interface Reece Com end Accessor Accessor Accessor data monitoring software y 1 NTC product temperature probe Accessory Accessory Accessory Internal alarm memory Yes Yes Yes Min Max Yes Yes Yes temperature memory Access port for e g PT 100 prob
28. res of the LKPv and LGPv models according to NF X 15 140 using a PT 100 temperature probe with 25 g copper thermal mass shows the following results LKPv 6520 8 0 C oe OG 65 6 0 C max 8 U mean value warmest probe expanded measurement uncertainty Sy oad o 0C oe H Gradient 4 0 C min CAU mean value coldest probe expanded measurement uncertainty one 3 0PC 29L 2026 Gradient HO 1 8 K 0 9 K 0 9 K from tl 2 t3 t4 t5 t6 t7 t t9 set temperature Probes Max fluctuation 1 0 K e Average probe temperature Set temperature LKPv 6522 8 0 C ome 7 0 C GaC 6 0 C 55C 50 C 4 5 C 4 0 C 35 min OU mean value coldest probe expanded measurement uncertainty 30C Zo Gradient HO 2 3 K 1 4 K 0 9 K from tl 12 D t4 t5 t6 t t8 t9 set temperature Probes E RO Max fluctuation 1 6 K e Average probe temperature Set temperature 13 LKPv and LGPv laboratory appliances with Profi Controller LKPv 8420 LoC max Bt Um mean value warmest probe expanded measurement uncertainty TOC 6C 6 0 C IoC SUG 49 C 4 0 C 3 SORO 20 Gradient HO 1 74 K 0 9K 0 84K from tl t2 t3 t4 t to t t8 t9 set temperature Probes 2 0 C Max fluctuation 1 5 K e Average probe temperature Set temperature LKPv 1420 8 0 C oC 7 0 C 01C 6 0 C max 9a Wa mean value warmest probe expanded measurement uncertainty
29. s only a SIM card and a power supply are required The following example shows a circuit with a GSM dialler A change in relay setting activates the alarm function of the dialler and thus initiates either a telephone call or an SMS to pre defined numbers with a pre recorded message The dialler in the example has 6 addressed alarm inputs This could be 6 individual appli ances or 6 rooms each with several appliances wired in series Example GSM dialer alarm system using volt free alarm contact Alarm inputs A1 6 Open or close A1 6 to GND Normal operation a E AS as f f a ae ete coated Any contractors normally open or closed In spite of all efforts to produce appliances of unequalled reliability Liebherr strongly recommends that the volt free contact is wired into some kind of independent and external warning system Please take a few moments to consider the value of the contents of the refrigerators and freezers under your supervision The cost of such a warning system is often negligible in comparison to the value of the contents 20 LK U v LCv LK Ujexv LG U ex and LGT laboratory appliances with Comfort Controller Interface for optional NTC product temperature probe All LK U v LCv LK U exv LG U ex and LGT models have an integrated interface for connecting an optional available NTC product temperature probe to the comfort controller The controller can be set to display either the intern
30. to convert the RS 485 signal to an RS 232 signal and allow connection to a PC or laptop The RS 485 bus connection is made using standard shielded data cables e g type LIYCY 2 x 0 14 mm The maximum possible length of the data lines depends on the quality of the components used The maximum range is 500m A maximum of 20 appliances can be wired in series Dedicated software is provided in the accessory package allowing visualisation analysis and export to other formats for storage The software reads the air probe temperature at 2 minute intervals and records alarm conditions When an alarm condition is registered the software will warn on the PC on which the software is running if this PC is not supervised e g at night or over weekends then the alarm signal might not be recognised In order to avoid unrecognised alarms the software includes an email function which sends an email in case of an alarm condition to predefined email addresses These emails can be easily checked with a smartohone Therefore the user will be warned without having direct access to a computer Networking Both laboratory appliances with Profi Controller as well as laboratory appliances with Comfort Controller can be networked using the same Liebherr accessory package RS 485 interface converter including temperature monitoring software Example RS 485 network Optimum shielded Twisted Pair BUS line appl
31. uding defrost cycles Test criteria for characterising the temperature consistency and distribution 1 Gradient or homogeneity The gradient H8 is the maximum difference obtained in an achieved environment between the mean values of measurements hat increased by their expanded uncertainty OF within the working space during the measurement time Gradient Distribution of temperatures within the chamber HO max 6 U_ min 8 U max mean value warmest probe expanded measurement uncertainty min mean value coldest probe expanded measurement uncertainty Example Gradient Homogeneity Bia E Maximum value Om Um 1 o V Om at Um 3 L Pu ee m al Bm 3 D sensor Nr 3 E E Er E E m 2 ie Om Um _ x ee o sensor Nr 2 B Minimum value Measurement period tin min The gradient indicates the temperature distribution within the cabinets Especially in the laboratory sector optimum temperature distribution is crucial to guarantee the safe storage of samples or other products at any place within the unit The lower the gradient the better is the temperature distribution within the unit 24 LK U v LCv LK Ujexv LG U ex and LGT laboratory appliances with Comfort Controller 2 Fluctuation The characterisation of the temperature fluctuation
32. within the working space enables to determine the variation in maximum temperature at a measurement point of the working space during the measurement time Maximum fluctuation Value of the probe with the greatest difference between highest and lowest measured temperature The lower the maximum fluctuation the better is the temperature consistency within the units Example Fluctuation oin C E O Do ab E E Maximum s fluctuation D s m o E C O SSO OO Cee D Ee o O UNA A Ss O ES Fluctuation e of a sensor B Se o A B B B Duration of measurements tin min 25 LK U v LCv LK Ujexv LG Ujex and LGT laboratory appliances with Comfort Controller Results according to NF X 15 140 The evaluation of air temperatures of the LK U v LCv LK U exv LG U ex and LGPv models according to NF X 15 140 using a PT 100 temperature probe with 25 g copper thermal mass shows the following results LKUv 1610 8 0 C Gone FOG max ae Um mean value warmest probe expanded measurement uncertainty 61C 6 0 C Sol 50 0 4 5 C 4 0 C 39C IoC 200 Gradient HO 2 9 K 1 3K 1 6K from ti 2 t3 t4 to to t t8 t9 set temperature Probes Ze e Average probe temperature Set temperature Max fluctuation 2 5 K LKUv 1612 Lore max Ot Um mean value warmest probe expanded measurement uncertainty UNE GSM 6 0 C 59 C 5 0 C 4 5 C 4 0 C so Ab 30C
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