* Your assessment is very important for improving the workof artificial intelligence, which forms the content of this project
Download Product manual for the 4-Quadrant-/ Combi meter
Survey
Document related concepts
Valve RF amplifier wikipedia , lookup
Schmitt trigger wikipedia , lookup
Serial digital interface wikipedia , lookup
Resistive opto-isolator wikipedia , lookup
UniPro protocol stack wikipedia , lookup
Standing wave ratio wikipedia , lookup
Power MOSFET wikipedia , lookup
Voltage regulator wikipedia , lookup
Surge protector wikipedia , lookup
Peak programme meter wikipedia , lookup
Power electronics wikipedia , lookup
Opto-isolator wikipedia , lookup
Switched-mode power supply wikipedia , lookup
Transcript
Product manual for the 4-Quadrant-/ Combi meter LZQJ-XC in accordance with VDEW-Specifications 2.1 Installation I Description I Operation instructions Edition: 24.07.2012 LZQJXC-PHB-E-3.40 The contents of this manual are protected by copyright. It is forbidden to translate, reprint, copy or store the contents in electronic data processing systems without the express permission of the EMH. All trade marks and product names mentioned in this manual are the property of the EMH metering GmbH & Co. KG or the respective title holder. EMH is certified in accordance with DIN EN ISO 9001:2008 and endeavour to improve their products continually. The contents of this manual and the technical specifications may be supplemented, amended or deleted without prior notice. The description for the product specification in this manual does not constitute an integral part of the contract. © 2012 EMH metering GmbH & Co. KG. All rights reserved. If you have any questions or suggestions, you can contact us at: EMH metering GmbH & Co. KG Neu-Galliner Weg 1 19258 Gallin GERMANY Tel.: +49 38851 326-0 Fax: +49 38851 326-1129 E-mail: [email protected] Web: www.emh-metering.com Technical Support: 2 Tel.: +49 38851 326-1930 E-mail: [email protected] Table of contents 1 1.1 1.2 Prologue ...................................................................................................... 9 General ......................................................................................................... 9 Quoted standards and other documents ..................................................... 10 2 2.1 2.2 2.3 2.4 2.4.1 2.4.2 2.5 2.5.1 2.5.2 2.5.3 2.5.4 2.6 Tips on mounting and installation........................................................... 12 General safety tips ...................................................................................... 12 Maintenance- and guarantee tips................................................................ 12 Mounting ..................................................................................................... 13 Installation................................................................................................... 14 Transformer operated meter ....................................................................... 14 Direct connected meter ............................................................................... 14 Terminal blocks ........................................................................................... 16 Transformer operated meter ....................................................................... 16 Direct connected meter 60 A ...................................................................... 17 Direct connected meter 100 A .................................................................... 18 Pin assignment of the RJ12 socket ............................................................. 19 Circuit diagrams .......................................................................................... 20 3 3.1 3.2 3.2.1 3.2.2 3.2.2 3.3 3.3.1 3.3.2 3.3.3 3.3.4 3.3.5 3.3.6 3.3. 3.3.8 3.3.9 3.3.10 3.3.11 3.3.12 3.4 3.4.1 3.4.1.1 3.4.1.2 3.4.2 3.4.2.1 3.4.2.1.1 3.4.2.1.2 3.4.2.1.3 3.4.3 3.4.4 3.4.5 3.4.5.1 3.4.5.2 3.4.5.2.1 3.4.5.2.2 3.4.5.2.3 3.4.5.3 3.4.5.4 General device description ...................................................................... 23 Meter layout ................................................................................................ 23 Technical data ............................................................................................ 24 Transformer connected meter ..................................................................... 24 Direct connected meter ............................................................................... 26 Direct connected meter with load switching ................................................ 28 Housing-, operation- and display elements ................................................. 30 Display ........................................................................................................ 31 Test - LEDs ................................................................................................. 33 Call-up and reset button.............................................................................. 33 Optical call-up sensor ................................................................................. 33 Parameterisation button .............................................................................. 33 Optical data interface D0 ............................................................................ 33 Meter cover ................................................................................................. 33 Sealable terminal cover .............................................................................. 34 Battery compartment................................................................................... 34 Communication module compartment ........................................................ 34 Nameplate .................................................................................................. 34 Transformer nameplate............................................................................... 34 Modules ...................................................................................................... 35 Voltage supply ............................................................................................ 35 Direct supply ............................................................................................... 35 Auxiliary voltage .......................................................................................... 35 Measuring device ........................................................................................ 36 Measuring principle ..................................................................................... 36 Voltage measurement ................................................................................. 36 Current measurement ................................................................................. 36 Data protection ........................................................................................... 37 Tariff switching clock ................................................................................... 37 Ripple control receiver (RCR) ..................................................................... 40 Data interfaces ............................................................................................ 41 Optical data interface D0 ............................................................................ 41 Electrical interface....................................................................................... 42 Electrical interface RS485........................................................................... 43 Electrical interface RS232........................................................................... 44 Electrical interface CL0 (CS) ....................................................................... 45 Optical fibre interface LLS........................................................................... 46 raconet radio interface ................................................................................ 46 3 4 3.4.6 3.4.6.1 3.4.6.2 3.4.6.3 3.4.6.4 3.4.6.5 3.4.6.6 3.4.6.6.1 3.4.6.6.2 3.4.6.6.2 3.4.6.6.3 3.4.6.6.3.5 3.4.6.6.3.6 3.4.7 3.4.7.1 3.4.7.2 Communication modules ............................................................................ 47 Modem module VARIOMOD XC ................................................................. 47 Interface Module XC ................................................................................... 47 Technical data ............................................................................................ 48 Housing- and display elements ................................................................... 48 Important tips for mounting and installation ................................................ 49 Mounting and installation ............................................................................ 50 Mounting and removal of the communication module ................................. 50 Connection .................................................................................................. 51 Connection of external devices to the communication module ................... 52 Start up of the communication module........................................................ 52 Switching on the VARIOMOD XC ............................................................... 54 LED displays ............................................................................................... 54 In- and outputs ............................................................................................ 55 Inputs .......................................................................................................... 55 Outputs ....................................................................................................... 55 4 4.1 4.1.1 4.1.1.1 4.1.1.1.1 4.1.1.1.2 4.1.1.2 4.1.1.3 4.1.1.4 4.1.1.4.1 4.1.1.4.2 Firmware .................................................................................................... 56 Tariff device ................................................................................................ 57 Energy- and maximum demand tariffs ........................................................ 57 Maximum demand metering ....................................................................... 57 Block measuring period .............................................................................. 57 Sliding measuring period ............................................................................ 58 De-coupling time te...................................................................................... 60 Reset (cumulation) ...................................................................................... 60 Load profile ................................................................................................. 62 General ....................................................................................................... 62 Standard load profile P.01 .......................................................................... 62 5 5.1 5.2 5.2.1 5.2.2 5.2.3 5.2.4 5.2.5 5.2.6 5.2.7 5.2.8 5.2.9 5.2.10 5.2.11 5.3 Display- and readout lists ........................................................................ 64 Display lists ................................................................................................. 64 Call-up of the display lists / control of the display ....................................... 65 Brief instructions on the operation of display .............................................. 65 Operation display (scrolling list) .................................................................. 66 Display test ................................................................................................. 66 Menu “Call-up button“ ................................................................................. 67 Call-up list (menu option “Std-dAtA”) .......................................................... 68 Load profile list, standard LP (menu option “P.01”) ..................................... 69 Certification relevant log book (menu option “P.99”) ................................... 70 Menu “Reset button” ................................................................................... 72 Set list (Menu option “Set”) ......................................................................... 73 Info list (Menu option “InFO-dAtA”) ............................................................. 74 Test list (Menu option “tESt”) ...................................................................... 75 Readout lists ............................................................................................... 76 6 6.1 6.1.1 6.1.2 6.1.2.1 6.1.2.2 6.1.2.3 6.1.2.4 6.1.2.4.1 6.1.2.4.2 6.2 6.3 Special features ........................................................................................ 77 Manipulation recognition ............................................................................. 77 Principle functions ....................................................................................... 77 Output possibilities ...................................................................................... 77 Cursor in the display ................................................................................... 77 Register entry ............................................................................................. 78 Activation of an alarm contact ..................................................................... 78 Log book entry ............................................................................................ 78 User log book P.200 ................................................................................... 78 Event log book P.210 .................................................................................. 79 Overload monitoring.................................................................................... 80 Installation check register C.86.0 ................................................................ 81 6.4 6.4.1 6.4.2 6.5 6.6 6.6.1 6.6.2 6.6.3 6.7 6.7.1 6.7.1.1 6.7.1.2 6.7.1.3 6.7.1.4 6.7.2 6.7.2.1 6.7.2.2 6.7.2.3 6.7.2.4 6.7.2.4.1 6.7.2.4.2 6.7.3 6.8 Network analysis ......................................................................................... 82 User load profile P.02 ................................................................................. 82 Voltage quality register C.86.1 .................................................................... 84 Consumption check register C.86.2 ............................................................ 85 Log boks ..................................................................................................... 85 User log book P.200 ................................................................................... 85 Event log book P.210 .................................................................................. 85 Event log book P.211 .................................................................................. 86 Load switching ............................................................................................ 86 Example cases ........................................................................................... 86 Example case 1 .......................................................................................... 86 Example case 2 .......................................................................................... 86 Example case 3 .......................................................................................... 86 Example case 4 .......................................................................................... 86 Load switching ............................................................................................ 87 Load switching via the call-up button .......................................................... 87 Load switching via commands .................................................................... 88 Manual load switching................................................................................. 88 Load switching by means of excess load .................................................... 88 Switching off by means of excess load ....................................................... 88 Automatic switching on ............................................................................... 88 Monitoring the switch off condition .............................................................. 88 Recording external measuring variables ..................................................... 89 7 7.1 7.2 Certification relevant tests ....................................................................... 91 Certification- and test mode ........................................................................ 91 Test load ..................................................................................................... 91 8 8.1 8.2 8.3 8.3.1 8.3.2 8.4 8.4.1 8.4.2 8.4.3 8.5 8.5.1 8.5.2 8.5.2.1 8.5.2.2 8.5.3 8.5.3.1 8.5.3.2 8.5.3.3 8.5.3.4 8.5.4 8.5.4.1 8.5.4.2 8.5.4.3 8.5.4.4 8.5.4.5 8.5.4.6 8.5.4.7 8.5.4.8 Appendix ................................................................................................... 92 OBIS (Object-Identification-System) ........................................................... 92 Standard impulse constants ........................................................................ 96 Error register ............................................................................................... 97 Explanation of the individual error flags ...................................................... 97 Clearing the error register ........................................................................... 97 Software ...................................................................................................... 98 EMH-COM .................................................................................................. 98 EMH-COMBI-MASTER 2000 ...................................................................... 98 EMH-Mobile ................................................................................................ 99 Basic operation of the LZQJ-XC ............................................................... 100 Overview ................................................................................................... 100 Possibilities of meter communication ........................................................ 101 Communication via optical interface ......................................................... 101 Communication via electrical interface...................................................... 101 Basic settings before communication........................................................ 102 General settings ........................................................................................ 102 Modem settings......................................................................................... 103 Setting date and time ................................................................................ 104 Setting baud rate....................................................................................... 104 Reading out the meter .............................................................................. 105 Reading out the tables .............................................................................. 105 Reading out load profile data .................................................................... 106 Reading out operation log book P.98 ........................................................ 107 Reading out certification relevant log book P.99 ....................................... 107 Reading out the user log book P.200 ........................................................ 108 Reading out event log book P.210 ............................................................ 108 Reading out event log book P.211 ............................................................ 108 Commenting readout tables ...................................................................... 108 5 8.5.4.9 8.5.5 8.5.5.1 8.5.5.2 8.5.5.3 8.5.5.4 8.5.5.5 8.5.5.6 Converting load profiles ............................................................................ 109 Processing the readout data ..................................................................... 111 Opening files ............................................................................................. 111 Saving files ............................................................................................... 111 Transferring files ....................................................................................... 111 Executing read- and write commands ....................................................... 112 Graphic display of load profiles ................................................................. 112 Export of load profile data ......................................................................... 115 9 EU Declaration of Conformity ................................................................ 119 Table index Table 1: Table 2: Table 3: Table 4: Table 5: Table 6: Table 7: Table 8: Table 9: Table 10: Table 11: Table 12: Table 13: Table 14: Table 15: Table 16: Table 17: Table 18: Table 19: Table 20: Table 21: Table 22: Table 23: Table 24: Table 25: Table 26: Table 27: Table 28: Table 29: Table 30: Table 31: Table 32: 6 Standard functions and options .................................................................... 9 Terminal block for transformer operated meters ......................................... 16 Terminal block for direct conneted meters 60 A .......................................... 17 Terminal block for direct conneted meters100 A ......................................... 18 Pin assignment of the RJ12 socket with a RS232 interface ........................ 19 Pin assignment of the RJ12 socket with a RS485 interface ........................ 19 Pin assignment of the RJ12 socket with a CL0 interface ............................ 19 Technical data for transformer connected meters ....................................... 25 Technical data for direct connected meters ................................................ 27 Technical data for direct connected meters with load switching ................. 29 Apparent power consumption ..................................................................... 36 Specification of RS485 interface ................................................................. 43 Specification of RS232 interface ................................................................. 44 Specification of CL0 interface ..................................................................... 45 Specification of optical fibre interface.......................................................... 46 Specification of inputs ................................................................................. 55 Specification of outputs ............................................................................... 55 Inhibition times for a renewed reset (Examples) ......................................... 61 Memory depths ........................................................................................... 62 Operation display ........................................................................................ 66 Test mode display ....................................................................................... 66 Menu “Call-up button” ................................................................................. 67 Call-up list ................................................................................................... 68 Load profile list ............................................................................................ 69 Certification relevant log book ..................................................................... 71 Menu “Reset button” ................................................................................... 72 Set list ......................................................................................................... 73 Info list ........................................................................................................ 74 Test list ....................................................................................................... 75 Memory depths ........................................................................................... 82 Standard impulse constants with secondary meters ................................... 96 Error examples ........................................................................................... 97 Figure index Figure 1: Figure 2: Figure 3: Figure 4: Figure 5: Figure 6: Figure 7: Figure 8: Figure 9: Figure 10: Figure 11: Figure 12: Figure 13: Figure 14: Figure 15: Figure 16: Figure 17: Figure 18: Figure 19: Figure 20: Figure 21: Figure 22: Figure 23: Figure 24: Figure 25: Figure 26: Figure 27: Figure 28: Figure 29: Figure 30: Figure 31: Figure 32: Figure 33: Figure 34: Figure 35: Figure 36: Figure 37: Figure 38: Figure 39: Figure 40: Figure 41: Figure 42: Figure 43: Figure 44: Figure 45: Dimensions ................................................................................................. 13 Back-up fuse with transformer operated meters ......................................... 14 Back-up fuse with direct connected meters ................................................ 14 RJ12 socket ................................................................................................ 19 Circuit diagram - Polyphase meter .............................................................. 20 Transformer operated meter; 3020 measuring record types M7 and M8 .... 20 Transformer operated meter; 4020 ............................................................. 20 Transformer operated meter; 4020 measuring record type M1 ................... 21 Transformer operated meter; 4020 measuring record type M3 ................... 21 Transformer operated meter; 4020 measuring record type M4 ................... 22 Transformer operated meter; 4020 measuring record type M6 ................... 22 Meter layout ................................................................................................ 23 Meter elements ........................................................................................... 30 Display ........................................................................................................ 31 Transformer nameplate............................................................................... 34 Definition of quadrants ................................................................................ 36 Optical communication adapter OKK .......................................................... 41 Application example of electrical interfaces ................................................ 42 Connection diagram - RS485 ...................................................................... 43 Connection diagram - RS485 with GND ..................................................... 43 RS485-two-wire bus system ....................................................................... 43 Connection diagram - RS232 ...................................................................... 44 Connection diagram - CL0 .......................................................................... 45 Connection diagram - LLS .......................................................................... 46 Connection plan - LLS ................................................................................ 46 VARIOMOD XC .......................................................................................... 47 Interface Module XC ................................................................................... 47 Housing- and display elements ................................................................... 48 RS485 interface of the VARIOMOD XC ...................................................... 52 Interfaces of the Interface Module XC......................................................... 52 LED functions of VARIOMOD XC ............................................................... 54 Formation of the maximum demand with a block measuring period ........... 57 Formation of the maximum demand with a sliding measuring period ......... 59 Diagram of standard load profile ................................................................. 63 Operation of the display .............................................................................. 64 Output of manipulations .............................................................................. 77 Diagram - Overconsumption ....................................................................... 80 Diagram of additional load profile ............................................................... 82 Load switching via the call-up button .......................................................... 87 Application plan - recording load profiles form other media ........................ 89 Diagram - Recording of load profiles from several meters .......................... 89 EMH-Mobile ................................................................................................ 99 EMH-Mobile - Table 1 ................................................................................. 99 EMH-Mobile - Installation check ................................................................. 99 EU Declaration of Conformity ................................................................... 119 7 Abbreviations Active energy Positive active energy (customer imports from utility -A Negative active energy (customer exports to utility) AA Active energy, pulse output signal +AA Positive Active energy, pulse output signal -AA Negative Active energy, pulse output signal BV Reactive energy, time integral 1 accord. to OBIS Cl. Accuracy class CS Electrical interface accord. to IEC 62056-21 D0 Optical interface accord. to IEC 62056-21 DIN Deutsches Institut für Normung e.V. (German Institute for standards) DLMS Device Language Message Specification EN European standards ERA Energy direction output ERA+A Energy direction output for active energy ERA+R Energy direction output for reactive energy EVU Utility IEC International Electromechanical Commission Imp. Impulse Imp./kWh Impulse per kWh Imp./kvarh Impulse per kvarh L1, L2, L3 External conductor LC Liquid Crystal LCD Liquid Crystal Display LED Light Emitting Diode LLS Optical fibre interface MAn Output signal for maximum demand tariff n M Maximum demand MKA Alarm contact output Mn Maximum demand tariff n MP Measuring period (only for maximum demand measuring) MPA Measuring period output MPE Measuring period input MR Maximum demand reset, MRA Output maximum demand reset MRE Input maximum demand reset MSB Most Significant Bit MZA Output maximum demand occasionally MZE Input maximum demand occasionally N Neutral conductor OBIS Object-Identification-System P Active power +P Positive active power (customer imports from utility) -P Negative active power (customer exports to utility) PTB PTB (German certified body) Q Reactive power +Q Positive reactive power -Q Negative reactive power Q1 Positive reactive power in ‘Quadrant I’ Q2 Positive reactive power in Quadrant II’ Q3 Negative reactive power in ‘Quadrant III’ Q4 Negative reactive power in ‘Quadrant IV’ A +A 8 R +R -R R1 R2 R3 R4 RA RAR RAA RL RLR RLA RA +RA -RA RA1 RA2 RA3 RA4 RP RS RS1 RS2 RCR RTX RX S0 SEZ TAn te TEn tm Tn TX Un Us UTC WV ZST ZSTs Reactive energy Positive reactive energy Negative reactive energy Positive reactive energy in ‘Quadrant I’ Positive reactive energy in ‘Quadrant II’ Negative reactive energy in ‘Quadrant III’ Negative reactive energy in ‘Quadrant IV’ Output impulse constants Output impulse constants for reactive energy Output impulse constants for active energy Test impulse constants Test impulse constants for reactive energy Test impulse constants for active energy Reactive energy, impulse output signal Positive reactive energy, impulse output signal Negative reactive energy, impulse output signal Reactive energy in ‘Quadrant I’ impulse output signal Reactive energy in ‘Quadrant II’ impulse output signal Reactive energy in ‘Quadrant III’ impulse output signal Reactive energy in ‘Quadrant IV’, impulse output signal Registration period (only for load profile) Display for reset, with one or no terminals Display for reset, Signal a Display for reset, Signal b Ripple Control Receiver Receiver / Transmitter, bi-directional connection, see CS Receiver-connection, see CS Interface accord. to DIN 43 864 Standard load profile meter Output signal for energy tariffs n De-coupling time Input signal for energy tariffs n Measuring period duration Energy tariffs n Sender-connection, see CS Nominal voltage (see DIN EN 61 036) Control voltage Universal Time Co-ordinated Active energy, time integral 1 accord. to OBIS Time stamp (see OBIS) Time stamp with season recognition (OBIS) 1 Prologue 1.1 General In this manual all versions of the LZQJ-XC meter are described. Please note that the meters can be designed differently regarding for example configuration, interfaces, in-/outputs etc. It is therefore possible that meter features are described in this manual which do not apply to the meter(s) used by you. The following table shows which functions are included in the standard configuration and which are available as an option. Function Standard Scrolling list Call-up list Set list Test list Info list Table 1, 2 and service table Option Table 3 Ripple control receiver Performance monitoring Manipulation recognition Load switching Standard load profile P.01 User load profile P.02 Operation log book P.98 Certification relevant log book P.99 User log book P.200 Event log book P.210 Event log book P.211 Installation check Settable pulse constants Settable transformer factors Analysis of the network quality Communication module (pluggable) Power supply from the meter Battery supply reading / reading out Battery supply RTC Optical Esung fibre interface raconet radio interface DCF-evaluation GPS-evaluation Table 1: Standard functions and options 9 1.2 Quoted standards and other documents 10 VDEW-Specifications 2.1 Electronic Load profile meter DIN EN 50160 Voltage characteristics of electricity supplied by public distribution systems IEC 62052-11 Electricity metering equipment (AC) - General requirements, tests and test conditions - Part 11: Metering equipment IEC 62053-21 Electricity metering equipment (a.c.) - Particular Requirements - Part 21: Static meters for active energy (classes 1 and 2) IEC 62053-22 Electricity metering equipment (a.c.) - Particular requirements - Part 22: Static meters for active energy (classes 0,2 S and 0,5 S) IEC 62053-23 Electricity metering equipment (a.c.) - Particular requirements - Part 23: Static meters for reactive energy (classes 2 and 3) IEC 62056-21 Electricity meter - Data exchange for meter reading, tariff and load control - Part 21: Direct local data exchange IEC 62056-46 Electricity metering - Data exchange for meter reading, tariff and load control - Part 46: Data link layer using HDLC protocol IEC 62056-53 Electricity metering - Data exchange for meter reading, tariff and load control - Part 53: COSEM application layer IEC 62056-61 Electricity metering - Data exchange for meter reading, tariff and load control - Part 61: Object Identification System (OBIS) IEC 62056-62 Electricity metering - Data exchange for meter reading, tariff and load control - Part 62: Interface classes DIN 43856 Electricity meters, tariff time switches and ripple control receivers; connection diagrams, terminal marking, circuit diagrams DIN 43857- 2 Watt-hour meters in moulded insulation case without instrument transformers, up to 60A rated maximum current; principal dimensions for polyphase meters DIN 43857- 4 Watt-hour meters in moulded insulation case without instrument transformers, up to 60A rated maximum current; principal dimensions for meter terminal cover for polyphase meters DIN EN 50470-1 Electricity metering equipment (a.c.) - Part 1: General requirements, tests and test conditions - Metering equipment (class indexes A, B and C) DIN EN 50470-3 Electricity metering equipment (a.c.) - Part 3: Particular requirements - Static meters for active energy (class indexes A, B and C) IEC 61000 Electromagnetic compatibility (EMC) IEC 60529 Degrees of protection provided by enclosures (IP code) DIN 66348-1 Interfaces and basic data link control procedures for serial measurement data communication; start-stop-transmission, point-to-point connection ITU-T V.11 Electrical characteristics for balanced double-current interchange circuits operating at data signaling rates up to 10 Mbit/s TIA/EIA-485 Electrical characteristics of generators and receivers for use in balanced digital multipoint systems ITU-T V.24 List of definitions for interchange circuits between data terminal equipment (DTE) and data circuit terminating equipment (DCE). ITU-T V.28 Electrical characteristics for unbalanced double-current interchange circuits 11 2 Tips on mounting and installation 2.1 General safety tips The meters are to be used exclusively for measuring electrical energy and must only be operated within the specified technical data (see nameplate). When installing or changing the meter, the conductor for which the meter is connected must be de-energised. For this purpose only the provided terminals must be used. Contact to parts under voltage is extremely dangerous; therefore the relevant backup fuses are to be removed and stored so that other people cannot insert these unnoticed. Before opening the meter, the secondary circuit to the current transformer must definitely be short circuited. The high voltage on the current transformer is extremely dangerous and destroys the current transformer. With an incorrect installation of the meter, the S0 inputs can lead to mains voltage. Caution: danger! The local standards, guidelines, regulations and instructions are to be obeyed. Only authorised, trained personnel are permitted to install the electricity meters. 2.2 Maintenance- and guarantee tips The meter is maintenance-free. With damages (e.g. caused by transportation or storage) no repairs may be carried out. Once the meter has been opened, all warranty claims cease. This also applies if a defect can be traced back to external influences (e.g. lightning, fire, extreme temperature- and weather conditions, incorrect or careless use or treatment). 12 2.3 Mounting Meters from the series LZQJ-XC are suitable for wall mounting according to DIN 43857-2. Figure 1: Dimensions 13 2.4 Installation When connecting the meter it is very important to take notice of the circuit diagram which you can find on the inside of the terminal cover and also in the delivery documents. In chapter 2.6 Circuit diagrams on page 16 you can find examples of these. 2.4.1 Transformer operated meter Meters for transformer operation are to be protected with a back-up fuse of < 10 A in the voltage path. Figure 2: Back-up fuse with transformer operated meters 2.4.2 Direct connected meter Meters for direct connection are to be protected with a back-up fuse of 100 A. Figure 3: Back-up fuse with direct connected meters 14 Installation check After installation of the meter, it is possible to check if it has been connected correctly by means of the function “Installation check“ in the EMH-COM/COMBIMASTER 2000. This function is not a standard part of the EMH-COM/COMBIMASTER 2000 program, however, can be ordered as an additional module. Open “Readout“ > “Installation check“ The graphic installation display shows the current network behaviour. In the table the current values of phase L1, L2, L3 and also the sum of all phases are shown. Further information can be found in the user manual EMH-COMBI-MASTER 2000. 15 2.5 Terminal blocks 2.5.1 Transformer operated meter Current and voltage terminals Additional terminals Sealing screws of terminal cover Terminal dimensions W x H or d (mm) 5,0 x 5,5 2,6 x 2,2 --- Minimum connection cross section (mm²) 2,5 1,0 --- Maximum connection cross section (mm²)* 6,0 2,5 --- Maximum torques for terminals (Nm) 1,2 --- 0,5 Screw head Screw and washer assembly with cross recess Spring-loaded terminal --- Drive Type PZ1 (acc. to ISO 4757) --- --- Optical fibre connection Button for manipulation recognition * Rated connection capacity acc. to IEC 60999-1 Table 2: Terminal block for transformer operated meters 16 2.5.2 Direct connected meter 60 A Current N-terminal terminals 10, 12 1, 3, 4, 6, 7, 9 N-tap 11 Additional Sealing terminals screws of terminal cover Terminal dimensions W x H or d (mm) 7,5 x 9,5 7,2 3,2 2,6 x 2,2 --- Minimum connection cross section (mm²) 10,0 10,0 1,0 1,0 --- Maximum connection cross section (mm²)* 25,0 25,0 2,5 2,5 --- Minimum torques for terminals (Nm) 4,0 4,0 --- --- --- Maximum torques for terminals (Nm) 5,0 5,0 0,5 --- 0,5 Screw and washer assembly with cross recess Slotted screw Springloaded terminal --- Type PZ2 (acc. to ISO 4757) --- --- --- Screw head Drive Optical fibre connection Button for manipulation recognition For testing the device the voltage path is interrupted by the path separator. With normal operation the path separator is removed! * Rated connection capacity acc. to IEC 60999-1 Table 3: Terminal block for direct conneted meters 60 A Note: External devices which are connected to the voltage taps of the meter (terminals 2, 5 and 8) must be protected with a suitable back-up fuse. The voltage taps of the meter have internally no protection and are directly connected to the system voltage. They may burdened with max. 0,5 A. 17 2.5.3 Direct connected meter 100 A Current N-terminal terminals 10, 12 1, 3, 4, 6, 7, 9 N-tap 11 Additional Sealing terminals screws of terminal cover Terminal dimensions W x H or d (mm) 9,8 x 11,2 10,0 3,2 2,6 x 2,2 --- Minimum connection cross section (mm²) 16,0 16,0 1,0 1,0 --- Maximum connection cross section (mm²)* 35,0 35,0 2,5 2,5 --- Minimum torques for terminals (Nm) 4,0 4,0 --- --- --- Maximum torques for terminals (Nm) 5,0 5,0 0,5 --- 0,5 Screw and washer assembly with cross recess Slotted screw Springloaded terminal --- Type PZ2 (acc. to ISO 4757) --- --- --- Screw head Drive Optical fibre connection Button for manipulation recognition For testing the device the voltage path is interrupted by the path separator. With normal operation the path separator is removed! * Rated connection capacity acc. to IEC 60999-1 Table 4: Terminal block for direct conneted meters100 A Note: External devices which are connected to the voltage taps of the meter (terminals 2, 5 and 8) must be protected with a suitable back-up fuse. The voltage taps of the meter have internally no protection and are directly connected to the system voltage. They may burdened with max. 0,5 A. 18 2.5.4 Pin assignment of the RJ12 socket Altnernatively to the spring terminals, the electrical interface can be equipped as a RS12 socket (6P6C). The pin assignment is described as follows: RJ12 socket Optical fibre connection 6 1 Figure 4: RJ12 socket RS232 interface Pin-No. Desription Function 1 GND Ground 2 RS232 TxD Transmission line 3 RS232 RxD Receiving line 4 N.C. not connected 5 N.C. not connected 6 N.C. not connected Table 5: Pin assignment of the RJ12 socket with a RS232 interface RS485 interface Pin-No. Desription Function 1 GND Ground 2 RS485 A(-) „negative“ connection 3 RS485 B(+) „positive“ connection 4 N.C. not connected 5 N.C. not connected 6 N.C. not connected Table 6: Pin assignment of the RJ12 socket with a RS485 interface CL0 interface Pin-No. Desription Function 1 N.C. not connected 2 + positive connection 3 - negative connection 4 N.C. not connected 5 N.C. not connected 6 N.C. not connected Table 7: Pin assignment of the RJ12 socket with a CL0 interface 19 2.6 Circuit diagrams In this chapter you will find some examples of circuit diagrams in accordance with DIN 43856. When connecting a meter you must pay attention to the circuit diagram which can be found on the inside of the terminal cover or in the delivery documents. Polyphase meter for direct connection in four-wire systems Figure 5: Circuit diagram - Polyphase meter Transformer operated meter for connection to current- and voltage transformer in three-wire systems (Aron connection); 3020 measuring record types M7 and M8 Figure 6: Transformer operated meter; 3020 measuring record types M7 and M8 Transformer operated meter for connection Figure 7: Transformer operated meter; 4020 20 Transformer operated meter for connection to current- and voltage transformer in 1 three-wire systems; 4020 measuring record type M1 Figure 8: Transformer operated meter; 4020 measuring record type M1 Transformer operated meter for connection to current- and voltage transformer in 2 three-wire systems; 4020 measuring record type M3 Figure 9: Transformer operated meter; 4020 measuring record type M3 1 If meter neutral point is not connected, then measuring record type M2 2 Restrictions: Externally – and combined supplied transformer operated meters are restricted to the voltage versions 3x58/100 V and 3x63/110 V in three wire networks with the measuring record types M2, M3,M5 and M6 (neutral point unearthed). For the measuring record types M1 and M4 (neutral point earthed) there are no restrictions. 21 Transformer operated meter for connection to current- and voltage transformer in 1 three-wire systems; 4020 measuring record type M4 Figure 10: Transformer operated meter; 4020 measuring record type M4 Transformer operated meter for connection to current- and voltage transformer in three-wire systems (fake connection with 2 current transformers); 2 4020 measuring record type M6 Figure 11: Transformer operated meter; 4020 measuring record type M6 Restrictions: Externally – and combined supplied transformer operated meters are restricted to the voltage versions 3x58/100 V and 3x63/110 V in three wire networks with the measuring record types M2, M3,M5 and M6 (neutral point unearthed). For the measuring record types M1 and M4 (neutral point earthed) there are no restrictions. 1 If the meter neutral point is not connected, then measuring record type M5 2 Restrictions: Externally – and combined supplied transformer operated meters are restricted to the voltage versions 3x58/100 V and 3x63/110 V in three wire networks with the measuring record types M2, M3,M5 and M6 (neutral point unearthed). For the measuring record types M1 and M4 (neutral point earthed) there are no restrictions. 22 3 General device description 3.1 Meter layout Figure 12: Meter layout 23 3.2 Technical data 3.2.1 Transformer connected meter Voltage 4-wire meter Current 5||1 A, 1(6) A, 1(10) A, 5 A, 1 A, 5(20) A Frequency Accuracy 3x58/100 V...3x240/415 V, 3x400/690 V 50 Hz, 60 Hz, 16,7 Hz active energy Cl.B (Cl. 1), Cl. C (Cl. 0,5 S), Cl. 0,2 S reactive energy Cl. 2,1 % (Cl. 2), 0,5 % (Cl. 2) Measuring system designation compensated current transformer Measuring types active energy +A, -A reactive energy +R, -R, R1, R2, R3, R4 others S, Ah, U²h, I²h LED (Imp./kWh[kvarh]) 10 000 - 100 000 (depending on meter type) output (Imp./kWh[kvarh]) 5 000 - 50 000 (depending on meter type) configuration ability after certification by means of the certification relevant logbook Energy registers maximum number 32 tariff register + 16 tariffless register, each with 15 pre-values Maximum registers maximum number 32 tariff register, each with 15 pre-values measuring period 1, 5, 10, 15, 30, 60 min, adjustable maximum number of channels 32 memory depth at 1 channel up to 3 years with a registering period of 15 min registering period 1, 5, 10, 15, 30, 60 min, adjustable registering type power, energy, energy feed accuracy within ± 5 ppm synchronisation via data interface, control input or DCF-module running reserve battery / capacitor > 20 years / approx. 6 days (150 hours) number of channels 6 telegrams all common telegrams S0-input / system voltage max. 2 / max. 9 (in total max. 10 inputs possible) Meter constants Load profile Real Time Clock Ripple control receiver Control inputs Data retention time Display without voltage with in the EEPROM, at least 10 years version VDEW-display, 84 x 24 mm height of digits in the value range 8 mm alternative display alphanumerical display 4 x 20 characters; 70,4 mm x 20,8 mm; height of digits 4 mm readout without power supply via buffer battery (optional) mechanical buttons for operation of display and reset (sealable under hinged module cover) optical sensor for operation of display optical data interface optical data interface D0 electrical data interface RS485, RS232 or CL0 data protocols IEC 62056-21 or DLMS maximum transmission rate 19200 baud (fixed or Mode C/E) Communication module modem GSM/GPRS, Ethernet, PSTN (analog) (pluggable) interface module RS485, RS232 data protocols IEC 62056-21 or DLMS maximum transmission rate 19200 baud (fixed or Mode C/E) maximum number 8 Opto-MOSFET max. 250 V AC/DC, 100 mA (make contact [NO] or break contact [NC]) S0-output max. 27 V DC, 27 mA relays max. 250 V AC/DC, 100 mA (max. 2 make contacts [NO]) high load relay max. 250 V AC/DC, 10 A (max. 2 make contacts [NO]) switched-mode power supply 3-phase mains buffering time > 500 ms Auxiliary voltage long-range 48…300 V AC/DC (optional) Power consumption voltage path Operation Data interfaces Outputs Energy supply per phase with auxiliary voltage < 0,02 VA / < 0,01 W (3x58/100 V) (Basic meter) without auxiliary voltage < 1,2 VA / < 0,75 W EMC-characteristics current path < 0,004 VA auxiliary voltage < 4,2 VA / < 2,5 VA isolation resistance 4 kV AC, 50 Hz, 1 min surge voltage 8 kV, impulse 1,2/50 μs, 2 Ω (measuring path, auxiliary voltage) 6 kV, impulse 1,2/50 μs, 500 Ω (outputs : Opto-MOSFET, relays; inputs: system voltage) resistance against HF-fields 24 10 V/m (under load) Temperature range specified operating range -25 °C...+55 °C limit range for operation, storage and transport Relative humidity -40 °C...+70 °C max. 95 %, non-condensing, acc. to IEC 62052-11, EN 50740-1 and IEC 60068-2-30 Housing dimensions approx. 180 x 285 x 80 (W x H x D) mm, acc. to DIN 43857 class of protection II degree of protection: housing IP 51 (optional IP 54) degree of protection: terminal block IP 31 housing material polycarbonate glass-fibre reinforced, without halogen, recyclable fire characteristics acc. to IEC 62052-11 Environmental mechanical M1 acc. to Measuring Instruments Directive (2004/22/EC) conditions electromagnetic E2 acc. to Measuring Instruments Directive (2004/22/EC) intended location indoor acc. to EN 50470-1 Weight Further features 1,2 kg measuring of instantaneous P, Q, S (per phase and sum), U, I, power factor, line frequency, values phase failures installation check via instantaneous values (service data) possible optical fibre interface for connection of up to 4 optical fibre separation boxes buffer battery exchangeable buffer battery for reading out the meter via the optical interface and reading the display without power manipulation recognition opening of meter and terminal cover and magnetic fields network analysis monitoring of U, I, THD, f, flicker, harmonics acc. to DIN EN 50160 Table 8: Technical data for transformer connected meters 25 3.2.2 Direct connected meter Voltage 4-wire meter Current 5(60) A, 10(60) A, 5(100) A, 10(100) A Frequency Accuracy 3x127/220 V…3x230/415 V 50 Hz, 60 Hz active energy Cl. A (Cl. 2), optional Cl. B (Cl. 1) reactive energy Cl. 3, optional Cl. 2 Measuring system designation compensated current transformer Measuring types active energy +A, -A reactive energy +R, -R, R1, R2, R3, R4 others S, Ah, U²h, I²h LED (Imp./kWh[kvarh]) 500 - 1 000 (depending on meter type) output (Imp./kWh[kvarh]) 250 - 500 (depending on meter type) configuration ability after certification by means of the certification relevant logbook Energy registers maximum number 32 tariff register + 16 tariffless register, each with 15 pre-values Maximum registers maximum number 32 tariff register, each with 15 pre-values measuring period 1, 5, 10, 15, 30, 60 min, adjustable maximum number of channels 32 memory depth at 1 channel up to 3 years with a registering period of 15 min registering period 1, 5, 10, 15, 30, 60 min, adjustable registering type power, energy, energy feed accuracy within ± 5 ppm synchronisation via data interface, control input or DCF-module running reserve battery / capacitor > 20 years / approx. 6 days (150 hours) number of channels 6 telegrams all common telegrams S0-input / system voltage max. 1 / max. 5 (in total max. 5 inputs possible) Meter constants Load profile Real Time Clock Ripple control receiver Control inputs Data retention time Display without voltage with in the EEPROM, at least 10 years version VDEW-display, 84 x 24 mm height of digits in the value range 8 mm alternative display alphanumerical display 4 x 20 characters; 70,4 mm x 20,8 mm; height of digits 4 mm readout without power supply via buffer battery (optional) mechanical buttons for operation of display and reset (sealable under hinged module cover) optical sensor for operation of display optical data interface optical data interface D0 electrical data interface RS485, RS232 or CL0 data protocols IEC 62056-21 or DLMS maximum transmission rate 19200 baud (fixed or Mode C/E) Communication module modem GSM/GPRS, Ethernet, PSTN (analog) (pluggable) interface module RS485, RS232 data protocols IEC 62056-21 or DLMS maximum transmission rate 19200 baud (fixed or Mode C/E) maximum number 8 Opto-MOSFET max. 250 V AC/DC, 100 mA (make contact [NO] or break contact [NC]) S0-output max. 27 V DC, 27 mA relays max. 250 V AC/DC, 100 mA (max. 2 make contacts [NO]) high load relay max. 250 V AC/DC, 10 A (max. 2 make contacts [NO]) switched-mode power supply 3-phase mains buffering time > 500 ms Auxiliary voltage long-range --- Power consumption voltage path < 1,2 VA / < 0,75 W per phase (Basic meter) current path < 0,01 VA EMC-characteristics isolation resistance 4 kV AC, 50 Hz, 1 min surge voltage 8 kV, impulse 1,2/50 μs, 2 Ω (measuring path, auxiliary voltage) Operation Data interfaces Outputs Energy supply 6 kV, impulse 1,2/50 μs, 500 Ω (outputs : Opto-MOSFET, relays; inputs: system voltage) Temperature range resistance against HF-fields 10 V/m (under load) specified operating range -25 °C...+55 °C limit range for operation, storage and transport Relative humidity -40 °C...+70 °C max. 95 %, non-condensing, acc. to IEC 62052-11, EN 50740-1 and IEC 60068-2-30 26 Housing dimensions approx. 180 x 285 x 80 (W x H x D) mm, acc. to DIN 43857 class of protection II degree of protection: housing IP 51 degree of protection: terminal block IP 31 housing material polycarbonate glass-fibre reinforced, without halogen, recyclable fire characteristics acc. to IEC 62052-11 Environmental mechanical M1 acc. to Measuring Instruments Directive (2004/22/EC) conditions electromagnetic E2 acc. to Measuring Instruments Directive (2004/22/EC) intended location indoor acc. to EN 50470-1 Weight Further features 1,4 kg measuring of instantaneous P, Q, S (per phase and sum), U, I, power factor, line frequency, values phase failures installation check via instantaneous values (service data) possible optical fibre interface for connection of up to 4 optical fibre separation boxes buffer battery exchangeable buffer battery for reading out the meter via the optical interface and reading the display without power manipulation recognition opening of meter and terminal cover and magnetic fields network analysis monitoring of U, I, THD, f, flicker, harmonics acc. to DIN EN 50160 Table 9: Technical data for direct connected meters 27 3.2.2 Direct connected meter with load switching Voltage 4-wire meter Current 5(100) A, 10(100) A Frequency Accuracy 3x230/400 V 50 Hz, 60 Hz active energy Cl. A (Cl. 2), optional Cl. B (Cl. 1) reactive energy Cl. 3, optional Cl. 2 Measuring system designation compensated current transformer Measuring types active energy +A, -A reactive energy +R, -R, R1, R2, R3, R4 others S, Ah, U²h, I²h LED (Imp./kWh[kvarh]) 500 - 1 000 (depending on meter type) output (Imp./kWh[kvarh]) 250 - 500 (depending on meter type) configuration ability after certification by means of the certification relevant logbook Energy registers maximum number 32 tariff register + 16 tariffless register, each with 15 pre-values Maximum registers maximum number 32 tariff register, each with 15 pre-values measuring period 1, 5, 10, 15, 30, 60 min, adjustable maximum number of channels 32 memory depth at 1 channel up to 3 years with a registering period of 15 min registering period 1, 5, 10, 15, 30, 60 min, adjustable registering type power, energy, energy feed accuracy within ± 5 ppm synchronisation via data interface, control input or DCF-module running reserve battery / capacitor > 20 years / approx. 6 days (150 hours) number of channels 6 telegrams all common telegrams S0-input / system voltage max. 1 / max. 5 (in total max. 5 inputs possible) Meter constants Load profile Real Time Clock Ripple control receiver Control inputs Data retention time Display Operation Data interfaces raconet radio module without voltage with in the EEPROM, at least 10 years version VDEW-display, 84 x 24 mm height of digits in the value range 8 mm readout without power supply via buffer battery (optional) mechanical buttons for operation of display and reset (sealable under hinged module cover) optical sensor for operation of display optical data interface optical data interface D0 (Mode C/E up to 19200 baud) electrical data interface RS485, RS232 or CL0 (fixed or Mode C/E up to 19200 baud) data protocols IEC 62056-21 or DLMS radio interface integrated raconet radio module (up to 9600 baud) functions meter remote readout via bi-directional communication, online mode, (pluggable) transferring of commands, automatic network build-up etc. transmitting frequency 868 MHz in licence free ISM-band certification acc. to DIN EN 300220 Communication module modem GSM/GPRS, Ethernet, PSTN (analog) (pluggable) interface module RS485, RS232 data protocols IEC 62056-21 or DLMS maximum transmission rate 19200 baud (fixed or Mode C/E) Load switching Outputs via command, call-up bottom or exceeding overload threshold maximum number 6 Opto-MOSFET max. 250 V AC/DC, 100 mA (make contact [NO] or break contact [NC]) S0-output max. 27 V DC, 27 mA relays max. 250 V AC/DC, 100 mA (max. 2 make contacts [NO]) high load relay max. 250 V AC/DC, 10 A (max. 2 make contacts [NO]) switched-mode power supply 3-phase mains buffering time > 500 ms Power consumption voltage path < 10 VA / < 2 W per phase (Basic meter) current path < 4 VA EMC-characteristics isolation resistance 4 kV AC, 50 Hz, 1 min surge voltage 6 kV, impulse 1,2/50 μs, 500 Ω (measuring paths, outputs: Opto-MOSFET, relays) resistance against HF-fields 10 V/m (under load), 30 V/m (without load) specified operating range -25 °C...+55 °C Energy supply Temperature range limit range for operation, storage and transport Relative humidity -40 °C...+70 °C max. 95 %, non-condensing, acc. to IEC 62052-11, EN 50740-1 and IEC 60068-2-30 28 Housing dimensions approx. 180 x 285 x 80 (W x H x D) mm, acc. to DIN 43857, height with antenna approx. 375 mm class of protection II degree of protection: housing IP 51 degree of protection: terminal block IP 31 housing material polycarbonate glass-fibre reinforced, without halogen, recyclable fire characteristics acc. to IEC 62052-11 Environmental mechanical M1 acc. to Measuring Instruments Directive (2004/22/EC) conditions electromagnetic E2 acc. to Measuring Instruments Directive (2004/22/EC) intended location indoor acc. to EN 50470-1 Weight Further features 1,8 kg measuring of instantaneous P, Q, S (per phase and sum), U, I, power factor, line frequency, values phase failures installation check via instantaneous values (service data) possible optical fibre interface for connection of up to 4 optical fibre separation boxes buffer battery exchangeable buffer battery for reading out the meter via the optical interface and reading the display without power manipulation recognition opening of meter and terminal cover and magnetic fields network analysis monitoring of U, I, THD, f, flicker, harmonics acc. to DIN EN 50160 internal disconnection relais the dielectric strength in open disconnection relay is 2 kV AC, 50 Hz, 1 min Table 10: Technical data for direct connected meters with load switching 29 3.3 Housing-, operation- and display elements Q-LED Parameterisation button P-LED Optical call-up button Sealing screw Sealing screw Optical data interface D0 Call-up button LC-display Reset button Battery compartment Sealing eye Sealable module cover Nameplate Transformer nameplate Communication module compartment Meter cover Sealing screw Sealing screw Terminal cover Figure 13: Meter elements 30 3.3.1 Display In the standard version the display is not illuminated, however, this can be realised at the customer’s request. The display is set up as follows: 2 1 3 4 5 6 MAN INST PWR T1 T2 T3 T4 M1 M2 M3 9 M4 RCE 8 RL CLOCK SET 7 Figure 14: Display 1. The operation display shows the current direction of energy as measured by the meter (export/import of active energy, export of inductive/capacitive reactive energy). If current is flowing it is possible to see in which quadrant is being measured by means of the energy direction arrow e.g.: st 1 Quadrant +P/+Q 2 nd Quadrant -P/+Q rd 3 Quadrant -P/-Q th 4 Quadrant +P/ -Q 31 2. The battery status display shows the charging status of the buffer battery of the real time clock. The following displays are possible: full voltage, real time clock is buffered when there is no voltage discharged, no buffering of the real time clock is possible 3. The communication display is continually lit-up when there is communication with the meter via data interfaces (optical or electrical) or the display flashes when the parameterisation status is active. 4. The phase display signalises connection of the individual phase voltages. With an incorrect rotating field all three symbols flash. 5. The unit is displayed corresponding to the measured energy type or the displayed measured value. 6. In the additional cursor field, operation conditions of the meter are represented. The black arrows show if a manipulation or an installation error has been registered or if the performance threshold has been exceeded. MAN The cursor is active if a manipulation has been registered on the terminalor meter cover or electromagnetic interference. INST The cursor is active if an entry has been registered in the installation check register. PWR The cursor is active if a power threshold set in the meter is exceeded. 7. In the standard cursor field, operation conditions of the meter are represented. The black arrows show which tariff and maximum demand is active and via which hardware (clock or ripple control receiver) the meter should be controlled. T1-T4 Tariff information for energy. All tariff registers which can be activated are displayed on the nameplate. M1-M4 Tariff information for maximum demand. All tariff registers which can be activated are displayed on the nameplate. RCR The cursor flashes when the internal RCR is activated and ready to receive. The relevant cursor is continually active when the internal ripple control receiver receives a telegram. RL The cursor flashes for the duration of the activation of a reset inhibition. CLOCK The cursor is active if the internal clock controls the tariff device. SET The cursor is active when the meter is in the set mode. 8. In the value area the measured values are represented. 9. In the OBIS code area the measured values are defined by means of the OBIS code. The display is capable of displaying the long OBIS code (see page 92). 32 3.3.2 Test - LEDs The Test-LEDs are used for the output of energy proportional active- and reactive energy impulses, for certification of the meter and for the display of start-up and no load operation. The impulse constants depend on the meter type. If the meter measures no current or current below the start-up threshold, the meter is in the no-load operation mode. In this case, the LED is continually lit-up. With Combimeters the LED is continually lit-up if the energy flow direction is negative. If the meter measures current above its start-up threshold, energy proportional impulses are displayed. 3.3.3 Call-up and reset button The call-up button serves to call up the display lists in the display. Via the reset button, which is situated behind the sealable module cover, a manual reset can be carried out. 3.3.4 Optical call-up sensor The optical call-up sensor serves to call up the display lists in the display. Operation of the display takes place by means of a pocket lamp. 3.3.5 Parameterisation button The parameterisation button is used to activate the parameterisation status in the meter. The button is located under the meter cover. To operate this button the meter must be opened which means the seals must be broken. Breaking the seals means that the certification expires and therefore this may only be carried out by authorised personnel. When the meter is in the parameterisation status the communication symbol flashes in the display. 3.3.6 Optical data interface D0 Communication between the meter and PC takes place via the optical data interface. An optical communication adapter OKK is required for this. In order to fix the OKK to the meter there is a magnetic ring which is found on the meter cover. Further information on the optical data interface can be found on page 41. 3.3. Meter cover The meter cover is made of crystal clear polycarbonate. The housing cover is mounted at the bottom in the baseplate and screwed at the top with both of the sealing screws. With the relevant configuration, when removing the housing cover, a manipulation is registered. More detailed information can be found on this in chapter “6.1 Manipulation” on page 77. 33 3.3.8 Sealable terminal cover The terminal cover is made of grey polycarbonate and is fixed to the terminal block with sealing screws. The circuit diagram is fixed on to the inside of the terminal cover. With the relevant configuration, when removing the terminal cover, a manipulation is registered. More detailed information on this can be found in chapter “6.1 Manipulation“ on page 77. 3.3.9 Battery compartment The battery compartment is found under the sealable module cover. A lithium battery (CR-P2, 6 V) can be assembled here which, if necessary, can be exchanged. The battery is used for reading out the meter via the optical interface and for reading the display during power failure. It also buffers the real time clock. In the delivery status the battery function is not active. To activate it, open the hinged cover and pull out the readout battery. Then remove it from the holder and flip it over so that the battery contacts to the compartment. Afterwards push the battery incl. folder in the battery compartment with the contacts of the compartment facing left. Finally close the hinged cover. 3.3.10 Communication module compartment The communication module compartment is found under the sealable module cover. Here a modem- or interface module can be inserted. Mounting and removal can take place when the meter is under voltage. Further information on the modules can be found on page 17 and also in the LZQJ accessories catalogue. 3.3.11 Nameplate The nameplate contains data for identification of the meter, the approval mark, technical specifications and explanations. The cursor lettering below the display and the description of the OBIS code on the nameplate are standard and not adapted to the meter version. The nameplate can contain more information than is configured on the existing version. The parameterised functions are to be taken from the list of desied features. 3.3.12 Transformer nameplate Transformer operated meters (in general secondary meters) are equipped with a transformer nameplate which is found under the sealable module cover. On the transformer nameplate the following information is displayed: Figure 15: Transformer nameplate 34 3.4 Modules Fundamentally the meter consists of: Switched-mode power supply Measuring device Tariff device Interfaces In- and outputs In the following the most important modules are described. 3.4.1 Voltage supply 3.4.1.1 Direct supply The LZQJ-XC is supplied via a primary switched, long-range power supply (3x58/100 V ... 3x240/415 V) with a high degree of efficiency. The power supply is “earth-fault proof“ and guarantees operation without the neutral conductor (N). In case a component fails during operation the power supply is overload- and short-circuit-proof. With single-phase connected meters from the LZQJ series a faultless operation up to Unom + 15% / - 20% is guaranteed. Permitted voltage versions: Measuring voltage Application 3 x 58/100 V 3 x 63/110 V 3 x 66,4/115 V 3 x 115/200 V 3 x 127/220 V 3 x 220/380 V 3 x 230/400 V 3 x 240/415 V 3 x 58/100 V – 240/415 V 4-wire 4- wire 4- wire 4- wire 4- wire 4- wire 4- wire 4-wire 4- wire 3.4.1.2 Auxiliary voltage Only valid for LZQJ-XC-P2 ... and LZQJ-P5 ... (precision meters with accuracy class 0.2 and 0.5)! The LZQJ-XC as a precision meter has the possibility of external auxiliary voltage supply. In general there are two types of supply which are differentiated between: a) Auxiliary supply The energy for the electronic measuring device is only taken from the auxiliary supply. The auxiliary supply and measuring circuit voltage are galvanically separated. b) Combined supply With certain voltage conditions the power for the electronic device is no longer taken from the auxiliary supply, instead, it is taken from the measuring circuit voltage. If the auxiliary supply completely fails, the power for the electronic measuring device is taken exclusively from the measuring circuit voltage (feature of the combined supply). This means, the meter is completely capable of functioning even if the auxiliary supply fails (advantage when compared to option a)). The presence of auxiliary voltage supply relieves the load in the voltage paths in the measuring system, resulting in a substantial decrease in apparent power consumption (see Table 11). 35 Measuring voltage Apparent power consumption per measuring-circuit voltage path 3x58/100 V up to 3x63/110 V with combined supply 3x58/100 V up to 3x63/110 V with auxiliary voltage supply 0.02 VA 3x220/380 V up to 3x240/415 V with combined supply, class of protection 2 0.26 VA 3x220/380 V up to 3x240/415 V with auxiliary voltage supply Table 11: Apparent power consumption 3.4.2 Measuring device 3.4.2.1 Measuring principle The electrical energy is measured by processing the sampling values which the Analog Digital Transformers (ADC) send to the processor. By means of this, all of the measured values can be measured or calculated in all quadrants. The calculation ensures that the values are stable and resistant to ageing. Figure 16: Definition of quadrants 3.4.2.1.1 Voltage measurement The terminal voltages create network proportional internal voltage levels at internal voltage dividers. These are fed into the 3 input channels of the ADC. 3.4.2.1.2 Current measurement For measuring current, error compensated current transformers are used. The output variables of the respective amplifier are fed into the 3 input channels of the ADC. 36 3.4.2.1.3 Data protection During operation the current measurements are stored in the working memory (RAM). Every 24 hours this data is transferred to a non-volatile memory. It is only in cases of longer interruptions that the measuring period is interrupted and the device completely shuts down. Data remains stored in the non-volatile memory for at least ten years. No buffer battery is needed to preserve the data. The data retention is assured exclusively by the qualities of the storage medium (Flash). 3.4.3 Tariff switching clock The tariff switching clock is integrated into the meter. It is based on a quartz-controlled, battery or capacitor-buffered real time clock (RTC) which provides time information (date, day of week, time) in second intervals. Switching times can be configured exclusively for the customer by means of: 16 season tables, 16 day types or 384 holiday definitions for any weekdays These switching times are compared continually with the real time clock. If they coincide with the configured switching times or switching periods, the switching function is activated. Switching functions are the activation of the maximum demand registers and energy registers. As a result of this, 32 energy registers and maximum demand registers each with a maximum of 8 tariffs can be configured via the tariff switching clock. At the beginning of the summer period an hour is added on to the time of the tariff switching clock (CET). The beginning and end of the summer period is determined with the help of a summer time register. This register is settable in order to be able to react to possible changes of the current valid summer time regulations. The accuracy of the real time clock is within ± 5ppm. The buffering of the real time clock (RTC) can take place by a SuperCap-capacitor with a running reserve of approx. 6 days (150 hours). With a completely discharged SuperCap the charging time is approx. 18 min after applying the voltage phases (90% voltage). Instead of a SuperCap-capacitor, the buffering can take place by using a battery (dry Li-battery) with a running reserve of > 20 years. The latter is recommended for meters with load profile memories so that the load profile is correctly dealt with chronologically when there are longer power interruptions or if the meter has been turned off for longer periods. As a rule, the real time clock is quartz controlled however, can also be synchronised via the following variations: Synchronisation of the real time clock via the line frequency The clock is synchronised cyclically by a mains frequency controlled timer Synchronisation of the real time clock via an impulse at the input contact Synchronisation takes place at o the next full 1 minute or o next measuring period limit or o a fixed time of the day Synchronisation of the real time clock via a DCF77-receiver connected to the S0-input DCF77 is a time signal which is emitted via longwave. The circulation is carried out by the PTB and serves as the legal time. In the DCF77 signal, time information of the next complete minute is coded to which the meter then synchronizes itself. 37 Configuration of the real time clock (RTC) Open “Configuration“ > “COMBI-TOOL“ > “Meter“ > “Real Time Clock“ Configuration of the holidays Open “Configuration“ > “COMBI-TOOL“ > “Tariff configuration“ > “Public Holidays“ Configuration of the seasons Open “Configuration“ > “COMBI-TOOL“ > “Tariff configuration“ > “Seasons“ 38 Configuration of the energy tariffs Open “Configuration“ > “COMBI-TOOL“ > “Tariff configuration“ > “Energy tariffs“ Configuration of the maximum demand tariffs Open “Configuration“ > “COMBI-TOOL“ > “Tariff configuration“ > “Maximum Demand tariffs“ Further information can be found in the user manual EMH-COMBI-MASTER 2000. 39 3.4.4 Ripple control receiver (RCR) The integrated rippple control receiver of the LZQJ-XC is based on a highly selective recursive filter which directly processes the16 bit sampling values of the AD-transformer. Due to the sampling rate of 3200 Hz, ripple control frequencies in the range of 110 to 1600 Hz are supported. The following telegrams can be configured. ABB Ricontic b ABB Ricontic s L&G Semagyr 50a L&G Semagyr 50b L&G Semagyr 52 L&G Semagyr 56 RWE Sauter Schlumberger Pulsadis I Schlumberger Pulsadis II EdF CDC Siemens TELENERG Zellweger ZAG 60 Zellweger ZAG 180 Decabit ZPA The telegrams differ by their command evaluation procedure and by their digital structure of the pulse sequence. The ripple control receiver can switch 6 ripple control relays which are available for control functions of the meter. Also tariff- and maximum demand controls, resets and caution signals can be passed on directly via terminals or optical fibre interfaces. Reading out and setting of the RCR position of the ripple control receiver Open “Direct“ > “RCR position...“ After activation of the menu option, the relay position of the ripple control receiver is read out first of all. Next a window opens in which the relevant relay position is marked with an “X”. The relay position can be changed by means of a double click on the appropriate field. To send the changed settings to the meter click on “Write“. 40 3.4.5 Data interfaces Data exchange between meters and readout devices (eg. PC, modem, PDA, etc.) takes place via the optical interface (D0) or, at auxiliary terminals, via the electrical interface (RS232, RS485, CL0). Communication is in accordance with DIN EN 62056-21 or DLMS. 3.4.5.1 Optical data interface D0 Communication between the meter and the PC takes place via the optical data interface. For this an optical communication adapter (OKK) is necessary which can be obtained from EMH. The OKK is available for connection to a readout device with a RS232-, USBor Bluetooth interface. It has a magnet to fix it to the iron ring situated on the front of the housing cover. Transmission rates from 300 to 9600 Baud, fixed or mode C/E can be set. Figure 17: Optical communication adapter OKK Configuration of the optical interface Open “Configuration“ > “COMBI-TOOL“ > “Meter“ > “Interfaces“ Further information can be found in the user manual EMH-COMBI-MASTER 2000. 41 3.4.5.2 Electrical interface Depending on the model, the LZQJ has the following electrical interfaces: CL0 RS485 RS232 Simultaneous operation of the first electrical interface and optical interface is not possible. In addition to the above listed interfaces a modem- or interface module can be mounted in the communication module compartment. By means of this it is possible to grant third parties restricted access to the meter data. The first interface can be used in parallel by the utility company for meter communication with access to all data. By means of a multilevel password concept, the access rights can be easily assigned. Figure 18: Application example of electrical interfaces Via the electrical interfaces, transmission rates of 300 to 19200 baud are possible. Configuration of interfaces Open “Configuration“ > “COMBI-TOOL“ > “Meter“ > “Interfaces“ Further information can be found in the user manual EMH-COMBI-MASTER 2000. 42 3.4.5.2.1 Electrical interface RS485 The electrical interface RS485 is a symmetrical two wire interface (half duplex) and is designed according to TIA/EIA-485 / ITU-T V.11. The galvanic de-coupled interface is found at the auxiliary terminals 23 (A) and 24 (B) and optionally at 27 (GND). Figure 19: Connection diagram - RS485 Figure 20: Connection diagram - RS485 with GND Features Number of connected meters up to 32 Maximum cable length up to 1000 m Data transmission rate 300 ... 19200 Baud Signal accord. to TIA/EIA-485 / ITU-T V.11 logic “1“ -0.3 V to –6 V logic “0“ +0.3 V to + 6 V Table 12: Specification of RS485 interface RS485 Norm-Bus Up to 32 devices can be operated on one RS485 Bus. Normally in bus systems the first and last device are terminated by a terminal resistor between wire “A” and “B” in order to eliminate conductor reflections. Bus structure: 23 24 Device 1 Device 2 Device 32 siehe Detail see device 1 RTERM= 120 A B ... A B max. 5 m A B RS485-two-wire bus max. 1000 m Figure 21: RS485-two-wire bus system 43 3.4.5.2.2 Electrical interface RS232 The electrical interface RS232 is a symmetrical two-wire interface designed according to ITU-T V.24 and ITU-T V.28. The galvanic de-coupled interface is found at three auxiliary terminals 23 (RxD) and 24 (TxD) and at 27 (GND). Figure 22: Connection diagram - RS232 Features Number of connected meters Maximum cable length up to 15 m Data transmission rate 300 ... 19200 Baud Signal accord. to ITU-T V.28 Table 13: Specification of RS232 interface 44 1 logic “1“ - 3 V to - 15 V logic “0“ + 3 V to + 15 V 3.4.5.2.3 Electrical interface CL0 (CS) The galvanic de-coupled CL0 interface is designed according to DIN 66348, part 1. It is a passive two-wire interface which means that it does not have its own power source. The data is transmitted by electric current / no electric current (Mark/Space) at a nominal current of 20 mA which is the reason why the CL0 interface is also referred to as the 20 mA current interface. The CL0 can be found at the auxiliary terminals 23 (+) and 24 (-) in accordance with the VDEW-Specifications 2.1. Figure 23: Connection diagram - CL0 The voltage drop in the meter of the series-connected transmitter is approx. 2 V and of the receiver is approx. 3 V so that a maximum of 4 meter outputs (dependent on the meter modem) can be connected in series and operated by a modem. General features Number of connected meters 1 Max. cable length up to 1000 m Data transmission rate 300 ... 19200 Baud Electrical features Signal One zero Sender 11m A ≤ 2,5m A Recipient 9mA ≤ 3m A Permitted voltage drops Sender max. 2 V Recipient max. 3 V Maximum values Current 30 mA (short circuit) Voltage 30 V (open electric circuit) Table 14: Specification of CL0 interface 45 3.4.5.3 Optical fibre interface LLS At the meter terminal L there is a coupling point to which an optical fibre can be connected by simply plugging- and screwing in. The other end of the optical fibre is plugged into the optical fibre separation box. The optical fibre interface can be found at the auxiliary termnal L. Figure 24: Connection diagram - LLS The optical fibre separation box is in DIN-Rail housing according to EN 50 022 and it has its own optical fibre output so that a total of four relay boxes can be cascaded. Figure 25: Connection plan - LLS For each relay box up to 6 control outputs can be realised, altogether a total of 24 control outputs. Each output of the optical fibre separation box can be designed as a relay(optional with suppressor circuit) or Opto-MOSFET output or as a make- or break contact. The optical fibre separation box is supplied by a long range network power supply from 100V to 230V. A complex input suppressor circuit protects the meter from destruction as a result of bad power supply. With the described arrangement, an optimal isolation is obtained by means of galvanic separation of the optical fibre between the meter and relay boxes. Features Number of connected boxes up to 4 Length of the optical fibre: Meter-Box up to 20 m Length of the optical fibre: Box-Box up to 50 m Data transmission rate 4800 Baud Table 15: Specification of optical fibre interface 3.4.5.4 raconet radio interface The raconet radio interface enables a wireless bi-directional communication like data readout and transmission of commands between meter and data collector. The data transmission takes places with 868 MHz in the license free and regulated ISM-Band. The antenna of the radio interface can be designed as integrated antenna or as housing antenna. Further information for raconet readout system you can find in separately documents. 46 3.4.6 Communication modules A distinct advantage of the LZQJ-XC is the possibility to change or upgrade a communication module during operation. Thereby installation costs are minimized and it is avoided that the consumer is switched off. 3.4.6.1 Modem module VARIOMOD XC The following modem modules are available: VARIOMOD XCanalog VARIOMOD XCgsm VARIOMOD XCgprs VARIOMOD XCethernet Figure 26: VARIOMOD XC 3.4.6.2 Interface Module XC Figure 27: Interface Module XC 47 3.4.6.3 Technical data Voltage from meter or external plug-in power supply unit Temperature range Operation Storage Analog -25°C…+55°C -40°C…+80°C GSM -10°C…+55°C -25°C…+70°C GPRS -10°C…+55°C -25°C…+70°C Ethernet -25°C…+55°C -40°C…+80°C Relative humidity 0…95%, non-condensing Degree of protection housing IP 20 Weight approx. 90 g 3.4.6.4 Housing- and display elements Slot for SIM card (only GSM/GPRS version) Connection to LZQJ-XC (pins) LEDs Type designation Type code Serial number Total insulation Year of manufacture Description of the connections Connections Figure 28: Housing- and display elements 48 3.4.6.5 Important tips for mounting and installation Safety tips The communication modules are electronic appliances and may not be used for any other purposes. Mounting may only be carried out by electronic specialists according to the generally recognised codes of practice and according to the standard requirements for the installation of telecommunication systems and devices. Before assembly, please examine the communication module for any exterior, obvious transport damages and on location check the electrical operating conditions. Mounting can take place under voltage. The communication module should be stored, used and transported in a way so that the pins cannot be damaged. Assembly of the external aerial with GSM- and GPRS modules When assembling the exterior aerial (which is available as an optional accessory) the assembly fixing bracket must be earthed against lightning by a specialist! Inserting the SIM card in the GSM- and GPRS modules Only insert the SIM card when the appliance is switched off! Maintenance- and guarantee tips The communication module is maintenance-free. With damages (e.g. caused by transportation or storage) no repairs may be carried out. Once the meter has been opened, all warranty claims cease. This also applies if a defect can be traced back to external influences (e.g. lightning, fire, extreme temperature- and weather conditions, incorrect or careless use or treatment). 49 3.4.6.6 Mounting and installation 3.4.6.6.1 Mounting and removal of the communication module Tip: Before you mount or remove the communication module or connect the connection cable read the safety tips on page 49! Mounting the communication module: 1. 2. 3. 4. 5. 6. 7. 8. Remove the terminal cover [5]. Open the hinged cover [1]. With GSM/GPRS modem: Insert the SIM card. Insert the module [3] in the communication module compartment [2]. Push the module in the module compartment [2] until the module snaps in. Connect the connection cable to the module. Close the hinged cover [1]. Mount the terminal cover [5] on the terminal block [4]. Removing the communication module: 9. 10. 11. 12. 13. 14. Remove the terminal cover [5]. Open the hinged cover [1]. Disconnect all connection cables. Push down the module [2]. Close the hinged cover [1]. Mount the terminal cover [5] on the terminal block [4]. 1 2 3 4 5 50 3.4.6.6.2 Connection VARIOMOD XCanalog VARIOMOD XCgsm/gprs VARIOMOD XCethernet Interface Module XC Pin-No. Designation Function 1 2 3 GND RS485 A (-) RS485 A (+) Ground „negative“ connection of the RS485 interface „positive“ connection of the RS485 interface 4 N.C. not connected 5 6 GND +UB Ground external supply (optional) 7 8 GND RS485 A (-) Ground „negative“ connection of the RS485 interface 9 10 RS485 A (+) N.C. „positive“ connection of the RS485 interface not connected 11 N.C. not connected 12 N.C. not connected VARIOMO XCanalog Pin-No. Designation Function 13 14 N.C. N.C. not connected not connected 15 16 PSTN PSTN analog telephone network analog telephone network 17 18 N.C. N.C. not connected not connected VARIOMOD XCethernet Pin-No. Designation Function 13 14 Tx+ Tx- Ethernet 10BaseT 100BaseTx assignment 15 16 RX+ 17 18 RX- 19 20 Interface Module XC Pin-No. Designation Function 13 14 GND RS232 TxD Ground Transmission line 15 16 RS232 RxD N.C. Receiving line not connected 17 18 N.C. N.C. not connected not connected 51 3.4.6.6.2 Connection of external devices to the communication module 3.4.6.6.2.1 Modem module VARIOMOD XC The modem module has a RS485 interface. Connection of the external devices takes place acc. to Figure 29. Potential equalisation Figure 29: RS485 interface of the VARIOMOD XC 3.4.6.6.2.2 Interface Module XC The interface module has a RS232- and RS485 interface. However, only one interface can be used. Simultaneous operation is not possible! Connection of the external device takes place acc. to Figure 30. Potential equalisation Figure 30: Interfaces of the Interface Module XC 3.4.6.6.3 Start up of the communication module 3.4.6.6.3.1 VARIOMOD XCanalog To connect the VARIOMOD XCanalog to the analog telephone network, plug the telephone cable into the socket [1] next to the terminal block. The plug must snap in. The other side of the telephone cable is plugged into the telephone socket [2]. [1] [2] 3.4.6.6.3.2 Insertion/removal of the SIM card with VARIOMOD XCgsm/gprs Tip: Only insert the SIM card when the appliance is switched off! Before final assembly of the VARIOMOD XC a SIM card must be inserted which is activated for data transfer. SIM cards with a deactivated PIN or with PIN “0000” can be used. If a SIM card with a different PIN should be used, the module is to be reconfigured with the VARIOMOD Manager. The SIM card is not included in the delivery! 52 Insert the SIM card Insert the SIM card [1] in the card slot.The card will snap in. Remove the SIM card Push downwards the SIM card [2]. The SIM card moves upward automatically [3]. Now remove the SIM card [4]. 3.4.6.6.3.3 Assembly oft he aerial with VARIOMOD XCgsm/gprs The magnetic fixing aerial (provided) is screwed to the FME-sleeve of the module. In order to guarantee optimal reception, the aerial should be mounted outside meter cabinets, upright on a magnetic surface. Manetic fixing aerial FME-sleeve [1] External aerial Assembly fixing bracket With the assembly of an external aerial (available as an optional accessory), the assembly fixing bracket must be earthed against lightning by a specialist! 3.4.6.6.3.4 VARIOMOD XCethernet To connect the module to a network, plug the network cable into the left socket [1]. The plug must snap in. The other side of the network cable is plugged into a network socket [2], into a switch [3] or into a network socket of a computer. [1] [2] [3] 53 3.4.6.6.3.5 Switching on the VARIOMOD XC After applying power (Power-LED lights up / flashes) or after a reboot (reset) the VARIOMOD performs an initialisation. If the Error-LED flashes or lights up this means there is interference. In this case please contact your supplier. 3.4.6.6.3.6 LED displays For optical indication of the operation modes the VARIOMOD XC has 3 light emitting diodes (LEDs). LED VARIOMOD Xcanalog VARIOMOD XCgsm/gprs VARIOMOD XCethernet Power (green) Flashes: Connection to meter and to analog telephone network established Flashes: Connection to meter established, SIM card is initialised, display of the field strength (switching time or number of flashes is the measurement taken for the field strength) Flashes: Connection to meter and to network established Lights up: Voltage applied but no connection to meter or to analog telephone network Lights up: Voltage applied but no connection to meter or SIM card doesn´t initialize Lights up: Voltage applied but no connection to meter or to network Off: No voltage applied Off: No voltage applied Off: No voltage applied Connect (yellow) Flashes: Establishment of a connection Lights up: Connection established Error (red) Flashes: Error Lights up: Error Figure 31: LED functions of VARIOMOD XC 54 3.4.7 In- and outputs 3.4.7.1 Inputs The transformer operated version of LZQJ-XC can be equipped with max. 10 inputs and designed as follows: max. 9 x system voltage inputs and 1 x S0 input or max. 8 x system voltage inputs and 2 x S0 inputs The direct connected version of the LZQJ-XC can be equipped with a maximum of 5 inputs and designed as follows: max. 4 x system voltage inputs and 1 x S0 input or max. 5 x system voltage inputs The inputs can be used e.g. for tariff switching, synchronisation of the RTC or as an impulse input for external electricity meters. Optionally other media such as gas- or water can be registered (see 6.8 Recording external measuring variables). Specifications System voltage Low voltage S0 58...230 V AC, potential-free fmax = 16,67 Hz Contact closing time tmin = 20 ms Contact opening time tmin = 40 ms 12…78 V DC, potential-free (option: 10…120 V AC, potential-free) fmax = 16,67 Hz Contact closing time tmin = 20 ms Contact opening time tmin = 40 ms max. 27 V DC, 27 mA (active), not potential-free fmax = 50 Hz Contact closing time tmin = 10 ms Contact opening time tmin = 10 ms Table 16: Specification of inputs 3.4.7.2 Outputs A maximum of 8 output contacts are available for supplying impulses to the customer. The contacts may be S0-outputs, relay- (max. 2) or MOSFET-outputs. MOSFET-outputs can be designed either as a make- or break contact. Relay outputs are realised as make contacts. If the output contacts listed here are not sufficient, the option of the optical fibre interface (LLS) for separate connection of an optical fibre separation box is recommended. Specifications S0 Relay High load relay Opto-MOSFET Pulse time 20 to 500 ms (25 to 1 Hz) in 10 ms-steps; Energy impulses 100-100.000 Imp./kWh; max. 27 V DC, 27 mA (passive) max. 250V AC/DC, 100 mA max. 250V AC/DC, 10 A max. 250V AC/DC, 100 mA Table 17: Specification of outputs The outputs can be used for example as impulse-, tariff-, measuring period- or alarm outputs. Note: With the wiring of pulse outputs, the maximum load capacity (see Table 17: Specification of outputs) must be observed. If necessary, a resistor or relay is to be inserted (activated). 55 4 Firmware Diverse configurable variables have been programmed in the meter which define the meters functions. These include: settable variables parameterable variables Settable variables can be changed by operation buttons or one of the interfaces. Parameterable variables include variables which define the properties of the counter. Parameterable variables can be changed via the optical interface D0 or one of the electrical interface. To do this, the meter must be in the parameterisation status (by pressing the parameterisation button). To operate the parameterisation button, the meter cover must be opened which means that the seals must be broken. Breaking the seals means that the certification is no longer valid and may therefore only be carried out by authorised personnel. When the meter is in the parameterisation status only the communication symbol flashes. The parameterisation status is ended by means of the following: 24 hours of uninterrupted operation Command F.F() (deletion of the error register) Deletion of the error register Open “Direct“ > “Single commands...“ > “Meter“ > “Write command“ and enter the following: Further information can be found in the user manual EMH-COMBI-MASTER 2000. 56 4.1 Tariff device The tariff device calculates the consumed or supplied electrical power or energy on the basis of the digitalised measured values and allocates it to the power and energy registers. 4.1.1 Energy- and maximum demand tariffs With the LZQJ meter, a maximum of 32 registers each can be configured for electrical energy and maximum demand. Each register has a memory with up to 15 pre-values which represent the measured values and the time stamp of the last 15 reset periods. The assignment of the measured variables is configured at EMH according to the customer’s requirements. 4.1.1.1 Maximum demand metering 4.1.1.1.1 Block measuring period One possibility of forming the maximum is based on the measurement of the average power during a block measuring period tm. The time integral of the accrued energy is divided by the measuring period. If the current maximum demand value exceeds the highest measured maximum demand value since the beginning of the billing period, this value is saved as the new maximum demand in the relevant register with the appropriate time stamp. The duration of the measuring period tm is derived from the real time clock (RTC). The duration of the measuring period can be configured to 1, 5, 10, 15, 30 or 60 minutes. The beginning of a measuring period is activated by an: Internal switching signal: Tariff switching clock Ripple control receiver, or External switching signal at one of the auxiliary terminals: At the control input S0 At a control input (system voltage) configured for this purpose Figure 32: Formation of the maximum demand with a block measuring period 57 4.1.1.1.2 Sliding measuring period An additional possibility of forming the maximum is measuring the average power over a sliding measuring period. The measuring period can be divided into several partial measuring periods depending on the measuring period length. By means of this, a sliding average value is created which is updated at the end of each partial measuring period. This average value is saved in a circular memory at the end of every partial measuring period and the sliding maximum is calculated on the basis of the entries saved in this circular memory. Formation of the sliding maximum begins with the first partial measuring period after a reset. As can be seen from the following example, a complete measuring period (in the example with 3 partial measuring periods) is required before the first valid value (1.85 kW) is available. A new, valid sliding measuring period is available at the end of each next partial measuring period. If the current power value exceeds the highest power value which has occurred since the beginning of the sliding measuring period, it is saved as the new, valid maximum in the appropriate register with a measuring period time stamp. The measuring period duration can be configured to 1, 5, 10, 15, 30 or 60 minutes. With a measuring period of ≤ 30 min, the duration of the partial measuring period is 1 min. With a measuring period of 30 to 60 min, the duration of the partial measuring periods is 5 min. The beginning of a measuring period is activated by an: Internal switching signal: Tariff switching clock Ripple control receiver, or External switching signal at one of the auxiliary terminals: At the control input S0 At a control input (system voltage) configured for this purpose The following example shows the calculating of sliding measuring periods by means of 3 partial measuring periods. 58 Figure 33: Formation of the maximum demand with a sliding measuring period The values from the sliding measuring period result from the sum of the last 3 entries from the circular memory. Measuring period 1: (0+0+0) = 0 kW Measuring period 2: (0.57+0+0) = 0.57 kW Measuring period 3: (0.72+0.57+0) = 1.29 kW Measuring period 4: (0.56+0.72+0.57) = 1.85 kW Measuring period 5: (0.83+0.56+0.72) = 2.11 kW Measuring period 6: (0.65+0.83+0.56) = 2.04 kW Measuring period 7: (1.03+0.65+0.83) = 2.51 kW Measuring period 8: (1.18+1.03+0.65) = 2.86 kW Measuring period 9: (0.85+1.18+1.03) = 3.06 kW (1. valid value) (1. valid value) (1. valid value) (1. valid value) (1. valid value) (1. valid value) 59 4.1.1.2 De-coupling time te In order to control other devices (e.g. a maximum demand monitor), a so-called decoupling signal te can be generated at an output (aux. terminal) or the optical fibre interface. Part 4 of VDE 0418 regulation stipulates that the de-coupling time may not exceed the higher of the following: 1% of the measuring period or 15 seconds. This de-coupling time is part of the measuring period and is generated at the beginning. In Europe, the measuring period most commonly used is 15 minutes (= 900 s), therefore the de-coupling time is 9 seconds. Electronic maximum demand meters need practically no de-coupling time. The de-coupling time te is distinguished by the speed of the software running time and rapid switching in the semiconductor elements which lies at a maximum in the millisecond range. Although the de-coupling signal is output externally with 1% of the measuring period, with electronic maximum demand meters there is a continual measuring process during this period. 4.1.1.3 Reset (cumulation) A reset has the following effect: Termination of the running measuring period Saving of the current maximum demand in the corresponding pre-value memory Cumulation of the current maximum demand in the cumulation register Reset of the maximum demand register to zero Reset of the current average power value to zero Saving of the energy values accrued until the time of the reset in the relevant prevalue memory Activation of a reset inhibition Incrementing of the reset register 0.1.0 Registration of the reset time in the appropriate pre-value memory A reset can be activated by one of the following: - Reset button - The internal tariff switching clock - The internal ripple control receiver An external control input - By a command via the optical data interface D0 By a command via the electrical data interface After a reset, depending on the selected reset channel, a temporal lock is activated. During this lock-out time no further resets can be carried out. The lock-out time is at least the duration of a measuring period and at the most 40 days. With each reset the block time is activated once again. Three block times with different durations can be set. 60 Inhibition times for a renewed reset via 1 2 3 4 5 activation of a reset by ... 1 ... Optical sensor or mechanical button t2 t3 t3 t3 t3 2 ... Interfaces (optical, electrical) t3 t2 t3 t3 t3 3 ... Terminals (Terminal block) t3 t3 t2 t2 t2 4 ... Internal ripple control receiver (RCR) t3 t3 t2 t3 t2 5 ... Internal real time clock or internal period counter t1 t1 t2 t2 t2 Table 18: Inhibition times for a renewed reset (Examples) The reset inhibitions are cancelled by a three-phase voltage interruption. With every reset, the respective time information (timestamp) is saved. The reset counter runs from 0...99 and, at the same time serves as a index for the pre-values. Set reset inhibition times Open “Configuration“ > “COMBI-TOOL“ > “Meter“ > “Reset inhibition“ Further information can be found in the user manual EMH-COMBI-MASTER 2000. 61 4.1.1.4 Load profile 4.1.1.4.1 General Fundamentally two independent load profiles can be created from the LZQJ-XC. P.01 Standard load profile According to VDEW-Specifications 2.1 P.02 User load profile Recording of the measured values for the network analysis according to EN 50160 standards 4.1.1.4.2 Standard load profile P.01 a. b. Measuring types There are principally three ways of measuring the individual load profile channels. Average value, OBIS value group D = 5 The calculation of the average value takes place analog to the maximum formation (see 4.1.1.1 Maximum) which means that the average value of every registration period arises from the time integral during the run period divided by the registration period duration. Energy, OBIS value group D = 8 At the end of each registration period the current values from the energy registers are saved. Energy feed, OBIS value groups D = 29 At the end of each registration period the differences between the current values from the energy registers and from the starting point of the registration period are saved.. Example of a load profile with a regsitration period length of 15 min /EMH4\@01LZQJC0012B P.01(0060323125020)(00000000)(15)(3)(1.5)(kW)(1.8)(kWh)(1.29)(kWh) (1.000)(00100.000)(0.2500) (1.000)(00100.250)(0.2500) (1.000)(00100.500)(0.2500) (1.000)(00100.750)(0.2500) (1.000)(00101.000)(0.2500) The load profile consists of header lines [P.01()] and value lines. The headers consist of a time stamp, status information and channel information on the readout values. The time stamp relates to the value lines and each marks the end of this period. The output format corresponds to the definition in the VDEW-Specifications 2.1. c. Memory depths Assuming there are 2 headers per day, tm = 15 min, the format is x.xxx kW and there is an exclusive configuration of the standard load profile, the following maximum memory depths would be the result. With simultaneous configuration of the user load profile P.02 the memory depths decrease. Number of channels Days with tm = 15 min 1 1698 2 1043 4 588 6 409 Table 19: Memory depths 62 The number of channels can be configured between 1 and 6 (as an option up to 32) and a measured variable can be freely assigned to each channel. The load profile always runs clock synchronised. The restart of a registration period (with t m = 15 min) takes place every ¼ h (time from the meters real time clock), which means at hh:00, hh:15, hh:30 and hh:45 o’clock. In the event of a voltage failure the current time is saved in the data protection memory. After power return, two methods are differentiated between: a) Power return within the current registration period: No new registration period is formed, the current registration period continues. Power return outside the current registration period: A new registration period is formed. b) With each power return a new registration period is formed The load profile can be represented in the display. The load profile can be certified and used for billing purposes. The load profile depth for output via data interfaces can be configured and integrated in up to four readout tables so that the volume of data can be selected to fit various requirements. Furthermore there is the possibility to read out targeted periods of the load profile. Figure 34: Diagram of standard load profile Read out standard load profile P.01 Open “Readout“ > “P.01 Standard LP...“ Further information can be found in the user manual EMH-COMBI-MASTER 2000. 63 5 Display- and readout lists 5.1 Display lists The display lists are shown in the meters display. The display is operated via the call-up and reset button. As an alternative to the call-up button, the optical call-up sensor can be used. Call-up sensor A R Call-up button Reset button Figure 35: Operation of the display The following belong to the display lists: Operation display (scrolling list) Test mode display Call-up list (“Std-dAtA” Display of all register contents in the list) Load profile list (“P.01” Display of load profile values) Certification relevant log book (“P.99” Display of changes to the output impulse constants and the LED-impulse constants) Set list (“SEt” Editing of settable variables) Info list (“InFO-dAtA” Display of instantaneous values) Test list (“tESt” High resolution mode for test purposes) The display lists can be configured at any time with the software EMH-COMBI-MASTER 2000. The call-up list is however the exception and, according to PTB regulations, may not be changed after calibration. Configuration of display lists Open “Configuration“ > “COMBI-TOOL“ > “Lists“ > “Display lists“ Further information can be found in the user manual EMH-COMBI-MASTER 2000. 64 5.2 Call-up of the display lists / control of the display 5.2.1 Brief instructions on the operation of display Operation display t<2s Test mode display t<2s Menu “Call-up button“ Call-up list (“Std-dAtA”) 2s<t<5s t<2s Load profile list (“P.01”) 2s<t<5s t<2s Set list (“Set”) 2s<t<5s Info list (“InFO-dAtA”) 2s<t<5s t<2s 2s<t<5s t<2s End (“End”) Menu “Reset button” t<2s t<2s Cert. rel. log book (“P.99”) t<2s Test list (“tESt”) 2s<t<5s t<2s 2s<t<5s End (“End”) 2s<t<5s t<2s 65 5.2.2 Operation display (scrolling list) The operation display is the standard display. Here the data is displayed in 10 s intervals (scrolling). Operation display Menu option 1 Display Button Operation display (scrolling) To the display test t<2s Table 20: Operation display 5.2.3 Display test In the test mode display, all segments of the display are activated and flash periodically. From the test mode display you can switch to the menu “Call-up button” or “Reset button”. It is possible to reach the menu “Call-up button” by pressing the call-up button < 2 s and the menu “Reset button” by pressing the reset button < 2 s. Test mode display Menu option 1 Display Button Test mode display (Display flashes) To the menu “Call-up button” t<2s To the menu “Reset button” t<2s Table 21: Test mode display 66 5.2.4 Menu “Call-up button“ The first displayed data in the menu “Call-up button” is the standard data. Every further operation of the call-up button leads to the display of further menu options e.g. to the load profile “P.01”. To select the menu option, the call-up button is pressed for at least 2 s. The end of the menu is represented with “End”. If the time limit of two measuring- or registering periods (in general 30 min) is reached after the last operation of the button the display automatically switches back to the operation display. This can also be achieved by pressing the call-up button for > 5 s. Menu “Call-up button” Menu option 1 Display Button Activation of the call-up list To the next menu option t<2s Entry into the call-up list 2s<t<5s 2 Activation of the load profile list To the next menu option t<2s Entry into the load profile list 2s<t<5s 3 Activation of the certification relevant log book (optional) To the next menu option t<2s Entry into the certification relevant log book 2s<t<5s 4 End of the display menu Return to pos. 1 t<2s Table 22: Menu “Call-up button” 67 5.2.5 Call-up list (menu option “Std-dAtA”) The call-up list contains billing relevant data. Every operation of the call-up button leads to the display of further data. To allow a faster display of data, pre-values can be skipped. This is achieved by pressing the call-up button longer than 2 s. The end of the menu is represented with “End”. If the time limit of two measuring periods (in general 30 min) is reached after the last operation of the button, the display automatically switches back to the operation display. This can also be achieved by pressing the call-up button for > 5 s. By means of this it is guaranteed that at least the procedure of a complete measuring period can be observed on the display. Call-up list Menu option 1 Display Button Entry into the call-up list Activation of the call-up list 2s<t<5s 2 First register To the next menu option t<2s 3 Next register To the next menu option t<2s 4 Pre-value To the next menu option t<2s 5 Repeat positions 3 and 4 for the display of further registers/values 6 End of the call-up list Return to pos. 2 t<2s To the operation display t>5s Table 23: Call-up list 68 5.2.6 Load profile list, standard LP (menu option “P.01”) The first value displayed in the load profile list is the date of the last recorded load profile. Every further operation of the call-up button < 2 s leads to the display of the previous date. By operating the call-up button > 2 s, the last load profile entry on the selected date is shown. Every further operation of the call-up button < 2 s switches the display to the next value in the selected registration period. After the last value, the date of the second to last registration period etc is displayed. The end of the menu is represented with “End”. If the time limit of two measuring- or registering periods (in general 30 min) is reached after the last operation of the button the display automatically switches back to the operation display. This can also be achieved by pressing the call-up button for > 5 s. By means of this it is guaranteed that at least the procedure of a complete measuring period can be observed on the display. Load profile list (Standard LP) Menu option 1 Display Button Entry in the load profile list Activation of the load profile list 2s<t<5s 2 Last date To the next menu option t<2s 3 Date of the previous day To the next menu option 2s<t<5s 4 Time of the last entry of the selected day To the next menu option t<2s 5 Status entry of the last entry To the next menu option t<2s 6 First load profile value of the last entry To the next menu option t<2s 7 Second load profile value of the last entry To the next menu option t<2s 8 Time of the penultimate entry of the selected day To the next menu option t<2s 9 End of the load profile list Return to pos. 4 t<2s To the operation display t>5s Table 24: Load profile list 69 5.2.7 Certification relevant log book (menu option “P.99”) The certification relevant log book is used for recording changes to the LED constant(s) and to the input- and output constants. The first displayed data of the certification relevant log book is the date of the entry. Every further operation of the call-up button leads to the display of further data in the following sequence: Date Time Status entry (when all entries deleted: 00002000 (delivery condition)) OBIS code of the displayed value o 0.3.0 Change of the LED constants o 0.3.3 Output impulse constants for active energy o 0.3.4 Output impulse constants for reactive energy o 1-B:0.7.0/1 Input impulse constants for active- and reactive energy Old value New value If there are other log book entries in the certification relevant log book these are displayed with every further operation of the call-up button < 2 s. The end of the menu is represented with “End”. If the time limit of two measuring- or registering periods (in general 30 min) is reached after the last operation of the button the display automatically switches back to the operation display. This can also be achieved by pressing the call-up button for > 5 s. By means of this it is guaranteed that at least the procedure of a complete measuring period can be observed on the display. Certification relevant log book Menu option 1 Display Button Activation of the certification relevant log book 2s<t<5s 2 Date of the last entry Entry into the certification relevant log book To the next menu option t<2s 3 Time of the last entry To the next menu option t<2s 4 Status entry To the next menu option t<2s 5 OBIS code To the next menu option t<2s 6 Old value To the next menu option t<2s 7 New value To the next menu option t<2s 70 8 9 Repeat position 2 to 7 for the display of further registers/values End of the certification relevant log book Return to pos. 2 t<2s To the operation display t>5s Table 25: Certification relevant log book In the certification relevant log book 40 entries can be saved. Further changes to the pulse constants are only possible when the oldest entry is internally marked as overwriteable. This is the case when: the time stamp of the oldest entry is more recent than the time stamp of the oldest pre-value the time stamp of the oldest entry is younger than the current operation time deducting the parameterised value in register 5BD. This value is higher than the operation time of a complete load profile. 71 5.2.8 Menu “Reset button” In order to operate the reset button the module cover seal must be broken. This may only be carried out by authorised personnel! The first value in the menu “Reset button” is the menu option SEt (set list). An operation of the call-up button < 2 s leads to the display of further menu options, e.g. info- or test list. To select the menu options, the call-up must be pressed for at least 2 s. The end of the menu is represented with “End”. If the time limit of two measuring- or registering periods (in general 30 min) is reached after the last operation of the button the display automatically switches back to the operation display. This is also achieved by pressing the call-up button > 5 s. Menu “Reset button” Menu option 1 Display Button Operation display (Scrolling) To the next menu option t<2s 2 Test mode display To the menu “Call-up button” t<2s To the menu “Reset button” t<2s 3 Activation of the set mode To the next menu option t<2s Entry into the set list 2s<t<5s 4 Activation of the info list To the next menu option t<2s Entry into the info list 2s<t<5s 5 Activation of the test mode To the next menu option t<2s Entry into the test list 2s<t<5s 6 End of the display mode Return to pos. 3 t<2s Table 26: Menu “Reset button” 72 5.2.9 Set list (Menu option “Set”) In the set list, settable values can be changed via the call-up button and/or the reset button. Values with several digits which can be changed via the edit button are edited starting at the left (first) digit. Important information for setting the date and time: When setting the clock you must first set the date and then the time. Otherwise the clock may be incorrectly set forward or back by 1 hour during the transition from summer to winter time (and vice versa) as seasonal adjustment is carried out later by the meter. Set list Menu option 1 Display Button Entry into the set list Activation of the set list 2s<t<5 2 First set value To the next menu option t<2s 3 Next set value Edit first value t<2s 4 Increment digit by 1 Edit first digit (digit flashes) t<2s Next digits flash t<2s 5 Increment digit by 1 To the next menu option t<2s 6 Repeat positions 4 to 5 for further digits 7 All digits flash Keep the old value t<2s Save new value t<2s 8 End of the set list Return to pos. 2 t<2s To the operation display t>5s Table 27: Set list 73 5.2.10 Info list (Menu option “InFO-dAtA”) The info list contains instantaneous values which are used during the start-up procedure. Every operation of the call-up button leads to the display of further data. To allow a faster display of data, pre-values can be skipped. This is achieved by pressing the call-up button longer than 2 s. The end of the menu is represented with “End”. If the time limit of two measuring- or registering periods (in general 30 min) is reached after the last operation of the button the display automatically switches back to the operation display. This is also achieved by pressing the call-up button > 5 s. By means of this it is guaranteed that at least a complete measuring period can be observed on the display. Info list Menu option 1 Display Button Activation of the info list Entry into the info list 2s<t<5 2 First register To the next menu option t<2s 3 Next register To the next menu option t<2s 5 Repeat positions 3 for the display of further registers 6 End of the info list Return to pos. 2 t<2s To operation display t>5s Table 28: Info list 74 5.2.11 Test list (Menu option “tESt”) The test list is used for testing the meter. It contains the same data as in the operation display, however, the data does not scroll and also the energy register(s) is displayed in high resolution. The LED flashes in each shown energy mode. Every operation of the call-up button leads to the display of further data. If the call-up button is activated for at least 5 seconds, the display automatically switches over into the operation display. The test mode is exited when the initialisation telegram (see for this ZVEI-recommendation “Testing of electronic meters via the data interface”) is sent together with the measuring period default (see parameter d) “0” via the data interfaces or when a time period of 24 hours elapses since activation of the mode. Test list Menu option 1 Display Button Entry into the test list Activation of the test list 2s<t<5 2 To the next menu option First register t<2s 3 To the next menu option Next register t<2s 4 Repeat pos. 3 for the display of further registers/values For return to the operation display Press t > 5 s. Table 29: Test list 75 5.3 Readout lists Readout lists offer the possibility (depending on configuration and access authorisation) to read out measuring variables, momentary values and events via the meters interfaces. Available lists Configurable Table 1 (billing data) Table 2 (load profile data of the last 40 days) Table 3 (test data) Service table (instantaneous values) Standard load profile P.01 User load profile P.02 Operation log book P.98 Certification relevant log book P.99 User log book P.200 Event log book P.210 Event log book P.211 Data readout Open “Readout > ...” Configuration of readout lists Open “Configuration” > “COMBI-TOOL” > “Lists” > “Readout lists” Further information and notes on reading out meter data can be found in the appendix on page 105 and in the user manual EMH-COMBI-MASTER 2000. 76 6 Special features 6.1 Manipulation recognition For registering manipulation attempts, the LZQJ-XC can be equipped with a manipulation recognition system which registers manipulation when the housing cover and terminal cover are removed or when there is magnetic interference. 6.1.1 Principle functions On the main board there are 2 micro buttons. The meter cover and terminal cover both have a pin on the inner side. Each time the meter cover or the terminal cover is removed, a manipulation attempt is registered by the respective micro button. By equipping the LZQJ-XC with a buffer battery the removal of the housing cover or terminal cover is also registered when the meter is switched off. 6.1.2 Output possibilities There are 4 possibilities to show a manipulation attempt. 1) 2) 3) 4) Cursor in the display Registration entry Activation of an alarm contact Log book entry Figure 36: Output of manipulations 6.1.2.1 Cursor in the display When a manipulation attempt is registered a cursor appears at the top right in the display next to “MAN”. How to reset a manipulation can be freely configured. 77 6.1.2.2 Register entry Manipulation attempts are shown by the first digit of the installation check register C.86. The digit “1” indicates manipulation of the meter cover: The digit “2” indicates a manipulation of the terminal cover: The digit “4” indicates manipulation from magnetic fields: There are many different possibilities for resetting the registration entry. 6.1.2.3 Activation of an alarm contact A manipulation message can be sent to the control centre via an alarm contact and a meter modem. A manipulation message can also be sent as an Short Message (SMS). 6.1.2.4 Log book entry 6.1.2.4.1 User log book P.200 Every manipulation attempt is registered in the user defined log book P.200. This data can also be read out via the service table TS. The beginning and end of the last manipulation is registered and saved with information on the time and date and also the number of manipulation attempts (provided meter is in the operation condition). Examples: P.200(0060120085945)(00002000)()(0) Status: Log book deleted P.200(0060120114119)(00000008)()(0) Status: Manipulation Terminal cover P.200(0060120114136)(00000108)()(0) Status: Unauthorised read access, manipulation of the terminal cover P.200(0060120114527)(00000108)()(0) Status: Unauthorised read access, manipulation of the terminal cover 78 6.1.2.4.2 Event log book P.210 In the event log book P.210 every manipulation attempt is saved with a time stamp (start and end). Every manipiulation is marked accordingly with an event code. Examples: P.210(0061124075651)(2000)()(0) P.210(0061124075938)(3307)()(0) Event 3307: PAR-status deactivated P.210(0061124080040)(339A)()(0) Event 339A: Housing cover has been closed P.210(0061124080047)(339B)()(0) Event 339B: Terminal cover has been closed Furhter events are for example: 23AC 33AC 239B 339B Start manipulation terminal cover End manipulation terminal cover Terminal cover contact has been opened Terminal cover contact has been closed 23AD 33AD 239A 339A Start manipulation housing cover End manipulation housing cover Housing cover contact has been opened Housing cover contact has been closed 23A8 33A8 239C 339C Start manipulation magnetic field End manipulation magnetic field Magnetic field sensor is activated Magnetic field sensor in neutral position again 2307 3307 PAR-status activated PAR-status activated 79 6.2 Overload monitoring The LZQJ-XC can be equipped with an overload monitoring feature which detects when the configured overload threshold is exceeded during a measuring period. Values from 0 to 99.999.999 kW are permitted. Setting the overload threshold Open “Direct” > “LZQJ-settings (VDEW2.1)...” > “Overload threshold” First of all read out the overload threshold set in the meter. Afterwards you can change the values and write them back into the meter. Further information can be found in the user manual EMH-COMBI-MASTER 2000. The sum of all overranges are saved in the register 1.36.0.01. The maximum demand register M0 for current consumption P+ 1.4.0 or the register 1.25 for the momentary value for P+ is used as a basis for recognising overconsumption. When the overconsumption threshold is exceeded a cursor (PWR) is shown in the display. An alarm contact can also be switched. Information on the overconsumption threshold can be found in the call-up list and in table 1. Figure 37: Diagram - Overconsumption 80 6.3 Installation check register C.86.0 In the installation check register C.86.0 installation errors are saved. The monitored measured variables result from the instantaneous values. The installation check register is usually shown in the scrolling list or can be called up via the call-up list. The installation check register has 32 error flags which are represented by an 8 digit hexidecimal number. With a correct installation of the meter, the register contains the value “00000000”. C.86.0 (0 0 0 0 0 0 0 0) Manipulation recognition Wrong phase sequence Free Negative energy direction Current interruption Max. current exceeded Undervoltage Overvoltage Event Manipulation recognition Wrong phase sequence Negative energy direction Current interruption Maximum current exceeded (I > Imax) Undervoltage (U < 80%) Overvoltage (U > 115%) Value Meaning 1* Manipulation of the meter cover 2* Manipulation of the terminal cover 4* Manipulation from magnetic fields 2 Wrong phase sequence 4* Asymmetric current, e.g. 30% 8 Asymmetric voltage, e.g. 18% 1 Negative energy direction L1 (P) 2 Negative energy direction L2 (P) 4 Negative energy direction L3 (P) 1* Current interruption L1 2* Current interruption L2 4* Current interruption L3 1 Maximum current exceeded L1 2 Maximum current exceeded L2 4 Maximum current exceeded L3 1 Undervoltage L1 2 Undervoltage L2 4 Undervoltage L3 1 Overvoltage L1 2 Overvoltage L2 4 Overvoltage L3 * optional, if configured 81 6.4 Network analysis 6.4.1 User load profile P.02 The user load profile P.02 registers and saves measured variables from the network quality following the EN 50160 standards. With regards to the measured variables and registration period duration (normally 10 min) the user load profile is completely independent of the standard load profile P.01. a. Measuring variables The following measuring variables are recorded: Average system voltage Uaverage (L1, L2, L3) Minimum system voltage Umin (L1, L2, L3) Maximum system voltage Umax (L1, L2, L3) Average phase currents Iaverage (L1, L2, L3) Maximum phase currents Imax (L1, L2, L3) Total Harmonic Distortion U THDU (L1, L2, L3) 1 Total Harmonic Distortion I THDI (L1, L2, L3) Flicker intensity Pst (L1, L2, L3) Network frequency f 1 Optionally in the user load profile other measured variables can also be recorded. Figure 38: Diagram of additional load profile b. Memory depths With the previous example and an exclusive configuration of the user load profile, the profile P.02 has the following maximum memory depth. With a simultaneous configuration of the standard load profile P.01 the memory depth decreases. Number of channels Days with tm = 10 min 32 54 Table 30: Memory depths The functions of the user load profile correspond to that of the standard load profile. The period length and the behaviour with voltage interruptions can be set separately for both load profiles. Unlike the standard load profile, the user load profile is not shown on the display. 1 not available with 60 Hz 82 Read out user load profiles P.02 Open “Readout” > “P.02 User-LP... ” Further information can be found in the user manual EMH-COMBI-MASTER 2000. 83 6.4.2 Voltage quality register C.86.1 In the voltage quality register C.86.1 the over- and underranges of the voltage parameters are saved. The register can also be used as a status channel in the user load profile P.02. The limiting values are defined in DIN EN 50160, they can also be configured to suit customer requirements. From the monitored values the average values are formed via the registration period of the user load profile P.02. At the end of a registration period the values are compared with the guidelines and if necessary saved in the appropriate registers. The voltage quality register has 32 error flags which are represented by means of an 8 digit hexadecimal number. The sum of all over- and underranges are saved in the registers C.88.00...31. C.86.1 (0 0 0 0 0 0 0 0) Free Free THD Voltage Flicker intensity Voltage L3 Voltage L2 Voltage L1 Network frequency Event THD Voltage Flicker intensity Voltage L3 Voltage L2 Voltage L1 Network frequency 84 Value 1 2 4 1 2 4 1 2 4 8 1 2 4 8 1 2 4 8 1 2 4 8 Meaning THDU, L1 > THDU, max THDU, L2 > THDU, max THDU, L3 > THDU, max Flicker Pst, L1 > Flicker Pst, max Flicker Pst, L2 > Flicker Pst, max Flicker Pst, L3 > Flicker Pst, max Voltage L3 < Umin1 Voltage L3 > Umax1 Voltage L3 < Umin2 Voltage L3 > Umax2 Voltage L2 < Umin1 Voltage L2 > Umax1 Voltage L2 < Umin2 Voltage L2 > Umax2 Voltage L1 < Umin1 Voltage L1 > Umax1 Voltage L1 < Umin2 Voltage L1 > Umax2 Network frequency f < fmin1 Network frequency f > fmax1 Network frequency f < fmin2 Network frequency f > fmax2 6.5 Consumption check register C.86.2 In the consumption check register C.86.2 the overranges of current parameters are saved. The register can also be used as a status channel in the user load profile P.02. From the monitored values the average values are formed via the registration period of the user load profile P.02. At the end of a registration period the values are compared with the guidelines and if necessary saved in the appropriate registers. The voltage consumption check has 32 error flags which are represented by means of an 8 digit hexadecimal number. The sum of all overranges are saved in the registers C.88.32...63. (0 0 0 0 0 0 0 0) C.86.2 Free Maximum current exceeded Event Value Meaning 1 IL1 > Imax 2 IL2 > Imax 4 IL3 > Imax Maximum current exceeded 6.6 Log boks 6.6.1 User log book P.200 In the user log book P.200 the following events are saved. Phase failure L1, L2, L3 Manipulation of the terminal cover Manipulation of the housing cover Negative rotary field Tariff switching times Unpermitted read access Unpermitted write access Deleting of the log book Current asymmetry Voltage asymmetry It is also possible to customise the configuration of the P.200 log book. In total up to 204 events can be saved. 6.6.2 Event log book P.210 In the event log book P.210 the following events are saved. Manipulation of the terminal cover Manipulation of the housing cover Manipulation from a magnetic interference field PAR-Status active It is possible to customise the configuration of the P.210 log book. Up to 32 different registers can be defined and up to 6 registers can be added to each event entry. Depending on the number of registers a maximum of 282 entries can be saved. 85 6.6.3 Event log book P.211 In the event log book P.211 the following events are saved. Events in the voltage quality register C.86.1 Phase failure L1, L2, L3 It is possible to customise the configuration of the P.211 log book. Up to 32 different events can be defined and up to 6 registers can be added to each event entry. Depending on the number of registers, a maximum of 282 entries can be saved. 6.7 Load switching As an option, the LZQJ-XC can be executed with a switching off relay for switching the load/power. By means of this, the power supply can be switched on or off at the final user. There are different cases of application which are described in the following. 6.7.1 Example cases 6.7.1.1 Example case 1 The customer (eg. holiday home owner) swiches the power supply off at the meter on site using the call-up button. Switching back on also takes place via the call-up button. 6.7.1.2 Example case 2 In spite of many warnings the customer has not paid their electricity bill. The energy supplier switches off the power supply to the customer via remote control. After payment of the bill the power supply is switched back on. The power supplier also reactivates the meter via remote control. Subsequently the customer can activate the power supply by operating the call up button. 6.7.1.3 Example case 3 The customer has agreed a limited power supply with the energy supplier (e.g. P max = 10 kW). If this power threshold is continually exceeded, the meter switches off the load. Depending on the configuration there are different possibilities to switch it back on: via a direct command from the energy supplier via a release command from the energy supplier for the customer to switch it on manually via the call-up button by the customer 6.7.1.4 Example case 4 The customer has agreed a limited power supply with the energy supplier (e.g. P max = 10 kW). If this power threshold is continually exceeded, the meter switches off the load. The customer has no access to the meter which means that he cannot switch it on again directly. In this case the meter swiches on the load again automatically after the disconnection time has lapsed. 86 6.7.2 Load switching 6.7.2.1 Load switching via the call-up button Operation display Via the menu option “LOAd OnIOFF” in the menu “Call-up button” the switching of the load can be carried out directly on the meter. By operating the call-up button 2 s < t < 5 s the submenu option “LOAd OFF” or “LOAd On” appears independent of the relay position. “LOAd OFF”: By operating the call-up button > 2 s the load is switched off. The display returns to the operation display. With a successful switching off, the display “OFF” appears. If the switching process failed, “LOAd Error” appears. The meter can still be operated. t<2s Display test t<2s Menu „Call-up button“ Call-up list (“Std-dAtA”) 2s<t<5 s “LOAd On”: By operating the call-up button > 2 s the load is switched back on. The display returns to the operation display. t<2s Load profile list (“P.01”) 2s<t<5 s t<2s Cert.rel. log book (“P.99”) 2s<t<5 s t<2s Load switching (“LOAd OnIOFF”) 2s<t<5s t<2s End (“End”) 2s<t<5 s t<2s Switch on - Menu Switch on no t>2s Relay closed? yes Switch off - Menu Switch off t>2s yes t<2s t<2s No-load condition fulfilled? no Operation display “Scrolling list” Operation display “OFF” t<2s End (“End”) Operation display “LOAd Error” t>5s Figure 39: Load switching via the call-up button 87 6.7.2.2 Load switching via commands Switching on and off the load using a command takes place via the meters interfaces (D0, CL0, RS232, RS485, radio). 6.7.2.3 Manual load switching Release for the manual switching on of the load takes place via the meters interfaces (D0, CL0, RS232, RS485, radio). Release can be identified via the display “PrESS:On” . The meter can no longer be operated in this condition. By operating the call-up button > 5 s the load is switched back on again. Afterwards the meter can be operated again as normal. 6.7.2.4 Load switching by means of excess load 6.7.2.4.1 Switching off by means of excess load When a fixed power threshold is exceeded the load us switched off. This threshold can be set and saved in the register 1.35.0.01(). In the regiser 1.35.0.02() a “forewarning threshold” can be saved. When one of the thresholds is reached, this is signalised in the display by the sideward cursor “PWR”. If no thresholds are configured, no power monitoring takes place. Threshold monitoring takes place by means of the power instantaneous value 1.25. Switching off takes place after a fixed lag time as long as the power is exceeded for the whole of the lag time. If the switching off is successful, “OFF” appears in the display. The meter can still be operated. The power thresholds and the lag time can be set via the meters interfaces (D0, CL0, RS232, RS485, radio). 6.7.2.4.2 Automatic switching on If the load is switched off due to power monitoring, this is switched back on again after a fixed diconnection time. If no disconnection time is configured, the load is not switched back on automatically. The disconection time can be set via the meters interfaces (D0, CL0, RS232, RS485, radio). 6.7.3 Monitoring the switch off condition If the load is switched off, the meter checks its idle condition. If this is not given after the switching off, the meter repeats its power down process cyclically. When the idle condition is fulfilled, “OFF” appears in the display. If the switching off fails, “LOAd Error” appears in the display. Additionally an entry appears in the status register for load switching C.86.8(). At the same time, a time meter is activated which records the hours in which the load was connected. The time meter can only be reset by deleting the measured data. Even if the switching off fails, the meter can still be operated and commands can be received. Note: A continuous base load above the meters response threshold is a requirement for the monitoring function. 88 6.8 Recording external measuring variables The LZQJ-XC is capable of registering other impulses from reference-, thermal-, wateror gas meters via 4 impulse inputs. From these inputs, energy values, maximum demand and load profiles can be formed. These measuring variables can then be read out via the LZQJ-XC meter. Figure 40: Application plan - recording load profiles form other media Figure 41: Diagram - Recording of load profiles from several meters Pulse counting In order to avoid incorrect registration of pulses, the minimum pulse length and no-pulse period can be set in 5ms steps. Furthermore the activating edge (rising or falling) can be selected. A registered pulse is evaluated by means of a settable pulse constant and a unit.The quantums which are formed in this way can either be summed among eachother or added to or subtracted from the measuring variables formed internally in the meter. When an input pulse constant is changed, an entry is made in the certification relevant log book P.99 (see 5.2.7 Certification relevant log book (menu option “P.99”)). All measuring variables resulting from this are available as an input channel for the energy- and maximum demand registers and for the load profile formation. 89 Example: Via the pulse input with the channel number 2, active power proportional pulses are counted. These are then added to the variables formed in the meter and registered in separate meter registers with the channel number 13 (see also 8.1 OBIS (ObjectIdentification-System)). 90 OBIS code Medium Channel Measuring variable Measurement type Tariff 1-2:1.8.1 Electricity Pulse input 2 Active power Energy 1 1-2:1.8.2 Electricity Pulse input 2 Active power Energy 2 1-2:1.6.1 Electricity Pulse input 2 Active power Power maximum demand 1 1-2:1.6.2 Electricity Pulse input 2 Active power Power maximum demand 2 1-13:1.8.1 Electricity Sum of measuring variables formed internally in the meter and variables formed via pulse input 2 Active power Energy 1 1-13:1.8.2 Electricity Sum of measuring variables formed internally in the meter and variables formed via pulse input 2 Active power Energy 2 1-13:1.6.1 Electricity Sum of measuring variables formed internally in the meter and variables formed via pulse input 2 Active power Power Maximum demand 1 1-13:1.6.2 Electricity Sum of measuring variables formed internally in the meter and variables formed via pulse input 2 Active power Power Maximum demand 2 7 Certification relevant tests The PTB Regulations, volume 6 for electricity meters and additional equipment apply. 7.1 Certification- and test mode Switching of the LED to the energy type which is to be measured takes place: 1) Directly at the meter Entry into the test mode “tESt” Readout of the table with a higher resolution 2) Via optical interface Call-up the certification- and test mode takes place with the program EMHCOMBI-MASTER 2000 Readout of the table with a higher resolution In the meter a register of the energy type to be tested can be called up on the display, e.g.: Active import Active export Reactive import Reactive export 1.8.1 2.8.1 3.8.1 4.8.1 Shortened no-load test LED is continuously lit-up no load, energy direction arrows are not displayed Shortened start-up test The LED starts to flash. The energy direction arrows display the measured energy direction. 7.2 Test load Test loads for testing meters which have several nominal voltages (long-range) or 1 a nominal voltage range This test is to be carried out at the upper and lower voltage rate which is specified on the nameplate, provided no other conditions are specified in the approval. Test loads for testing meters which have two nominal currents 1 With the test of meters with two nominal currents (e.g. 5||1 A) the lowest test point (5% or 10%) is measured with the smaller nominal current. All other test points are measured using the higher nominal current. Testing of meters with two energy directions 1 As long as no other regulations are specified in the approval documents meters which measure energy in both directions are measured in a way as if two separate meters for import and export are being dealt with. 1 Extract from the PTB Regulations, volume 6 for electricity meters and additional equipment. 91 8 Appendix 8.1 OBIS (Object-Identification-System) The Object-Identification-System OBIS is described in IEC 62056-61 and is used for identification of measured values, e.g. electricity, water, gas and heat. The OBIS-code system is divided into the value groups A to F. Value range F: Pre-values Value range E: Tariff Value range D: Measuring type Value range C: Type of measuring variable Value range B: Channel number Value range A: Medium In the following table the codes commonly used with EMH electricity meters are described. A 92 B 1- x. 11111111[A] [A] [A] [A] [A] [A] 1: 2: 3: 4: 5: 6: 7: 8: [B] [B] [B] [B] [B] [B] C 0. 0. 0. 0. 0 0. 0. 0. 0. 0. 0. 0. 0. 0. 0. 0. 0. 0. 0. 0. 0. 0. 0. 0. 0. 0. 0. 0. 0. 0. 0. 0. 0. C C C C C C C C 1. 2. 3. 4. 5. 6. D 0. 0. 0. 0. 0. 0. 0. 0. 0. 0. 1. 1. 1. 2. 2. 2. 2. 2. 2. 3. 3. 3. 3. 4. 4. 4. 7. 8. 8. 9. 9. 9. 9. D D D D D D D D D D D D D D E 0 1 2 3 4 5 6 7 8 9 0 1 2. 0 1. 1. 1. 2 3 0 1 3 4 1 2 3 y 0 4 1 2 3 5 E E E E E E E E E E E E E E F xx 01 02 50 [*F] [*F] [*F] [*F] [*F] [*F] [*F] [*F] [*F] [*F] [*F] [*F] [*F] [*F] Meaning Device address Identification number 1 Identification number 2 Identification number 3 Identification number 4 Identification number 5 Identification number 6 Identification number 7 Identification number 8 (customer address) Identification number 9 (utility address) Number of resets Number of available pre-values Pre-values reset time periods Configuration program version number Parameter number Parameter setting Set number Switching clock program number Ripple control program number LED constant active energy LED constant reactive energy Output constant active energy Output constant reactive energy Readout factor energy Transformer factor current Transformer factor voltage Channel x input pulse constants Measuring period lengths Registering period lengths Time Date Weekday and Week number Weekday Electricity/Channel 1 Electricity/Channel 2 Electricity/Channel 3 Electricity/Channel 4 Electricity/Channel 5 Electricity/Channel 6 Electricity/Channel 7 Electricity/Channel 8 Positive active power Negative active power Positive reactive power Negative reactive power Reactive power quadrant 1 Reactive power quadrant 2 A [A] [A] [A] [A] [A] [A] [A] [A] [A] [A] [A] [A] [A] [A] [A] [A] [A] [A] [A] B [B] [B] [B] [B] [B] [B] [B] [B] [B] [B] [B] [B] [B] [B] [B] [B] [B] [B] [B] C 7. 8. 9. 10. C C C C C C C C C C C C C C C 21. 41. 61. 22. 42. 62. 83. 83. 83. 83. D D D D D 2. 4. 5. 6. 8. 9. D D D D D D D D D 8. 8. 8. 8. 8. 8. 8. 8. 8. 8. E E E E E E E E E E E 0. 1. 2. 3. 4. 5. 6. 7. 8. 0 0 0 0 0 0 1 2 4 5 1. 10. x 196. 10. 0 31. 51. 71. 32. 52. 72. 1. 21. 41. 61. 3. 23. 43. 63. 9. 29. 49. 69. 13. 33. 53. 73. 14. 1. 1. 2. 2. 1. 1. 1. 1. 2. 2. 2. 2. 1. 3. C. C. C. C. C. C. C. C. C. C. C. C. 25 25 25 25 25 25 25 25 25 25 25 25 25 25 25 25 25 25 25 25 25 25 25 35. 35. 35. 35. 36. 36. 36. 36. 36. 36. 36. 36. 58. 58. 1. 2. 2. 2. 2. 3. 4. 5. 6. 6. 7. 7. 0. 0. 0. 0. 0. 90. 0. 90. 0. 90. 0. 90. [x] [x] 0 0 1 2 3 0 3. 0 1 F [*F] [*F] [*F] [*F] [*F] [*F] [*F] [*F] [*F] [*F] [*F] [*F] [*F] [*F] [*F] [*F] 01 02 01 02 01 01 02 02 01 01 02 02 01 Meaning Reactive power quadrant 3 Reactive power quadrant 4 Positive apparent power Negative apparent power Cumulative register Current average value Last average value Maximum demand Energy register (Energy) Energy feed Tariff 0 (24 h active) Tariff 1 Tariff 2 Tariff 3 Tariff 4 Tariff 5 Tariff 6 Tariff 7 Tariff 8 Positive active power phase 1 energy register tariff 0 Positive active power phase 2 energy register tariff 0 Positive active power phase 3 energy register tariff 0 Negative active power phase 1 energy register tariff 0 Negative active power phase 2 energy register tariff 0 Negative active power phase 3 energy register tariff 0 Copper losses + energy register, tariff 0 Copper losses - energy register, tariff 0 Iron losses + energy register tariff 0 Iron losses - energy register tariff 0 Positive power phase energy register tariff x (overload consumption: 1.25 > 1.35.0.0) Positive power phase energy register tariff 0 (overload consumption: 1.4.0 > 1.35.0.0) Instantaneous value current phase 1 Instantaneous value current phase 2 Instantaneous value current phase 3 Instantaneous value voltage phase 1 Instantaneous value voltage phase 2 Instantaneous value voltage phase 3 Instantaneous value active power total Instantaneous value active power phase 1 Instantaneous value active power phase 2 Instantaneous value active power phase 3 Instantaneous value reactive power total Instantaneous value reactive power phase 1 Instantaneous value reactive power phase 2 Instantaneous value reactive power phase 3 Instantaneous value apparent power total Instantaneous value apparent power phase 1 Instantaneous value apparent power phase 2 Instantaneous value apparent power phase 3 Instantaneous value power factor total Instantaneous value power factor phase 1 Instantaneous value power factor phase 2 Instantaneous value power factor phase 3 Instantaneous value line frequency Overload threshold 1 P+ Overload threshold 2 P+ Overload threshold 1 POverload threshold 2 PNumber of exceeds total threshold 1 P+ Number of exceeds since reset of threshold 1 P+ Number of exceeds total threshold 2 P+ Number of exceeds since reset of threshold 2 P+ Number of exceeds total threshold 1 PNumber of exceeds since reset of threshold 1 PNumber of exceeds total threshold 2 PNumber of exceeds since reset of threshold 2 PTest mode (x=0…8) Test mode (x=0…8) Manufacturing number Number of parameterisation Time of last parameterisation Time of last switching program change Time of the last ripple control program change In-/ output conditions Internal operational conditions Internal operational conditions Battery hours meter (x=0…8) Voltage clock battery Number of voltgae failures 3 phase Number of voltage failures L1 93 A 94 B C C. C. C. C. C. C. C. C. C. C. C. C. C. C. C. C. C. C. C. C. C. C. C. C. C. C. C. C. C. C. C. C. C. C. C. C. C. C. C. C. C. C. C. C. C. C. C. F. P. P. P. P. P. P. P. 81. 81. 81. 81. 81 81. 81. 81. 94. 96. 32. 52. 72. 32. 52. 72. 32. 52. 72. 31. 51. 71. 31. 51. 71. 140. 141. D 7. 7. 8. 50. 51. 51. 52. 52. 52. 54. 54. 54. 69. 69. 69. 69. 69. 69. 69. 75. 75. 75. 75. 80. 80. 80. 80. 80. 85. 86. 86. 86. 86. 86. 86. 86. 87. 87. 87. 88. 88. 88. 88. 90. 90. 90. 90. F 01 02 98 99 200 210 211 7. 7. 7. 7 7. 7. 7. 7. 49. 6. 5 5 5 23 23 23 26 26 26 5 5 5 26 26 26 5 5 E 2 3 x 0 4 9 0 7 8 0 7 8 0 1 2 3 4 5 7 0 1 2 3 0 1 2 3 4 0 0 1 2 5 6 7 8 0 1 2 x 96 97 98 0 1 2 3 00 10 20 21 02 40 51 62 2. 1 F 02 Meaning Number of voltage failures L2 Number of voltage failures L3 Operating hour counter tariff x Meter operating hours Time of last DCF synchronisation Time of last GPS synchronisation Phase information Event counter magnetic manipulation Time counter magnetic manipulation Ripple control receiver relay position Event counter negative active power Time counter negative active power Overconsumption threshold1, positive active power Overconsumption threshold 1, negative active power Overconsumption threshold 2, positive active power Overconsumption threshold 2, negative active power Equivalent resistance conduction losses Equivalent resistance transformer losses Threshold tan(phi) Access protection settings Access protection settings Access protection settings Access protection settings Load disconnection Release of load connection Load connection Debounce time for the load switching in s Timer for automaticac load reconnection in s Time counter for interfered load disconnection in h Installation check register Voltage check register Consumption register Radio status register Input status register Output status register Status register fort he load switching Bit mask installation check register Bit mask voltage check register Bit mask consumption register Event counter for the network quality (x=00…31) Monitoring time counter for the network quality Monitoring time counter for the network quality Time - start of the monitoring Check sum PAR Check sum SET Check sum ROM Check sum system Error register Load profile User load profile VDEW log book Certification relevant log book User log book Event log book Event log book Phase angle U1-U1 Phase angle U1-U2 Phase angle U1-U3 Phase angle U2-U3 Phase angle U3-U1 Phase angle U1-I1 Phase angle U2-I2 Phase angle U3-I3 Standard data record recognition (Info register) RTC-battery-charging condition (good/bad) Average value voltage phase 1 Average value voltage phase 2 Average value voltage phase 3 Minimum value voltage phase 1 Minimum value voltage phase 2 Minimum value voltage phase 3 Maximum value voltage phase 1 Maximum value voltage phase 2 Maximum value voltage phase 3 Average value current phase 1 Average value current phase 2 Average value current phase 3 Maximum value current phase 1 Maximum value current phase 2 Maximum value current phase 3 THD phase 1 THD phase 2 A B C 142. 143. 144. 145. 146. 147. 148. 14. 32. 52. 72. 31. 51. 71. D 5 5 5 5 5 5 5 5 7. 7. 7. 7. 7. 7. E x x x x x x F Meaning THD Phase 3 THD phase 1 THD phase 2 THD phase 3 Flicker intensity Pst U phase 1 Flicker intensity Pst U phase 2 Flicker intensity Pst U phase 3 Average value line frequency x. Harmonics (% refering to the fundamental wave) in U phase 1 x. Harmonics (% refering to the fundamental wave) in U phase 2 x. Harmonics (% refering to the fundamental wave) in U phase 3 x. Harmonics (% refering to the fundamental wave) in I phase 1 x. Harmonics (% refering to the fundamental wave) in I phase 2 x. Harmonics (% refering to the fundamental wave) in I phase 3 95 8.2 Standard impulse constants The impulse constants for the LED and the impulse outputs are designed in accordance with VDEW-Specifications 2.1. Other values are possible depending on the customers requests. LED Imp./kWh(kvarh) Impulse output Imp./kWh(kvarh) 3x230/400 V, 5II1 A 10 000 5 000 3x58/100 V, 5II1 A 40 000 20 000 100 000 50 000 50 000 20 000 1.000 500 500 250 5 000 2 500 3x58/100 V, 1 A 3x58/100 V, 1(2) A 3x230/400 V, 10(60) A 3x230/400 V, 10(100) A 3 x400/690 V, 5II1 A Table 31: Standard impulse constants with secondary meters If the meter has a long-range power supply and a certification relevant log book, the impulse constants for the LED(s), the impulse outputs and also impulse inputs can be changed at any time. Changing the impulse constants Open “Direct” > “LZQJ-settings (VDEW2.1)...” > “Impulse constants output” or “Impulse constants input” First of all read out the impulse constants set in the meter. Afterwards you can change the values and write them back into the meter. Further information can be found in the user manual EMH-COMBI-MASTER 2000. 96 8.3 Error register The LZQJ-XC has an error register. With the help of this register, functional errors in the meter are registered. Output of the error register takes place via the display and one of the readout lists. 8.3.1 Explanation of the individual error flags The LZQJ has 32 error flags which are represented by an 8 digit Hex-code. F.F(00000000) No error F.F(00000001) Incomplete data protection F.F(00000002) Incomplete cumulations F.F(00000003) Incomplete data protection + Incomplete cumulations F.F(00000004) Invalid flash data (no valid data protection found) F.F(00000005) Incomplete data protection + invalid flash data F.F(00000006) Incomplete data protection + Incomplete cumulations F.F(00000007) Incomplete data protection + Incomplete cumulation + invalid flash data F.F(00000100) Error in par-cross-check sum F.F(00000200) Error in set-cross-check sum F.F(00000300) Error in par-cross-check sum + error in set-cross-check sum F.F(00000400) Error in code-cross-check sum F.F(00000500) Error in par-cross-check sum + error in code-cross-check sum F.F(00000600) F.F(00000800) Error in set-cross-check sum + error in code-cross-check sum Error in par-cross-check sum + error in set-cross-check sum + error in codecross-check sum Error in system-cross-check sum F.F(00000900) Error in par-cross-check sum + error in system-cross-check sum F.F(00000A00) F.F(00004000) Error in set-cross-check sum + error in system-cross-check sum Error in par-cross-check sum + error in set-cross-check sum + error in system-cross-check sum Error in code-cross-check sum + error in system-cross-check sum Error in par-cross-check sum + error in code-cross-check sum + error in system-cross-check sum Error in set cross-check sum + error in code-cross-check sum + error in system-cross-check sum Error in par-cross-check sum + error in set-cross-check sum + error in codecross-check sum + error in system-cross-check sum Error in certification relevant log book F.F(00008000) Error in calibration-cross-check sum F.F(0000C000) F.F(08000000) Error in certification-relevant log book + error in calibration-cross-check sum Time basis error F.F(00008800) Error in system-cross-check sum and error in the calibration-cross-check sum F.F(00000800) Error in system-cross-check sum F.F(00008000) Error in calibration-cross-check sum F.F(08000002) Incomplete cumulation and time basis error F.F(00000002) Incomplete cumulations F.F(08000000) Time basis error F.F(00000700) F.F(00000B00) F.F(00000C00) F.F(00000D00) F.F(00000E00) F.F(00000F00) Table 32: Error examples 8.3.2 Clearing the error register To clear the error register use the W5-write command F.F(). To be able to execute this command the meter must be in the parameterisation status. After carrying out the W5-command the parameterisation status is switched off. 97 8.4 Software 8.4.1 EMH-COM EMH-COM is a modular developed software which enables communication between a readout device (e.g. PC or laptop) and EMH meters. The software is designed especially for starting up the meter, reading out data from the meter and also for changing the basic settings. Due to the modular set-up, the software can be tailored directly to the customer’s requests. The most important functions of the programs are: Reading out of meter data Graphical load profile display Setting the clock Modem function (optional) Tariff settings for different meter (optional) Send write command (optional) 8.4.2 EMH-COMBI-MASTER 2000 The EMH-COMBI-MASTER 2000 contains all functions of theEMH-COM program and allows in addition the configuration of meters from the series LZQJ-XC. The most important functions of the programs are: 98 All functions contained in the EMH-COM software Configuration of meters Setting of transformer ratios and digitness with transformer meters Further optional functions such as readout of the network quality and harmonics 8.4.3 EMH-Mobile EMH-Mobile is a mobile and manageable tool for starting up and reading out electricity meters on location. EMH-Mobile consists of a PDA (Personal Digital Assistant) and an optical communication adapter (Bluetooth-OKK). With both devices, a wireless communication is possible via a Bluetooth-interface Figure 42: EMH-Mobile The software EMH-Mobile is installed on the PDA for communication with meters. Special features of the software include “Installation check” (possible with all EMH meters with a service table) and also the readout of electronic household meters eHZ. Via the “Installation check” the meter connection can be easily checked. Connection errors can therefore be detected on location. Figure 43: EMH-Mobile - Table 1 Figure 44: EMH-Mobile - Installation check 99 8.5 Basic operation of the LZQJ-XC 8.5.1 Overview In the following you receive a short overview on the operation of the LZQJ-XC. Further support can be found in the user manual EMH-COMBI-MASTER 2000. Possibilities of meter communication (page 101 onwards) o Communication via the optical data interface o Communication via the electrical interface(s) Basic settings before communication (page 102 onwards) o General settings (interface, passwords and meter address) o Modem settings o Setting of date and time o Setting of the baud rate Read out of the meter (page 105 onwards) o Readout of tables 1 - 3 and the service table o Readout of load profiles o Read out of the operation log book o Read out of the certification relevant log book o Read out of the user log book o Read out of the event log books o Commenting the readout tables o Conversion of the load profile data Processing of readout data (page 111 onwards) o Opening and saving of files e.g. readout tables, load profiles (also converted), protocol files etc. 100 o o Transfer of set-, parameterisation-, tariff- and ripple control files Ripple control files o Execution of read- or write commands o Graphic display of load profiles o Export of load profile data 8.5.2 Possibilities of meter communication In the following, the communication between a readout device and a meter via the optical- or electrical interface are described. 8.5.2.1 Communication via optical interface The optical communication adapter OKK enables communication between a readout device (e.g. PC or laptop) and EMH meters. On the meter the connection is to the optical data interface D0 and on the PC, depending on the version, the connection is to a COMport or to a USB interface. Connection of the OKK: Connect the optical communication adapter OKK to a free COM-Port or a free USB interface on your PC. If you have an OKK with USB connection then a special USB driver must be installed. The driver can be found on the CD-ROM which is included in the delivery with the OKK. Tips for the installation of the driver can also be found on the CD-ROM. Note: Before communication can take place with the meter the interface must be configured under “Setting” > “Program settings...” >. (see 8.5.3.1 General settings). 8.5.2.2 Communication via electrical interface Communication with the meter via the connection PC-modem-meter modem (remote meter read out) requires the definition of some parameters (see 8.5.3.2 Modem). 101 8.5.3 Basic settings before communication 8.5.3.1 General settings Once the optical communication adapter or modem line has been set up correctly you still need to set the correct settings in EMH-COMBI-MASTER 2000: COM-Port, to which to an OKK is connected Baud rate Login-password W5-password Meter address Click “Setting” > “Program settings...” > “General” “Port” Setting the COM-Port when using an optical communication adapter OKK. Note: In order to determine the COM-Port when using an OKK with USB connection take a look at “Start” > “Settings” > “System control” > “System-[Hardware]-Device manager”. Further information on this can be found on the CD-ROM which is included in the delivery of the optical communication adapter. “Baud rate” Setting the interface speed Note: When using an OKK you should always use “Mode C”. “Bluetooth OKK” Activate this checkbox when using a Bluetooth-OKK. “Login-password” Input of the login-password With activation a password is sent to the meter when logging in. The password is saved encoded together with the program settings. “W5-password” Input of the W5-password Certain set commands (e.g. setting the clock, writing identity numbers) are only sent to the meter together with the W5 password. The pre-setting 00000000 only has to be changed if a different password was agreed on. 102 “Meter-address” Input of the meter-address This information is only necessary if the meter has a meter-address. The meter-address only applies to the meters electrical interface and therefore is only used with a remote readout or a special solution. The meter-address can by found by reading out the service table. The OBIS code for the meter-address is 0.0.0. 8.5.3.2 Modem settings To be able to communicate with the meter via a modem line the following settings must be made: Entry of the name and telephone number Definition of the PC-modem Definition of the meter modem (if necessary with password) Click “Setting” > “Program settings...” > “Modem” Field Phone number Entry of the telephone number of the meter modem which is to be called. Note: If a number for an outside line is necessary (often with telephone sets), this must be at the front of the telephone number. Then enter a “w”. The “w” causes a short dialing break after reaching the network before dealing further. If “w” does not operate properly then please contact the telephone administrator and ask for the interval signal. To insert a new row click on “New”. In order to delete a row click on the row and then on „Delete“. “Local modem …” Selection of the PC modem The modems which are most frequently used are included in the list. If your modem is not listed then select the setting “allg. Hayes-Modem;AT&FE0X3”. This setting functions with most types of modems. 103 Field meter modem selection Selection of the meter modem EMH-COMBI-MASTER 2000 supports meter modems from the manufacturer Dr. Neuhaus (ZDUE), Görlitz (ENC 280), Elster (DM 100) and EMH (Sparkline II, VARIOMOD) and others. As a rule, for simple, transparent modems it is sufficient to activate “Auto-Transparent modem”. In the field Modem-Timeout 90 s are entered as a standard. This information causes the program to automatically interrupt the connection if it is “faulty”. It is not recommended to select a smaller value. For meter modems with a password protection, the password can be entered in the field “Modem password”. If there is no password activated in the meter modem, the field stays empty. 8.5.3.3 Setting date and time In order to send the PC-time and PC-date to the meter to synchronise the meter proceed as follows: Click “Direct” > “Set clock” > “Write” It is also possible to read out the time and date from the meter. To do this click on “Read”. 8.5.3.4 Setting baud rate To set the start- and data baud rate for the external interface proceed as follows: Click “Direct” > “Baud rate...” > To begin with activate the option box “VDEW 2.1”. Now click on “Read” to read out the start- and data baud rate. Afterwards you can change the settings and send them to the meter by clicking on “Write”. 104 8.5.4 Reading out the meter 8.5.4.1 Reading out the tables You can read out the following tables: Table 1: Billing data Table 2: Load profile Table 3: EMH-internal data Service-Table: Service data (instantaneous values) Click “Readout” > “Table 1”/“Table 2”/“Table 3”/“Service table” At the end of every meter read out a BCC (Block Character Check) takes place. With this BCC, by means of a checksum sent by the meter, a check is carried out to see if the meter read out was correct (Announcement BCC = xx OK). . With a faulty data readout an announcement appears at the end of the readout that the sent BCC is not the same as the calculated BCC. The readout is displayed in red. To save the tables click on “Readout” > “Save”. Now select the directory where you want to save the file. In the field “File name” enter the name of the file and select in the field “Files of type” - “Readout files (*.tab)”. Then click on “Save”. 105 8.5.4.2 Reading out load profile data Click “Readout” > “P.01 Standard LP” or “P.02 User LP…” “Start date” Set the start date of the load profile to be read out, start time is 00:00 o’clock “End date” Set the end date of the load profile to be read out, end time is 24:00 o’clock “Read out compressed” Read out the compressed load profile This function can only be used if the meter supports the reading out of compressed load profiles. “Read out complete” Read out the complete load profile The readout of the load profiles can take a long time depending on the size and number of channels. “Read out identity number additionally” In addition to the load profile, the selected meter address or the identity number from the selection list is read out in order to be able to assign the load profile to the meter at a later date. “Read out R6 block by block” Activate this option to read out the load profile block by block. In the corresponding dropdown box you can enter the number of rows which should be read out within a readout cycle. A block by block readout makes sense when you read out the load profile via the telephone- or GSM network. This is to avoid destruction of the load profiles due to interference in the network. Button Read out single load profile channels, selection leads to extension of the window. First of all read out all available channels via the button “read out available channels”. Then you can select the load profile channels to be read out by clicking on the checkbox. To read out the marked load profile channels click on “OK”. 106 8.5.4.3 Reading out operation log book P.98 Click “Readout” > “P.98 Log book..” “Start date” Set the start date of the log book which is to be read out, start time is 00:00 o’clock “End date” Set the end date of the log book which is to be read out, end time is 24:00 o’clock “Read out complete” Read out the complete log book “Read out identity numbers additionally” In addition to the log book entries, the selected meter address or identity number in the selection list is read out in order to be able to allocate the log book entries to the meter at a later date. “Read out R6 block by block” Activate this option to read out the load profile block by block. In the corresponding dropdown box you can enter the number of rows which should be read out within a readout cycle. A block by block readout makes sense when you read out the load profile via the telephone- or GSM network. This is to avoid destruction of the load profiles due to interference in the network. 8.5.4.4 Reading out certification relevant log book P.99 Click “Readout” > “P. 99 Certification relevant log book” In the certification relevant log book changes of the LED-impulse constants and also of the impulse values from the P- and Q-output are saved. Altogether a maximum of 40 entries are contained in the certification relevant log book. 107 8.5.4.5 Reading out the user log book P.200 Click “Readout” > “P.200 User log book” 8.5.4.6 Reading out event log book P.210 Click “Readout” > “P.210 Event log book” 8.5.4.7 Reading out event log book P.211 Click “Readout” > “P.211 Event log book” 8.5.4.8 Commenting readout tables To explain the readout data you can comment the tables, load profiles and log books row by row. Click “Readout” > “Comment” Without comments: With comments: The tables, load profiles and log books are always read out without comments. Therefore a comment is only possible after the readout. 108 8.5.4.9 Converting load profiles Conversion of load profile data as preparation for data export After reading out a load profile the readout looks as follows: Click “Readout” > “Convert” First of all the following window opens: In the selection box “Transformer factor“ you can set a transformer factor. This setting has an effect on the scaling of the Y-axis in the display. Provided that you use the programs control centre you can search for the transformer factor belonging to a customer/meter. For this click on “Search for transformer factor in control centre”. The identity number is then searched for in the control centre data to determine the transformer factor. If no identity number is found in the control centre data, the following window appears: The transformer factor then has to be set manually in the dropdown box. Note: The transformer factor only effects the graphic load profile display and the printout. The load profile conversion is not affected by this. Here a factor for export can be specified independent of the graphic display. 109 After conversion the load profile data looks as follows: Attention: After a conversion to data export a graphical load profile display is no longer possible! Export of load profile data To export the load profile click on “Readout” > “Save...”. Select the index where the file should be saved and enter the name of the file in the field “File name”. After this, select the file type load profile export (*.txt) and click on “Save”. Afterwards you can import the file in a spreadsheet program e.g. MS Excel (for this see chapter 8.5.5.6 Export page 115 onwards). 110 8.5.5 Processing the readout data 8.5.5.1 Opening files Opening files e.g. readout tables, load profiles (also converted), protocol files etc. Click “Readout” > “Open” 8.5.5.2 Saving files Saving files e.g. readout tables, load profiles (also converted), protocol files etc. Click “Readout” > “Save” 8.5.5.3 Transferring files Transferring saved set-, parameterisation-, tariff- and ripple control files Click “File” > “Transfer...” Click “Transfer”. Select the file which is to be transferred and click on “Open”. The file is now transferred to the meter. To close the window click on “Cancel”. Note: Pay attention that in the selection field “File type” the type of file is selected which you want to transfer. Otherwise the file to be transferred will not be displayed in the window. 111 8.5.5.4 Executing read- and write commands Sending read- or write commands to the meter Click “Direct” > “Single commands...” 1. Example: Read out time from the meter Click “Direct” > “Single commands...” “Read command” 2. Example: Send identity number to the meter Click “Direct” > “Individual commands ..” “ Write command” 8.5.5.5 Graphic display of load profiles Graphical display of load profile data Click “Readout” > “Graphic display” The x-axis (abscissa) describes the time, the y-axis (ordinate) the performance. For every channel a separate scaling of the y-axis can be shown. This must be pre-defined under “Readout” > “Graphic display” > “Channel” > “Selection”. With the horizontal scrolling beam you can move the time axis. With the sliding controller “Zoom” which can be found in the lower area of the window it is possible to make the viewed time frame of the load profile curve longer or shorter. If several days are shown in the graphic then you can change over to a daily display via a double click on one of the shown dates. The cursor always marks a measuring period duration which can be moved with the cursor buttons and also Pic , Pic , Pos 1 and End. When you move the cursor in the main area of the window, the relevant load profile values appear in the field below this with information about the time stamp and the status entries. 112 Menu bar of the graphic display “Graphic” > “Print” Prints the content of the window “Graphic” > “Exit” Closes the graphic display, return to the main window “Channel” After activation of the menu option “Channel”, the following window appears: Via the buttons you can “activate all channels” or “deactivate all channels”. Via the checkboxes you can however also activate or deactivate individual channels. “In the load profile graphic individual scaling of each channel” In the graphic load profile display the scaling of the y-axis is separately shown for every channel. “Set zero point of the Y-axis automatically” In the graphic load profile display the bottom limit of the y-axis is modified to reach a higher resolution. “Scaling only in the visible area” Representation of the load profile is scaled to the window size depending on the zoom setting. “Season display and evaluation” Representation of the load profile is scaled to the window size depending on the zoom setting. 113 “Transformer factor” Multiplication of the load profile data with a transformer factor Via the dropdown box you can set a transformer factor for the load profile display. This setting effects the scaling of the y-axis in the display. Provided that you use the control centre of the program you can search for the transformer factor which belongs to a meter/customer. For this click on “Search for transformer factor in the control centre”. The identity number is then searched for in the control centre data to determine the transformer factor. If no identity number is found in the control centre the following window appears. The transformer factor then has to be set manually in the dropdown box. Note: The transformer factor only effects the graphical load profile display and the print. The load profile conversion is not affected by this. Here a factor for export can be specified independent of the graphic display. “Total evaluation” “Complete LP ” Here it is possible to “Display” and “Print” the evaluation of the complete load profile channel by channel. “Displayed LP ” Here a channel by channel evaluation of the load profile in the area displayed in the window takes place. The functions “Display” and “Print” are also available here. 114 8.5.5.6 Export of load profile data Before export, the load profile files must be converted (see page 109). After this, save the data under “Readout” > “Save...” as “Load profile export (*.txt)”. The exported load profile file (here called “Musterlastprofil”) looks as follows when opened: In order to import the file “Musterlastprofil” in Excel and to represent the load profile graphically proceed as follows: 1. Open Excel. 2. Click on “File” > “Open”. 3. Select the file type “All files(*.*)”. The file “Musterlastprofil” can now be seen. 4. Open the file “Musterlastprofil”. 115 116 5. In the following window click on “Fertig stellen”. 6. Mark the desired display area, e.g. 1 day over the columns A to E. 7. Now call up the “Diagramm-Assistent” and select the “Linie”. 8. Click on “Weiter” until the following window appears: 117 9. Click on “Weiter” until the following window appears: In the box “Diagrammtitel”, enter for example “Lastgang”, in the box Rubrikenachse (X) “Zeit” and in the field Größenachse (Y) “P+”, “Q+”. Then click on “Weiter”. 10. In the following window you must decide if the diagram should be included on the active page or if a new page should be created for the diagram. Then click on the “Fertig stellen”. 11. In this example we have decided to create a new page. Excel has created a new page for the title “Diagramm” on which the load profile is graphically represented. 118 9 EU Declaration of Conformity Figure 45: EU Declaration of Conformity Note: The current EU Declaration of Conformity can be requested at any time. 119