Kamstrup A/S · Industrivej 28, Stilling · DK-8660 Skanderborg · T: +45 89 93 10 00 · info@kamstrup.com · kamstrup.com
Technical Description
MULTICAL® 801
MULTICAL® 801
2
Kamstrup A/S · Technical Description · 5512-571_R1_GB_11_2016
MULTICAL® 801
Kamstrup A/S · Technical Description · 5512-571_R1_GB _11.2016
3
Contents
1 General Description ........................................................................................................ 6
1.1 Block diagram ...................................................................................................................................... 6
2 Technical data ................................................................................................................ 7
2.1 Approved meter data ............................................................................................................................ 7
2.2 Electrical data ....................................................................................................................................... 8
2.3 Mechanical data ................................................................................................................................. 10
2.4 Material .............................................................................................................................................. 10
2.5 Accuracy ............................................................................................................................................. 11
3 Type overview ............................................................................................................... 12
3.1 Type and programming overview ......................................................................................................... 12
3.2 Type number composition................................................................................................................... 13
3.3 PROG, A-B-CCC-CCC ............................................................................................................................ 14
3.4 Display coding .................................................................................................................................... 24
3.5 >EE< Configuration of MULTI-TARIFF ...................................................................................................... 26
3.6 >FF< Input A (VA), pulse division >GG< Input B (VB), pulse division ........................................................ 27
3.7 >MN< Configuration of leak limits ......................................................................................................... 28
3.8 Data for configuration ......................................................................................................................... 29
4 Dimensioned sketches .................................................................................................. 30
5 Installation ................................................................................................................... 31
5.1 Mounting in inlet or outlet pipe ........................................................................................................... 31
5.2 EMC conditions................................................................................................................................... 32
5.3 Climatic conditions ............................................................................................................................. 32
5.4 Electrical installations ........................................................................................................................ 32
5.5 Terminal Overview .............................................................................................................................. 32
6 Calculator functions ...................................................................................................... 33
6.1 Energy calculation .............................................................................................................................. 33
6.2 Application types ................................................................................................................................ 34
6.3 Calculator with two flow sensors ......................................................................................................... 39
6.4 Combined heat/cooling metering ........................................................................................................ 40
6.5 Flow measurement V1 and V2 ............................................................................................................. 41
6.6 Power measurement, V1 ..................................................................................................................... 42
6.7 Min. and max. flow and power, V1 ...................................................................................................... 43
6.8 Temperature measurement ................................................................................................................. 44
6.9 Display functions ................................................................................................................................ 46
6.10 Info codes .......................................................................................................................................... 51
6.11 Tariff functions ................................................................................................................................... 54
6.12 Data loggers ....................................................................................................................................... 58
6.13 Leak surveillance ................................................................................................................................ 60
MULTICAL® 801
4
Kamstrup A/S · Technical Description · 5512-571_R1_GB_11_2016
6.14 Reset functions .................................................................................................................................. 63
6.15 SMS commands ................................................................................................................................. 64
7 Flow meter connection.................................................................................................. 66
7.1 Volume inputs V1 and V2 ................................................................................................................... 66
7.2 Flow meter with active 24 V pulse output ....................................................................................... 67
7.3 Pulse inputs VA and VB ...................................................................................................................... 73
8 Temperature sensors .................................................................................................... 75
8.1 Sensor types ...................................................................................................................................... 76
8.2 Cable influence and compensation .................................................................................................... 77
8.3 Pocket sensors .................................................................................................................................. 79
8.4 Pt500 short direct sensor pair ............................................................................................................ 80
9 Other connections ........................................................................................................ 81
9.1 Pulse outputs CE and CV [16-19] ........................................................................................................ 81
9.2 Analog outputs [80-87] ...................................................................................................................... 81
9.3 Data connection [62-64] ..................................................................................................................... 82
9.4 Valve control [16B-18B] ..................................................................................................................... 82
9.5 Auxiliary supply [97A-98A] ................................................................................................................. 83
10 Power supply ............................................................................................................ 84
10.1 Built in battery backup ....................................................................................................................... 84
10.2 230 VAC supply ................................................................................................................................. 85
10.3 24 VAC supply ................................................................................................................................... 85
For MULTICAL® 801 with both analog outputs and high-power communication we recommend a stronger
transformer, e.g. type 5920-161..................................................................................................................... 86
10.4 Danish regulations for the connection of mains operated meters ........................................................ 87
11 Plug-in modules ........................................................................................................ 88
11.1 Plug-in modules ................................................................................................................................. 88
11.2 Retrofitting modules .......................................................................................................................... 97
12 Data communication ................................................................................................. 99
12.1 MULTICAL 801 Data Protocol ............................................................................................................ 99
12.2 MULTICAL 66-CDE compatible data ................................................................................................. 101
13 Calibration and verification ..................................................................................... 102
13.1 High-resolution energy reading ........................................................................................................ 102
13.2 Pulse interface ................................................................................................................................. 103
13.3 True energy calculation .................................................................................................................... 104
14 METERTOOL HCW .................................................................................................... 105
14.1 Introduction ..................................................................................................................................... 105
14.2 How to use METERTOOL HCW for MULTICAL® 801 .............................................................................. 106
14.3 Verification using METERTOOL HCW .................................................................................................. 112
14.4 LogView HCW ................................................................................................................................... 115
MULTICAL® 801
Kamstrup A/S · Technical Description · 5512-571_R1_GB _11.2016
5
15 Approvals ................................................................................................................ 117
15.1 Type approvals ................................................................................................................................. 117
15.2 The Measuring Instrument Directive .................................................................................................. 117
16 Troubleshooting ...................................................................................................... 118
17 Environmental declaration ....................................................................................... 119
17.1 Disposal ........................................................................................................................................... 119
17.2 Transport restrictions ........................................................................................................................ 119
18 Documents .............................................................................................................. 120
MULTICAL® 801
6
Kamstrup A/S · Technical Description · 5512-571_R1_GB_11_2016
1 General Description
MULTICAL® 801 is an energy meter with many applications. In addition to being an accurate and reliable mains
supplied heat meter, MULTICAL
®
801 can also be used for:
• Energy metering independent of supply voltage interruptions
• Cooling metering in water-based systems
• Bifunctional heat/cooling metering in separate registers
• Leak surveillance of heat and cold water installations
• Power and flow limiter with valve control
• Data logger
• Data communication
• Analog 0/4…20 mA outputs
In designing MULTICAL
®
801, we have attached great importance to flexibility through programmable functions and
plug-in modules in order to secure optimum use in a wide range of applications. In addition, the construction makes
it possible to update previously installed MULTICAL
®
801 via the PC-program METERTOOL.
This technical description has been written with a view to enabling operations managers, meter installers,
consulting engineers and distributors to utilize all functions comprised in MULTICAL
®
801. Furthermore, the
description is directed to laboratories performing tests and verification.
MULTICAL
®
801 is based on the platform used for MULTICAL® 601. However, many extra facilities such as back
illuminated display, back up of energy metering during power failure, extra communication channels and the option
of four analog outputs have been added.
1.1 Block diagram
MULTICAL® 801
Kamstrup A/S · Technical Description · 5512-571_R1_GB _11.2016
7
2 Technical data
2.1 Approved meter data
Approval DK-0200-MI004-009
Standard EN 1434:2007 and OIML R75:2002
EU-directives Measuring Instrument Directive, Low Voltage Directive,
Electromagnetic Compatibity Directive
Temperature range θ: 2 °C…180 °C
Differential range ∆Θ: 3 K…170 K
Accuracy E
C
± (0.5 + ∆Θ
min
/∆Θ) %
Temperature sensors -Type 67-F and 67-K Pt100 – EN 60 751, 4-wire connection
-Type 67-G and 67-L Pt500 – EN 60 751, 4-wire connection
Compatible flow meter types -ULTRAFLOW
-Electronic meters with active or passive pulse output
-Mechanical meters with electronic pick-up
-Mechanical meters with reed contact
Flow meter sizes [kWh] qp 0.6 m
3
/h…15 m3/h
[MWh] qp 0.6 m
3
/h…15000 m3/h
[GJ] qp 0.6 m
3
/h…30000 m3/h
EN 1434 designation Environmental class A and C
MID designation Mechanical environment: Class M1
Electromagnetic environment: Class E1 and E2
Non-condensing environment, closed location
5…55 °C (indoors)
MULTICAL® 801
8
Kamstrup A/S · Technical Description · 5512-571_R1_GB_11_2016
2.2 Electrical data
Calculator data
Typical accuracy
Calculator EC ± (0.15 + 2/∆Θ) %
Sensor pair: ET ± (0.4 + 4/∆Θ) %
Display
LCD – 7 (8) digits with digit heigth 7.6 mm and back illumination
Resolution
9999.999 – 99999.99 – 999999.9 – 9999999 - 99999999
Energy units
MWh – kWh – GJ – Gcal
Data logger (Eeprom)
Standard: 460 days, 36 months, 15 years, 50 info codes
Standard: Programmable data logger with logging depth 1080 registers
Clock/calendar
Standard: Clock, calendar, leapyear compensation, target date
Standard: Real time clock with battery backup
Standard: Battery backup of energy measurement incl. ULTRAFLOW
Data communication
Standard: KMP protocol with CRC16 used for optical communication
as well as base modules
Power of temperature sensors
<
10 µW RMS
Mains supply
230 VAC +15/-30 %, 50/60 Hz (all types)
24 VAC ±50 %, 50/60 Hz (Type 67-F/G without analog outputs)
24 VAC ±25 %, 50/60 Hz (Type 67-F/G with analog outputs)
Insulation voltage
4 kV
Power consumption
Current consumption
<
3 W without analog outputs
< 9 W with analog outputs
Max. 50 mA/230 VAC
Max. 450 mA/24 VAC
Battery backup
3.65 VDC, 2 batteries A-cell lithium
(Type No. 66-99-619)
Replacement interval
Backup period
10 years’ normal operation (with mains supply)
1 year (without supply)
The replacement interval is reduced at high ambient temperature
EMC data
Fulfils EN 1434 class A and C (MID class E1 and E2)
MULTICAL® 801
Kamstrup A/S · Technical Description · 5512-571_R1_GB _11.2016
9
Temperature measurement
T1
T2
T3
T4
-Type 67-F and 67-K
4-W Pt100
Measuring range
0.00…185.00 °C 0.00…185.00 °C 0.00…185.00 °C
N/A
Preset range
0.01…180.00 °C 0.01…180.00°C 0.01…180.00 °C 0.01…180.00 °C
-Type 67-G and 67-L
4-W Pt100
Measuring range
0.00…185.00 °C 0.00…185.00 °C 0.00…185.00 °C
N/A
Preset range
0.01…180.00 °C
0.01…180.00 °C
0.01…180.00 °C
0.01…180.00 °C
Max. Cable lengths
(Max Ø6mm cable)
Pt100, 2-wire
Pt500, 2-wire
Pt500, 4-wire
2 x 0.25 mm2: 2.5 m
2 x 0.50 mm2: 5 m
2 x 1,00 mm
2
: 10 m
2 x 0.25 mm2: 10 m
2 x 0.50 mm2: 20 m
4 x 0.25 mm2: 100 m
-
MULTICAL® 801
10
Kamstrup A/S · Technical Description · 5512-571_R1_GB_11_2016
Flow measurement V1 and V2
ULTRAFLOW
V1: 9-10-11 and V2: 9-69-11
Reed contacts
V1: 10-11 and V2: 69-11
24 V active pulses
V1: 10B-11B and V2: 69B-79B
EN 1434 pulse class
IC
IB
(IA)
Pulse input
220 kΩ pull-up to 3.6 V 220 kΩ pull-up to 3.6 V
12 mA at 24 V
Pulse ON
<
0.4 V i > 0.5 ms
<
0.4 V i > 50 ms
<
4 V i > 3 ms
Pulse OFF
> 2.5 V i > 10 ms
> 2.5 V i > 50 ms
> 12 V i > 10 ms
Pulse frequency
<
128 Hz
<
1 Hz
<
128 Hz
Integration frequency
<
1 Hz
<
1 Hz
<
1 Hz
Electrical isolation
No
No
2 kV
Max. cable length
10 m
25 m
100 m
Pulse inputs VA and VB
VA 65-66 and VB: 67-68
Water meter connection
FF(VA) and GG(VB) = 01…40
Electricity meter connection
FF(VA) and GG(VB) = 50…60
Pulse input
680 kΩ pull-up to 3.6 V
680 kΩ pull-up to 3.6 V
Pulse ON
<
0.4 V i > 30 ms
<
0.4 V i > 30 ms
Pulse OFF
>
2.5 V i > 30 ms
>
2.5 V i > 30 ms
Pulse frequency
<
1 Hz
<
3 Hz
Electrical isolation
No
No
Max. cable length
25 m
25 m
Requirements to ext. contact
Leak current at function open < 1 µA
Pulse outputs CE and CV
Energy (16-17) Volume (18-19)
Type
Open collector (OB)
Pulse duration
Programmable 32, 100 or 247 ms via METERTOOL
External voltage
5…30 VDC
Current
1…10 mA
Residual stress
UCE ≈ 1 V at 10 mA
Electrical isolation
2 kV
Max. cable length
25 m
2.3 Mechanical data
Environmental class
Fulfils EN 1434 class A and C
Ambient temperature
5…55 °C non-condensing, closed location (installation indoors)
Protection class
IP67
Storage temperature
-20…60 °C (drained flow meter)
Weight
1.4 kgs excl. sensors and flow meter
Cable adapters
6 pcs. D 3…6 mm and 3 pcs. D 4…8 mm
2.4 Material
Top cover
PC
Connection base
PC + 10 %GF
Sealing cover, top
ABS
Sealing cover, bottom
PC
Prism behind display
PMMA
MULTICAL® 801
Kamstrup A/S · Technical Description · 5512-571_R1_GB _11.2016
11
2.5 Accuracy
Figure 1
MULTICAL
®
801 typical accuracy compared to EN 1434.
MULTICAL® 801
12
Kamstrup A/S · Technical Description · 5512-571_R1_GB_11_2016
3 Type overview
MULTICAL® 801 can be ordered in countless combinations as required by the customer. First, you select the
required hardware from the type overview. Then select ”Prog”, ”Config” and ”Data” to suit the application in
question.
The supplied meter is configured from the factory and ready for use, however it can be changed/reconfigured after
installation.
Please note that the points marked “Total prog” cannot be changed without breaking the verification seal. This
means that the change must be carried out by an accredited meter laboratory.
We currently develop new functions and modules for MULTICAL
®
801. Please contact Kamstrup A/S if your
application is not covered by the variants shown.
3.1 Type and programming overview
Type number 67-x-x-xx-xxx-xxx
Total prog
Choice of calculator, modules,
sensor pairs and flow sensor
Prog. A-B-CCC-CCC
Total prog
Config. DDD-EE-FF-GG-M-N
Partial prog.
Data
Partial prog.
MULTICAL® 801
Kamstrup A/S · Technical Description · 5512-571_R1_GB _11.2016
13
3.2 Type number composition
*) ULTRAFLOW is packed in a separate carton which is strapped together with the MULTICAL 801 carton. The cable between
MULTICAL
801 and ULTRAFLOW it not connected from the factory.
**) GSM module and RF module are NOT combinable in one meter.
MULTICAL
801 Type 67-
Sensor connection
Pt100 4-wire (T1-T2-T3) No analog outputs
F
Pt500 4-wire (T1-T2-T3) No analog outputs
G
Pt100 4-wire (T1-T2-T3) 4 analog outputs
K
Pt500 4-wire (T1-T2-T3) 4 analog outputs
L
Module 2 (VA and VB are not available for module position 2)
No module
0
SIOX module (Auto detect Baud)
M
M-Bus (Alternative registers)
P
M-Bus modul with MCIII data package
Q
M-Bus V RadioRouter **)
W
LonWorks, FTT-10A
Y
GSM/GPRS module **)
Z
3G GSM/GPRS module (GSM8H)
U
Ethernet/IP module (IP201)
T
Module 1 (VA and VB are available for module position 1)
No module
00
M-Bus + pulse inputs
20
RadioRouter + pulse inputs **)
21
Data logger + 4-20 mA inputs + pulse inputs
22
LonWorks, FTT-10A + pulse inputs
24
M-Bus (Alt. reg.) + pulse inputs
27
M-Bus module with MC-III data package + pulse inputs
29
Wireless M-Bus Mode C1 + pulse inputs
30
Wireless M-Bus Mode T1 OMS 15 min. (Individual key )
31
Wireless M-Bus Mode C1 Alt. reg. (Individual key) + pulse inputs
35
Wireless M-Bus Mode C1 Fixed Network (Individual key)
38
ZigBee 2.4 GHz int.ant. + pulse inputs
60
Metasys N2 (RS485) + pulse inputs
62
SIOX module (Auto detect Baud rate)
64
BACnet MS/TP + pules inputs
66
Modbus RTU + pulse inputs
67
High Power Radio Router + pulse inputs
84
Supply
230 VAC supply
7
24 VAC supply
8
Pt500 sensor pair (2-wire sensors)
No sensor pair
0
Pocket sensor pair with 1.5 m cable
A
Pocket sensor pair with 3.0 m cable
B
Pocket sensor pair with 5 m cable
C
Pocket sensor pair with 10 m cable
D
Short direct sensor pair with 1.5 m cable
F
Short direct sensor pair with 3.0 m cable
G
Set of 3 pocket sensors with 1.5 m cable
L
Set of 3 short direct sensors with 1.5 m cable
Q3
Flow sensor/pick-up unit
1 ULTRAFLOW included *)
(specificy type)
1
2 nos. ULTRAFLOW included *)
(specificy type)
2
Prepared for 1 ULTRAFLOW
(specificy type)
7
Prepared for 2 nos. (identical) ULTRAFLOW
(specificy type)
8
Prepared for meters w/Reed switch output (both V1 and V2)
L
Prepared for foreign flowpart with passive/active pulses
N
Meter type
Heat meter, (MID module B+D)
2
Heat/cooling meter (MID modules B+D & TS+DK268)
3
Heat meter, National approvals
4
Cooling meter (TS27.02+DK268)
5
Heat/Cooling meter
6
Volume meter, hot water
7
Volume meter, cooling water
8
Energy meter
9
Delivery code (language on label etc.)
XX
MULTICAL® 801
14
Kamstrup A/S · Technical Description · 5512-571_R1_GB_11_2016
3.2.1 Accessories
30-26-857 Flow meter bracket
66-99-098 Data cable w/USB plug
66-99-099 Infrared optical reading head w/USB plug
66-99-102 Infrared optical reading head RS232 w/D-sub 9F
66-99-106 Data cable RS232, D-sub 9F
66-99-136 Infrared optical reading head for Kamstrup/EVL w/RS232 w/D-sub 9F
66-99-144 Infrared optical reading head for Kamstrup/EVL w/USB plug
66-99-370 Verification unit, Pt100 (to be used with METERTOOL)
66-99-371 Verification unit, Pt500 (to be used with METERTOOL)
66-99-619 Batteri backup (2xA cell lithium battery)
66-99-278 Short circuit pen (for total reset and total programming)
66-99-209 Short circuit jumper (for use with 2-wire temperature sensors)
16-40-080 Jumper for modules
65-56-4x-xxx Temperature sensor pair with connection head (2/4-wire)
59-20-177 Cable gland wrench 15 mm (hardened galvanised steel)
59-20-178 Cable gland wrench 19 mm (hardened galvanised steel)
66-99-103 Q144 dummy cover (144 mm x 144 mm) for blinding in panels/racks
66-99-634 24VAC High Power SMPS modul
66-99-622 230 VAC High Power SMPS modul
679xxxxxx2xx External Communication Box
66-99-724 METERTOOL for HCW
66-99-725 LogView for HCW
Contact Kamstrup A/S for questions about further accessories.
3.3 PROG, A-B-CCC-CCC
The Prog, which cannot be changed without breaking the verification seal, determines the meter’s legal parameters.
This means that the change must be made by an accredited laboratory.
The A-code states whether flow sensor (V1) is installed in inlet or outlet pipe. As the volume of water increases with
temperature, the calculator must correct for the installation form in question. Wrong programming or installation
results in measuring errors. Further details concerning installation of flow sensor in inlet and outlet in connection
with heat and cooling meters appear from section 5.1.
The B-code indicates the measuring unit used for the energy register. GJ, kWh or MWh are the most used units,
whereas only a few countries outside the EEA use Gcal.
The CCC-code states the calculator’s adaption to a specific flow sensor type to the effect that calculating speed and
display resolution are optimized for the selected flow sensor at the same time as type approval regulations about
minimum resolution and maximum register overflow are obeyed. We have divided the CCC-codes into smaller tables
in order to obtain a faster overview.
CCC(V1) states the CCC-code of the flow sensor connected to flow sensor input V1 on terminals 9-10-11 (or 10B-
11B). In most applications, this is the flow sensor used for energy calculation.
CCC(V2) states the CCC-code of a possible extra flow sensor, which can be connected on terminals 9-69-11 (or 69B-
79B). If V2 is not used, CCC(V2) is equal to CCC(V1). For leak surveillance CCC(V2) must be equal to CCC(V1).
MULTICAL® 801
Kamstrup A/S · Technical Description · 5512-571_R1_GB _11.2016
15
Prog. number
A - B
-
CCC (V1)
-
CCC (V1)
Flow meter position
k-factor
table
- Inlet (at T1)
3
- Outlet (at T2)
4
Measuring unit, Energy
- x10 GJ 1 - GJ 2 - kWh 3 - MWh 4 - Gcal 5
Flow meter coding
(CCC-table)
CCC CCC
MULTICAL® 801
16
Kamstrup A/S · Technical Description · 5512-571_R1_GB_11_2016
3.3.1 CCC-TABLE FOR MULTICAL
801
The CCC-tables are divided into quick codes (CCC=4XX and 1XX) for electronic meters, e.g. ULTRAFLOW
, and slow
codes for e.g. reed contacts (CCC=0XX).
CCC= 4XX Electronic meters with quick and bounce-free pulses as well as info codes for ULTRAFLOW
X4
Max. pulse frequency: 128 Hz
Max. integration frequency: 1 Hz
CCC= 1XX Electronic meters with quick and bounce-free pulses
Max. pulse frequency: 128 Hz
Max. integration frequency: 1 Hz
CCC= 0XX Mechanical meters delivering slow pulses with bounce (flow sensor type "L")
Max. pulse frequency: 1 Hz
Max. integration frequency: 1 Hz
Max. integration frequency is 1 Hz for all types. The CCC-codes have been so composed that qs+20 % (or Qmax+20
%) does not exceed an integration frequency of 1 Hz.
Example: CCC=107 (applying to a qp 1.5 m
3
/h meter) : 1 Hz integration frequency is obtained at q = 3.6 m3/h.
EN 1434 comprises requirements to the resolution and register size of the energy indication. MULTICAL
®
801
fulfils these requirements provided that it is connected to one of the below-mentioned flow sensor sizes:
[kWh] qp 0.6 m
3
/h…15 m3/h
[MWh] qp 0.6 m
3
/h…15000 m3/h
[GJ] qp 0.6 m
3
/h…30000 m3/h
MULTICAL® 801
Kamstrup A/S · Technical Description · 5512-571_R1_GB _11.2016
17
3.3.2 CCC-codes for ULTRAFLOW
X4
Number of decimals in display
CCC
No.
Pre-
counter
Flow
factor
kWh MWh
Gcal
GJ m³
[ton]
l/h m³/h kW MW Imp./l qp
[m³/h]
Type No. Flow sensor
416 3000 78642 0 3 2 2 0 - 1 - 300 0.6 65-X-CAAA-XXX 1-2-7-8
65-X-CAAD-XXX
65-X-CAAF-XXX
484 300 78642 1 - 3 3 0 - 1 - 300 0.6 1-2-7-8
419 1000 235926 0 3 2 2 0 - 1 - 100 1.5 65-X-CDA1-XXX 1-2-7-8
65-X-CDAA-XXX
65-X-CDAC-XXX
65-X-CDAD-XXX
65-X-CDAE-XXX
65-X-CDAF-XXX
65-X-CDBA-XXX
407 100 235926 1 - 3 3 0 - 1 - 100 1.5 1-2-7-8
498 600 393210 0 3 2 2 0 - 1 - 60 2.5 65-X-CEAF-XXX 1-2-7-8
65-X-CEB/CA-XXX
451 5000 471852 - 2 1 1 0 - 1 - 50 3.5 65-X-CGAG-XXX 1-2-7-8
65-X-CGB/CB-XXX
436 500 471852 0 3 2 2 0 - 1 - 50 3.5 1-2-7-8
437 2500 943704 - 2 1 1 0 1 - 25 6 65-X-CHAF-XXX 1-2-7-8
65-X-CHAG-XXX
65-X-CHAH-XXX
65-X-CHB/CB-XXX
438 250 943704 0 3 2 2 0 - 1 - 25 6 1-2-7-8
447 1000 2359260 - 1 0 0 - 2 - 3 1,0 150 65-5-FCCN-XXX 1-2-7-8
478 1500 1572840 - 2 1 1 0 - 1 - 15 10 65-X-CJAJ-XXX 1-2-7-8
65-X-CJB/C2-XXX
65-X-CJB/CD-XXX
481 600 3932100 - 1 0 0 - 2 - 3 0,6 250 65-5-FDCN-XXX 1-2-7-8
483 150 1572840 0 3 2 2 0 - 1 - 15 10 1-2-7-8
420 1000 2359260 - 2 1 1 0 - 1 - 10 15 65-X-CKB/C4-XXX 1-2-7-8
65-X-CKB/CE-XXX
485 100 2359260 0 3 2 2 0 - 1 - 10 15 1-2-7-8
479 600 3932100 - 2 1 1 0 - 1 - 6 25 65-X-CLBG-XXX 1-2-7-8
458 5000 471852 - 1 0 0 - 2 0 - 5 40 65-X-CMBH-XXX 1-2-7-8
65-X-CMBJ-XXX
486 500 471852 - 2 1 1 - 2 0 - 5 40 1-2-7-8
470 2500 943704 - 1 0 0 - 2 - 3 2,5 60 65-X-FACL-XXX 1-2-7-8
487 250 943704 - 2 1 1 - 2 - 3 2,5 60 1-2-7-8
480 1500 1572840 - 1 0 0 - 2 - 3 1,5 100 65-X-FBCL-XXX 1-2-7-8
488 150 1572840 - 2 1 1 - 2 - 3 1,5 100 1-2-7-8
489 100 2359260 - 2 1 1 - 2 - 3 1,0 150 65-5-FCCN-XXX 1-2-7-8-N
491 400 589815 - 1 0 0 - 1 - 2 0,4 400 65-5-FECN-XXX 1-2-7-8-N
65-5-FECP-XXX
65-5-FECR-XXX
MULTICAL® 801
18
Kamstrup A/S · Technical Description · 5512-571_R1_GB_11_2016
492 250 943704 - 1 0 0 - 1 - 2 0,25 600 65-5-FFCP-XXX 1-2-7-8-N
65-5-FFCR-XXX
493 150 1572840 - 1 0 0 - 1 - 2 0,15 1000 65-5-FGCR-XXX 1-2-7-8
ULTRAFLOW® high-resolution CCC-codes
3.3.3 CCC-codes for ULTRAFLOW
II, type 65 54 XXX
Number of decimals in display
CCC
No.
Pre-
count
er
Flow factor
kWh
MWh
Gcal
GJ m³
[tons]
l/h m³/h kW MW Imp./l
qp
[m³/h]
Type No. Flow
sensor
116 3000 78642 0 3 2 2 0 1 300 0.6 65 54 A8X
65 54 AAX
1-2-7-8-N
119 1000 235926 0 3 2 2 0 1 100 1.5 65 54 A6X
65 54 A7X
65 54 A1X
65 54 A2X
65 54 A3X
1-2-7-8
136 500 471852 0 3 2 2 0 1 50.0 2.5
65 54 A4X
65 54 ADX
1-2-7-8
151 5000 471852 2 1 1 0 1 50.0 3.5 65 54 B1X
65 54 B7X
1-2-7-8
137 2500 943704 2 1 1 0 1 25.0 6.0
6.0
10
10
65 54 B2X
65 54 B2X
65 54 BGX
65 54 BHX
1-2-7-8
120 1000 2359260 2 1 1 0 1 10.0 15
25
65 54 B4X
65 54 B8X
1-2-7-8
158 5000 471852 1 0 0 2 0 5.0 40 65 54 B9X 1-2-7-8
170 2500 943704 1 0 0 2 3 2.5 60 65 54 BAX 1-2-7-8
147 1000 2359260 1 0 0 2 3 1.0 150 65 54 BBX 1-2-7-8
194 400 5898150 1 0 0 2 3 0.4 400 65 54 BCX 1-2-7-8
195 250 9437040 1 0 0 2 3 0.25 1000 65 54 BKX 1-2-7-8
198 600 393210 0 3 2 2 0 - 1 - 60.0 2.5 65 54 XXX 1-2-7-8
Current flow indication (l/h or m³/h) is calculated based on volume pulses/10 s (see paragraph 6.5)
MULTICAL® 801
Kamstrup A/S · Technical Description · 5512-571_R1_GB _11.2016
19
3.3.4 CCC-codes for ULTRAFLOW
type 65-R/S/T
Number of decimals in display
CCC
No.
Pre-
count
er
Flow
factor
kWh
MWh
Gcal
GJ m³
[tons]
l/h m³/h kW MW Imp./l
qp
[m³/h]
Type No. Flow
sensor
116 3000 78642 0 3 2 2 0 1 300 0.6 65-X-CAAA-XXX
65-X-CAAD-XXX
1-2-7-8-N
119 1000 235926 0 3 2 2 0 1 100 1.5 65-X-CDAC-XXX
65-X-CDAD-XXX
65-X-CDAE-XXX
65-X-CDAF-XXX
65-X-CDAA-XXX
1-2-7-8-N
136 500 471852 0 3 2 2 0 1 50.0 3.0 65-X-CFAF-XXX
65-X-CFBA-XXX
1-2-7-8-N
151 5000 471852 2 1 1 0 1 50.0 3.5 65-X-CGAG-XXX
65-X-CGBB-XXX
1-2-7-8-N
137 2500 943704 2 1 1 0 1 25.0 6
6
10
10
65-X-CHAG-XXX
65-X-CHBB-XXX
65-X-C1AJ-XXX
65-X-C1BD-XXX
1-2-7-8-N
178 1500 1572840 2 1 1 0 1 15.0 10 65-X-CJAJ-XXX
65-X-CJBD-XXX
1-2-7-8-N
120 1000 2359260 2 1 1 0 1 10.0 15 65-X-CKBE-XXX 1-2-7-8-N
179 600 3932100 2 1 1 0 1 6.0 25 65-X-CLBG-XXX 1-2-7-8-N
120
1000
2359260
2 1 1 0 1 10.0
25
65-X-C2BG-XXX
1-2-7-8-N
158 5000 471852 1 0 0 2 0 5.0 40
65-X-CMBH-
XXX
1-2-7-8-N
170 2500 943704 1 0 0 2 3 2.5 60 65-X-FABL-XXX
65-X-FACL-XXX
1-2-7-8-N
180 1500 1572840 1 0 0 2 3 1.5 100 65-X-FBCL-XXX 1-2-7-8-N
147 1000 2359260 1 0 0 2 3 1.0 150 65-X-FCBN-XXX
65-X-FCCN-XXX
1-2-7-8-N
181 600 3932100 1 0 0 2 3 0.6 250 65-X-FDCN-XXX 1-2-7-8-N
191 400 589815 1 0 0 1 2 0.4 400 65-X-FEBN-XXX
65-X-FEBR-XXX
65-X-FECN-XXX
65-X-FECP-XXX
65-X-FECR-XXX
1-2-7-8-N
192 250 943704 1 0 0 1 2 0.25 600
600
1000
1000
65-X-FFCP-XXX
65-X-FFCR-XXX
65-X-F1BR-XXX
65-X-F1CR-XXX
1-2-7-8-N
193 150 1572840 1 0 0 1 2 0.15 1000 65-X-FGBR-XXX 1-2-7-8-N
Current flow indication (l/h or m³/h) is calculated based on volume pulses/10 s (see paragraph 6.5)
MULTICAL® 801
20
Kamstrup A/S · Technical Description · 5512-571_R1_GB_11_2016
3.3.5 High-resolution CCC-codes for ULTRAFLOW
(for cooling meters etc.)
Number of decimals in display
CCC
No.
Pre-
count
er
Flow
factor
kWh
MWh
Gcal
GJ m³
[tons]
l/h m³/h kW MW Imp./l
qp
[m³/h]
Type No. Flow
sensor
184 300 78642 1 3 3 0 1 300 0.6 1-2-7-8
107 100 235926 1 3 3 0 1 100 1.5 1-2-7-8-N
136 500 471852 0 3 2 2 0 1 50.0 3.5 1-2-7-8-N
138 250 943704 0 3 2 2 0 1 25.0 6.0
10
1-2-7-8-N
183 150 1572840 0 3 2 2 0 1 15.0 10 1-2-7-8
185 100 2359260 0 3 2 2 0 1 10.0 15 1-2-7-8-N
186 500 471852 2 1 1 2 0 5.0 40 1-2-7-8-N
187 250 943704 2 1 1 2 3 2.5 60 1-2-7-8-N
188 150 1572840 2 1 1 2 3 1.5 100 1-2-7-8
189 100 2359260 2 1 1 2 3 1.0 150 1-2-7-8-N
191 400 589815 1 0 0 1 2 0.4 400 1-2-7-8-N
192 250 943704 1 0 0 1 2 0.25 600
1000
1-2-7-8-N
193 150 1572840 1 0 0 1 2 0.15 1000 1-2-7-8
Current flow indication (l/h or m³/h) is calculated based on volume pulses/10 s (see paragraph 6.5)
MULTICAL® 801
Kamstrup A/S · Technical Description · 5512-571_R1_GB _11.2016
21
3.3.6 CCC-codes for other electronic meters with passive or active output
Number of decimals in display
CCC
No.
Pre-
counter
Flow factor MWh
Gcal
GJ m³
[tons]
m³/h kW MW l/imp Imp./l
Qmax
[m³/h]
Type Flow
sensor
147 1000 2359260 1 0 0 2 3 1 - 18...75 SC-18
N
148 400 5898150 1 0 0 2 3 2.5 - 120…300 SC-120
N
149 100 2359260 1 0 0 1 - 2 10 - 450…1200 SC-450
N
150 20 11796300 1 0 0 1 - 2 50 - 1800…3000 SC-1800
N
175 7500 314568 1 0 0 2 3 - 7.5 15…30 DF-15
N
176 4500 524280 1 0 0 2 3 - 4.5 25…50 DF-25
N
177 2500 943704 1 0 0 2 3 - 2.5 40…80 DF-40
N
Number of decimals in display
CCC
No.
Pre-
counter
Flow factor MWh
Gcal
GJ m³
[tons]
m³/h MW l/imp Imp./l
Qp range
[m³/h]
Qs
[m³/h]
Type Flow
sensor
201 100 235926 2 1 1 1 2 1 1 10…100
75 FUS380
DN50-65
N
202 40 589815 2 1 1 1 2 2.5 0.4 40…200
240 FUS380
DN80-100
N
203 400 589815 1 0 0 1 2 2.5 0.4 100…400
500 FUS380
DN125
N
204 100 235926 1 0 0 0 1 10 0.1 150…1200 1600 FUS380
DN150-250
N
205 20 1179630 1 0 0 0 1 50 0.02 500…3000 3600 FUS380
DN300-400
N
206 100 2359260 0 x10
*)
x10
*)
0 1 100 0.01 1400…18000 36000 FUS380
DN5001200
N
Current flow indication (l/h or m³/h) is calculated based on volume pulses/10 s (see paragraph 6.5)
*) Under this CCC code, the count will display the seven most significant digtes, followed by “0”
MULTICAL® 801
22
Kamstrup A/S · Technical Description · 5512-571_R1_GB_11_2016
3.3.7 CCC-codes for vane-wheel meters with electronic pick-up
Number of decimals in display
CCC
No.
Pre-
count
er
Flow factor
kW
h
MWh
Gcal
GJ m³
[tons]
l/h m³/h kW MW Imp./l
qp
[m³/h]
Type Flow
sensor
108 1403 168158 0 3 2 2 0 1 140.3 0.6 GWF
N
109 957 246527 0 3 2 2 0 1 95.7 1.0 GWF
N
110 646 365211 0 3 2 2 0 1 64.6 1.5 GWF
N
111 404 583975 0 3 2 2 0 1 40.4 1.5 (2.5) HM (GWF)
N
112 502 469972 0 3 2 2 0 1 50.2 1.5 – 2.5* GWF
N
113 2350 1003940 2 1 1 0 1 23.5 3.5 - 6* GWF
N
114 712 331357 2 1 1 0 1 7.12 10 - 15* GWF
N
115 757 311659 0 3 2 2 0 1 75.7 1.0* GWF
N
116 3000 78642 0 3 2 2 0 1 300.0 0.6* GWF
N
117 269 877048 0 3 2 2 0 1 26.9 1.5 Brunata
N
118 665 354776 0 3 2 2 0 1 66.5 1.5 Aquastar
N
119 1000 235926 0 3 2 2 0 1 100.0 0.6 HM
N
121
294
802469
0 3 2 2 0 1 29.4
1.5 – 2.5
N
122 1668 141442 0 3 2 2 0 1 166.8 0.6 HM
N
123 864 273063 0 3 2 2 0 1 86. 0.5 - 1* HM
N
124 522 451966 0 3 2 2 0 1 52. 2. (1.5*) CG (HM)
N
125 607 388675 0 3 2 2 0 1 60.7 1.5 - 1*
1.5*
HM
N
126 420 561729 0 3 2 2 0 1 42.0 1.0 (2.5*) CG (HM)
N
127 2982 791167 2 1 1 0 1 29.82 2.5
3.5*
HM
N
128 2424 973292 2 1 1 0 1 24.24 3.5* HM
N
129 1854 1272524 2 1 1 0 1 18.54 6* HM
N
130 770 3063974 2 1 1 0 1 7.7 10* HM
N
131 700 3370371 2 1 1 0 1 7.0 15* HM
N
132 365 645665 0 3 2 2 0 1 36.54 2.5 Wehrle
N
133 604 390154 0 3 2 2 0 1 60.47 1.5 Wehrle
N
134 1230 191732 0 3 2 2 0 1 123.05 0.6 Wehrle
N
135 1600 1474538 2 1 1 0 1 16.0 10* HM
N
139 256 921586 0 3 2 2 0 1 25.6 1.5 – 2.5 GWF
N
140 1280 1843172 2 1 1 0 1 12.8 3.5 – 5.0 GWF
N
141 1140 2069526 2 1 1 0 1 11.4 6 GWF
N
142 400 589815 2 1 1 2 3 4 10 GWF
N
143 320 737269 2 1 1 2 3 3.2 10 - 15 GWF
N
144 1280 1843172 1 0 0 2 3 1.28 25 - 40 GWF
N
145 640 3686344 1 0 0 2 3 0.64 60 GWF
N
146 128 18431719 1 0 0 2 3 0.128 125 GWF
N
152 1194 1975930 2 1 1 0 1 11.94 10 GWF
N
153 1014 2326686 2 1 1 0 1 10.14 15 GWF
N
156 594 397182 0 3 2 2 0 1 59.4 1.5 Metron
N
157 3764 626796 2 1 1 0 1 37.64 2.5 Metron
N
163 1224 192750 0 3 2 2 0 1 122.4 0.6 – 1.0 GWF/U2
N
164
852
280064
0 3 2 2 0 1 85.24
1.5
GWF/U2
N
165 599 393735 0 3 2 2 0 1 59.92 2.5 GWF/U2
N
168 449 5259161 2 1 1 0 1 4.486 15/25 HM/WS
N
169 1386 1702208 1 0 0 2 0 1.386 40 HM/WS
N
173 500 471852 1 0 0 1 2 0.5 80 Westland
N
Current flow indication (l/h or m³/h) is calculated based on volume pulses/10 s (see paragraph 6.5)
* Multiple-jet water meter
MULTICAL® 801
Kamstrup A/S · Technical Description · 5512-571_R1_GB _11.2016
23
3.3.8 CCC-codes for mechanical flow sensors with reed contact
Number of decimals in display
CCC
No.
Pre-
count
er
Flow
factor
kWh
MWh
Gcal
GJ m³
[tons]
m³/h l/h kW MW l/imp Imp./l
Qmax
[m³/h]
Flow
sensor
010 1 921600 1 - 3 3 - 0 1 - 1 1
≤ 3,0
L
011 1 921600 - 3 2 2 2 0 - 10 0.1 1…30
L
012 1 921600 - 2 1 1 1 - 2 100 0.01 10…300
L
013 1 921600 - 1 0 0 0 - 1 1000 0.001 100…3000
L
020 4 230400 0 3 2 2 2 0 - 2.5 0.4
≤ 6
L
021 4 230400 - 2 1 1 1 - 2 25 0.04 3…60
L
022 4 230400 - 1 0 0 0 - 1 250 0.004 30…600
L
Current flow indication (l/h or m³/h) is calculated based on measured duration between two volume pulses.
(see paragraph 6.5)
Selecting one of the above-mentioned CCC-codes, both CCC (V1) and CCC (V2) must be selected from this table.
Note: CCC=9XX cannot be used for MULTICAL
®
801, but only for MULTICAL® 602.
Note: Continuous maximum water flow and permanent ∆Θ > 75 K may cause overflow in the daily data logger at
CCC=010-011-012-013-150-202-205-206. With these combinations, we recommend you to use the built Prog.
data logger.
MULTICAL® 801
24
Kamstrup A/S · Technical Description · 5512-571_R1_GB_11_2016
3.4 Display coding
Display code ”DDD” indicates the active readings of each meter type. ”1” is the first primary reading, whereas e.g.
”1A” is the first secondary reading. The display automatically returns to reading ”1” after 4 minutes.
Date Stamp
Heat meter
DDD=210 Heat meter
DDD=410 Cooling meter
DDD=510 Heat/cooling
DDD=610 Heat volume
DDD=710 Coolingvolume
DDD=810 Heat meter
DDD=910
1.0
Heat energy (E1)
1
1 1
1
1.1
Yearly data
•
1A
1A 1A
1.2
Monthly data
•
1B
1B 1B
1A
2.0
Cooling energy (E3)
1
2
2.1
Yearly data
•
1A
2A
2.2
Monthly data
•
1B
2B
3.X
3.1
E2
3.2
E4
2
3.3
E5 2A
3.4
E6 2B
3.5
E7 2C
3.6
E8 (m3*tf)
2
2
3.7
E9 (m3*tr)
2A
2A
4.0
Volume V1
3 3 2 3 1 1 3
4.1
Yearly data
•
3A
3A
2A
3A
1A
1A
4.2
Monthly data
•
3B
3B
2B
3B
1B
1B
3A
4.3
Mass 1 3B
4.4
P1 3C
5.0
Volume V2
4
5.1
Yearly data
•
5.2
Monthly data
•
4A
5.3
Mass 2 4B
5.4
P2 4C
6.0
Hour counter
4 4 3 4 2 2 5
7.0
T1 (Inlet)
5 5 4
5
6
7.1
Year-to-date average
5A
5A
4A
5A
7.2
Month-to-date average
5B
5B
4B
5B
8.0
T2 (Outlet)
6 6 5
6
7
8.1
Year-to-date average
6A
6A
5A
6A
8.2
Month-to-date average
6B
6B
5B
6B
9.0
T1-T2 (∆t) - = cooling
7 7 6
7
8
10.0
T3
9
11.0
T4 (prog.)
10
12.0
Flow (V1)
8 8 7 8 3 3 11
12.1
This year’s max.
•
8A
8A
7A
8A
3A
3A
12.2
Max. yearly data
•
12.3
This year’s min.
•
12.4
Min. yearly data
•
12.5
This month’s max.
•
12.6
Max. monthly data
•
8B
8B
7B
8B
3B
3B
11A
12.7
This month’s min.
•
12.8
Min. monthly data
•
8C
8C
7C
8C
3C
3C
11B
13.0
Flow (V2)
9
9
4 4 12
14.0
Power (V1)
10
10 8 9
13
14.1
This year’s max.
•
10A
10A
8A
9A
14.2
Max. yearly data
•
14.3
This year’s min.
•
14.4
Min. yearly data
•
14.5
This month’s max.
•
14.6
Max. monthly data
•
10B
10B
8B
9B
14.7
This month’s min.
•
14.8
Min. monthly data
•
10C
10C
8C
9C
MULTICAL® 801
Kamstrup A/S · Technical Description · 5512-571_R1_GB _11.2016
25
Date Stamp
Heat meter
DDD=210 Heat meter
DDD=410
Cooling meter
DDD=510 Heat/cooling
DDD=610 Heatvolume
DDD=710 Coolingvolume
DDD=810 Heat meter
DDD=910
15.0
VA (Input A)
11
11 9 10 5 5
14
15.1
Meter No. VA
11A
11A
9A
10A
5A
5A
14A
15.2
Yearly data
•
11B
11B
9B
10B
5B
5B
14B
15.3
Monthly data
•
11C
11C
9C
10C
5C
5C
14C
16.0
VB (Input B)
12
12
10
11 6 6
15
16.1
Meter No. VB
12A
12A
10A
11A
6A
6A
15A
16.2
Yearly data
•
12B
12B
10B
11B
6B
6B
15B
16.3
Monthly data
•
12C
12C
10C
11C
6C
6C
15C
17.0
TA2
13
13 12
17.1
TL2 13A
13A
18.0
TA3
14
14 13
18.1
TL3 13A
13A
19.0
Info Code
15
15
11
14 7 7
16
19.1
Info event counter
15A
15A
11A
14A
7A
7A
16A
19.2
Info logger (latest 36 events)
•
15B
15B
11B
14B
7B
7B
16B
20.0
Customer No.
(No 1+2)
16
16
12
15 8 8
17
20.1
Date
16A
16A
12A
15A
8A
8A
17A
20.2
Hour 16B
16B
12B
15B
8B
8B
17B
20.3
Target date
16C
16C
12C
15C
8C
8C
17C
20.4
Serial no. (No 3)
16D
16D
12D
15D
8D
8D
17D
20.5
Prog. (A-B-CCC-CCC) (No 4)
16E
16E
12E
15E
8E
8E
17E
20.6
Config 1 (DDD-EE) (No 5)
16F
16F
12F
15F
8F
8F
17F
20.7
Config 2 (FF-GG-M-N) (No 6)
16G
16G
12G
15G
8G
8G
17G
20.8
Software edition (No 10)
16H
16H
12H
15H
8H
8H
17H
20.9
Software check sum (No 11)
16I
16I
12I
15I
8I
8I
17I
20.10
Segment test
16J
16J
12J
15J
8J
8J
17J
20.14
Module type 1 (No 30)
16K
16K
12K
15K
8K
8K
17K
20.15
Module 1 primary adr. (No 31)
16L
16L
12L
15L
8L
8L
17L
20.16
Module 1 secondary adr. (No32)
16M
16M
12M
15M
8M
8M
17M
20.17
Module type 2 (No40)
16N
16N
12N
15N
8N
8N
17N
20.18
Module 2 primary adr. (No41)
16O
16O
12O
15O
8O
8O
17O
20.19
Module 2 secondary adr. (No42)
16P
16P
12P
15P
8P
8P
17P
20.20
Module external type (No50)
16Q
16Q
12Q
15Q
8Q
8Q
17Q
20.21
Module external prim. add. (No51)
16R
16R
12R
15R
8R
8R
17R
20.22
Module secondary add. (No52)
16S
16S
12S
15S
8S
8S
17S Number of yearly data displayed (1…15)
2 2 2 2 2 2
2
Number of monthly data displayed (1…36)
12
12
12
12
12
12
12
DDD=210 is the ”standard code” of heat meters with meter type 67xxxxxxx2xx. Please contact Kamstrup for
other combinations. A DDD-code can contain max. 103 readings, including 4 data logger readings. Top module no.
and base module no. to be left out of account.
A complete overview of existing display codes (DDD) appears from a separate document (5512-593).
Please contact Kamstrup for further details.
Note: One data reading can collect up to 36 monthly data and up to 15 yearly data. The number of yearly and
monthly data that can be displayed is determined by the DDD-code.
MULTICAL® 801
26
Kamstrup A/S · Technical Description · 5512-571_R1_GB_11_2016
3.4.1 Energy overview
The above-mentioned energy types E1 to E9 are calculated as follows:
Formula
∆Θ
Example of an application
Included in Application No.
(see paragraph 6.2)
Register type
E1=V1(T1-T2)k
T1: Inlet / T2: Outlet
T1 > T2 Heat energy (V1 in inlet or outlet pipe) 1+2+3+4+5+6+8 Legal Display/Data/Log
E2=V2(T1-T2)k
T2: Outle t
T1 > T2 Heat energy (V2 in outlet pipe) 2+7
Display/Data/Log
E3=V1(T2-T1)k
T2: Inlet / T1: Outlet
T2 > T1 Cooling energy (V1 in inlet or outlet pipe) 1+10 Legal Display/Data/Log
E4=V1(T1-T3)k
T1: Inlet
T1 > T3 Forwarded energy 7+9+10 Display/Data/Log
E5=V2(T2-T3)k
T2: Inlet
T2 > T3 Returned energy or tap from outlet pipe 5+7+9 Display/Data/Log
E6=V2(T3-T4)k
T3: Inlet
T3 > T4 Tap water energy, separate 3+6
Display/Data/Log
E7=V2(T1-T3)k
T3: Outlet
T1 > T3 Returned energy or tap from inlet pipe 4+8
Display/Data/Log
E8=m3 x T1 - Average temperature in inlet pipe
See paragraph 6.2.2
Display/Data/Log
E9=m3 x T2 - Average temperature in outlet pipe Display/Data/Log
3.5 >EE< Configuration of MULTI-TARIFF
MULTICAL® 801 has 2 extra registers, TA2 and TA3, which can accumulate heat energy E1 (EE=20 accumulates
volume) parallel with the main register based on the limits programmed for tariff limits TL2 and TL3.
Example: EE=11 (Power tariff)
TA2 shows energy consumed…
…above the power limit TL2
EE= TARIFF TYPE FUNCTION
Delivery code 2xx
Delivery code 4xx
Delivery code 5xx
Delivery code 6xx
Delivery code 7xx
Delivery code 8xx
Delivery code 9xx
00 No active tariff
No function
11
Power tariff
Energy is accumulated in TA2 and TA3 based on the power limits
in TL2 and TL3.
• •
12
Flow tariff
Energy is accumulated in TA2 and TA3 based on the flow limits in
TL2 and TL3.
• •
13
T1-T2 tariff
Energy is accumulated in TA2 and TA3 based on the ∆t-limits in
TL2 and TL3.
• •
14
Inlet temperature tariff
Energy is accumulated in TA2 and TA3 based on the tF-limits in TL2
and TL3.
• •
15
Outlet temperature tariff
Energy is accumulated in TA2 and TA3 based on the tR-limits in
TL2 and TL3.
• •
19
Time controlled tariff
TL2=Start time for TA2
TL3=Start time for TA3
• •
20
Heat/cooling volume tariff
(TL2 and TL3 are not used)
Volume (V1) is divided into TA2 for heat (T1>T2) and TA3 for
cooling (T1<T2). (Recommended for heat/cooling applications)
• • •
21
PQ-tariff
Energy if P>TL2 is saved in TA2 and energy if Q>TL3 is saved in TA3 • •
See paragraph 6.9 for further details on the tariff registers.
MULTICAL® 801
Kamstrup A/S · Technical Description · 5512-571_R1_GB _11.2016
27
3.6 >FF< Input A (VA), pulse division >GG< Input B (VB), pulse division
MULTICAL
®
801 has 2 pulse inputs, VA and VB, which are placed on base module 1 (see paragraph 7.2 for further
details). The inputs are individually configured via the FF and GG codes as shown in the table below.
In the absence of other information from the customer the inputs will be configured as FF=24 and GG=24.
Input A
Terminal 65-66
Input B
Terminal 67-68
FF
Max. input
f ≤1Hz
GG
Max. input
f ≤1 Hz
Precounter Wh/imp l/imp
Measuring unit anddecimal
point
01 100 m³ h
01 100 m³ h
1 - 100 vol A/vol b (m3) 000000.0
02 50 m³ h
02 50 m³ h
2 - 50 vol A/vol b (m3)
000000,0
03 25 m³ h
03 25 m³ h
4 - 25 vol A/vol b (m3) 000000.0
04 10 m³ h
04 10 m³ h
10 - 10 vol A/vol b (m3) 000000.0
05 5 m³ h
05 5 m³ h
20 - 5.0 vol A/vol b (m3) 000000.0
06
2.5 m³ h
06
2.5 m³ h
40 - 2.5 vol A/vol b (m3) 000000.0
07
1 m³ h
07
1 m³ h
100 - 1.0 vol A/vol b (m3) 000000.0
24
10 m³ h
24
10 m³ h
1 - 10
vol A/vol b (m
3
)
00000.00
25
5 m³ h
25
5 m³ h
2 - 5.0
vol A/vol b (m3)
00000.00
26
2.5 m³ h
26
2.5 m³ h
4 - 2.5
vol A/vol b (m3)
00000.00
27
1 m³ h
27
1 m³ h
10 - 1,0
vol A/vol b (m3)
00000,00
40
1,000 m³ h
40
1,000 m³ h
1
-
1000
vol A/vol b (m3)
0000000
FF
Max. Input
f ≤3 Hz
GG
Max. Input
f ≤3 Hz
Precounter Wh/imp l/imp
Measuring unit anddecimal
position
50 2500 kW
50 2500 kW
1 1000 - EL A/EL b (kWh) 0000000
51 150 kW
51 150 kW
60 16.67 - EL A/EL b (kWh) 0000000
52 120 kW
52 120 kW
75 13.33 - EL A/EL b (kWh) 0000000
53 75 kW
53 75 kW
120 8.333 - EL A/EL b (kWh) 0000000
54 30 kW
54 30 kW
240 4.167 - EL A/EL b (kWh) 0000000
55 25 kW
55 25 kW
340 2.941 - EL A/EL b (kWh) 0000000
56 20 kW
56 20 kW
480 2.083 - EL A/EL b (kWh) 0000000
57 15 kW
57 15 kW
600 1.667 - EL A/EL b (kWh) 0000000
58 7.5 kW
58 7.5 kW
1000 1.000 - EL A/EL b (kWh) 0000000
59 750 kW
59 750 kW
10 100 - EL A/EL b (kWh) 0000000
60 1250 kW
60 1250 kW
2 500 - EL A/EL b (kWh) 0000000
61 75 kW
61 75 kW
100 10.00 - EL A/EL b (kWh) 0000000
62
15 kW
62
15 kW
500 2.000 - EL A/EL b (kWh) 0000000
70
25000 kW
70
25000 kW
1
10000
-
EL A/EL b (MWh)
00000.00
MULTICAL® 801
28
Kamstrup A/S · Technical Description · 5512-571_R1_GB_11_2016
3.7 >MN< Configuration of leak limits
When MULTICAL 801 is used for leak surveillance, the sensitivity is determined by the configuration of ”M-N”.
District heating leak surveillance (V1-V2)
Cold water leak surveillance (VA)
M=
Sensivity of leak search
N=
Constant leakage at no consumption (pulse
resolution 10 l/imp)
0
OFF 0 OFF 1 1.0 % qp + 20 % q
1
20 l/h 3x10 min. (30 min. without pulses)
2
1.0 % qp + 10 % q
2
10 l/h 6x10 min. (1 hour without pulses)
3
0.5 % qp + 20 % q
3
5 l/h 12x10 min. (2 hours without pulses)
4
0.5 % qp + 10 % q
Note: M=2 and N=2 are default values when leak surveillance is used. Increased sensitivity, e.g. M=4, can only be
achieved using METERTOOL.
Info codes for leakage/burst are only active when M
> 0 or N > 0 respectively.
MULTICAL® 801
Kamstrup A/S · Technical Description · 5512-571_R1_GB _11.2016
29
3.8 Data for configuration
Automatic
To be stated when ordering
Default
Serial no. (S/N) and year
E.g. 5300000/2009
-
-
Customer No.
Display No. 1 = 8 digits MSD
Display No. 2 = 8 digits LSD
- Up to 16 digits
Limited to 11 digits
depending on PcBase
compatibility
Customer number = S/N
Target date
-
MM=1-12 and DD=1-28
Depends on delivery code
TL2 - 5 digits
0
TL3 - 5 digits
0
Average peak time
-
1…1,440 min
60 min.
Max. T1 for cooling metering
-
0.01…180 °C
25 °C at DDD=5xx and 6xx
T2 prog.
0.01…180 °C
-
T3 prog.
0.01…180 °C
5 °C
T4 prog.
0.01…180 °C
0 °C
0°C
YYYY.MM.DD/hh.mm.ss
GMT+offset according to
country code
GMT ± 12.0 hours
(30 min. in leaps)
-
Data registers for configuration of modules and functions
qp [l/h]
from CCC-table
- - Valve travel
-
20…500 s
300 s
Hysteresis
-
0.5…5 s
0.5 s
Primary data addr.
Secondary data addr.
Baud rate
Reserved
Reserved
Reserved
….. Reserved
Reserved: These registers are prepared for later extensions of the functionality of the modules. Therefore, they have
no actual designations yet.
-COUNTRY CODES
Information on country codes see 55 14-170
- MAINTENANCE
See instructions no. 55 08-709 concerning update of programming and configuration.
MULTICAL® 801
30
Kamstrup A/S · Technical Description · 5512-571_R1_GB_11_2016
4 Dimensioned sketches
Front measurements of MULTICAL
®
801 Installation measurements of MULTICAL® 801
Wallmounted MULTICAL
®
801 seen from the side Cable unions of MULTICAL® 801
All measurements in [mm]
MULTICAL® 801
Kamstrup A/S · Technical Description · 5512-571_R1_GB _11.2016
31
5 Installation
5.1 Mounting in inlet or outlet pipe
Prog. number
A
MULTICAL® 801 is programmed for flow meter mounted in either inlet
or
outlet pipe. The table below indicates installation conditions for:
♦ Heat meters
♦ Cooling meters
♦ Heat/cooling meters
Flow sensor position
k-factor
table
- Inlet (at T1)
3
- Outlet (at T2)
4
Formula
k-factor
Prog.
Hot
pipe
Cold
pipe
Installation:
Heat meter
E1=V1(T1-T2)k
k-factor for
T1 in
Inlet table
A=3 (Flow
sensor in
inlet pipe)
V1 and
T1
T2
k-factor for
T2 in
Outlet table
A=4 (Flow
sensor in
outlet pipe)
T1
V1 and
T2
Cooling meter
E3=V1(T2-T1)k
k-factor for
T1 in
Outlet table
A=3 (Flow
sensor in
inlet pipe)
T2
V1 and
T1
k-factor for
T2 in
Inlet table
A=4 (Flow
sensor in
outlet pipe)
V1 and
T2
T1
MULTICAL® 801
32
Kamstrup A/S · Technical Description · 5512-571_R1_GB_11_2016
5.2 EMC conditions
MULTICAL® 801 has been designed and CE-marked according to EN 1434 Class A and Class C (corresponding to
Electromagnetic environment: Class E1 and E2 of the Measuring Instruments Directive) and can thus be installed
in both domestic and industrial environments.
All control cables must be drawn separately and not
parallel to e.g. power cables or other cables with the risk of
inducing electromagnetic interference. There must be a distance of min. 25 cm between signal cables and other
installations.
5.3 Climatic conditions
MULTICAL® 801 has been designed and approved for indoor installation in non-condensing environments with
ambient temperatures from 5…55°C.
Furthermore, MULTICAL
®
801 can also be installed in unheated rooms as the instrument is protected by self-
heating.
Protection class IP67 allows short-term submergence, provided that all cable unions have been correctly mounted
and that the plastic cover has been properly fastened.
5.4 Electrical installations
See paragraph 10
5.5 Terminal Overview
MULTICAL® 801 has many connection options. The terminals are placed at the bottom of the meter. Additional
information can be found in Section 7 (Flow Meter Connection), Section 8 (Temperature Sensors) and Section 9
(Other connections).
MULTICAL® 801
Kamstrup A/S · Technical Description · 5512-571_R1_GB _11.2016
33
6 Calculator functions
6.1 Energy calculation
MULTICAL 801 calculates energy based on the formula stated in EN 1434-1:2007, which uses the international
temperature scale issued in 1990 (ITS-90) and the pressure definition of 16 bar.
In a simplified form, the energy calculation can be expressed as Energy = V x ∆Θ x k.
The calculator always calculates energy in [Wh], and then converts the value to the selected measuring unit.
E [Wh] =
V x ∆Θ x k x 1000
E [kWh] = E [Wh] / 1,000
E [MWh] =
E [Wh] / 1,000,000
E [GJ] =
E [Wh] / 277,780
E [Gcal] =
E [Wh] / 1,163,100
V is the added (or simulated) water volume in m
3
. If e.g. the CCC-code = 119 is used, the calculator has been
programmed to receive 100 imp./litre. If for instance 10,000 pulses are added, this corresponds to
10,000/100 = 100 litres or 0.1 m
3
.
∆Θ
is he measured temperature difference, e.g. ∆Θ = inlet temperature – outlet temperature. Please note that
different temperatures are used for the calculation of ∆Θ as MULTICAL
801 can calculate various different
energy types. Both in the display and during data reading each energy type is uniquely defined, e.g.
Heat energy: E1 = V1(T1-T2)k
Cooling energy: E3 = V1 (T2-T1)k
k is the heat coefficient of water which is calculated on the basis of the formula stated in EN 1434-1:2007
(identical with the energy formula of OIML R75-1:2002). For checking the measurement, Kamstrup can
supply an energy calculator:
MULTICAL® 801
34
Kamstrup A/S · Technical Description · 5512-571_R1_GB_11_2016
6.2 Application types
MULTICAL 801 operates with 9 different energy formulas, E1…E9, which are all calculated parallel with each
integration, no matter how the meter is configured.
Formula
∆Θ
Example of an application Included in Application No. Register type
E1=V1(T1-T2)k
T1: Inlet / T2: Outlet
T1 > T2 Heat energy (V1 in inlet or outlet pipe) 1+2+3+4+5+6+8 Legal Display/Data/Log
E2=V2(T1-T2)k
T2: Outle t
T1 > T2 Heat energy (V2 in outlet pipe) 2+7
Display/Data/Log
E3=V1(T2-T1)k
T2: Inlet / T1: Outlet
T2 > T1 Cooling energy (V1 in inlet or outlet pipe) 1+10 Legal Display/Data/Log
E4=V1(T1-T3)k
T1: Inlet
T1 > T3 Forwarded energy 7+9+10
Display/Data/Log
E5=V2(T2-T3)k
T2: Inlet
T2 > T3 Returned energy or tap from outlet pipe 5+7+9 Display/Data/Log
E6=V2(T3-T4)k
T3: Inlet
T3 > T4 Tap water energy, separate 3+6 Display/Data/Log
E7=V2(T1-T3)k
T3: Outlet
T1 > T3 Returned energy or tap from inlet pipe 4+8 Display/Data/Log
E8=m3 x T1 - Average temperature in inlet pipe
See paragraph 6.2.2
Display/Data/Log
E9=m3 x T2 - Average temperature in outlet pipe Display/Data/Log
6.2.1 E1…E7
Energy types E1…E7 are described by application examples below.
Application no. 1
Closed thermal system with 1 flow meter
Heat energy: E1 = V1(T1-T2)k
T1:Inlet or T2:Outlet
Cooling energy: E3 = V1(T2-T1)k
T1:Inlet or T2:Outlet
Flow meter V1 is placed in inlet or outlet as selected
during PROG.
Mass: M1 = V1 (Kmass t1) or
Mass: M1 = V1 (Kmass t2) depending on Inlet/Outlet
programming.
Application no. 2
Closed thermal system with 2 identical flow meters
Billing energy: E1 = V1(T1-T2)k
T1:Inlet
Control energy: E2 = V2 (T1-T2)k
T2:Outlet
T3 can be used for checking the measurement of
either inlet for outlet temperature, but T3 is not used
for calculation.
Mass: M1 = V1 (Kmass t1)
Mass: M2 = V2 (Kmass t2)
MULTICAL® 801
Kamstrup A/S · Technical Description · 5512-571_R1_GB _11.2016
35
Application no. 3
2-string system with 2 flow meters
Heat energy: E1 = V1(T1-T2)k
T1:Inlet or T 2:Outlet
Tap water energy: E6 = V2 (T3-T4)k
T3:Inlet
T3 is measured or programmed
T4 is programmed
Flow meter V1 is placed in inlet or outlet as selected
during PROG.
Mass: M1 = V1 (Kmass t1) or
Mass: M1 = V1 (Kmass t2) depending on inlet/outlet
programming.Mass: M2 = V2 (Kmass t3)*
Application no. 4
2 heating circuits with joint inlet pipe
Heat energy #1: E1 = V1(T1-T2)k
T2:Outlet
Heat energy #2: E7 = V2(T1-T3)k
T3:Outlet
T3 is measured or programmed
Mass: M1 = V1 (Kmass t1)
Mass: M2 = V2 (Kmass t3)*
Application no. 5
Open system with tapping from outlet pipe
Heat energy: E1 = V1(T1-T2)k
T1:Inlet
Tap water energy: E5 = V2 (T2-T3)k
T2:Inlet
T3 is measured or programmed
Mass: M1 = V1 (Kmass t1)
Mass: M2 = V2 (Kmass t2)
MULTICAL® 801
36
Kamstrup A/S · Technical Description · 5512-571_R1_GB_11_2016
Application no. 6
Open system with separate flow meter for tapping
Heat energy: E1 = V1(T1-T2)k
T2:Outlet
Tap water energy: E6 = V2 (T3-T4)k
T3:Inlet
T3 is measured or programmed
T4 is programmed
Mass: M1 = V1 (Kmass t1)
Mass: M2 = V2 (Kmass t3)*
Application no. 7
Open system with 2 flow meters
Forwarded energy: E4 = V1 (T1-T3)k
T1:Inlet
Returned energy: E5 = V2 (T2-T3)k
T2:Inlet
(∆E = E4-E5 cannot be calculated by
MULTICAL® 801)
Heat energy: E2 = V2 (T1-T2)k
T2:Outlet
T3 is measured or programmed
Mass: M1 = V1 (Kmass t1)
Mass: M2 = V2 (Kmass t2)
Application no. 8
Hot water boiler with circulation
Total consumption E1 = V1(T1-T2)k
T2:Outlet
Circulated consumption: E7 = V2(T1-T3)k
T3:Outlet
MULTICAL® 801
Kamstrup A/S · Technical Description · 5512-571_R1_GB _11.2016
37
Application no. 9
2 cooling circuits with joint inlet pipe
Cooling energy #1: E4 = V1 (T1-T3)k
T1:Inlet
Cooling energy #2: E5 = V2 (T2-T3)k
T2:Inlet
Application no. 10
Two-stage boiler system with 1 flow meter
Boiler energy „B“: E3 = V1 (T2-T1)k
T1:Outlet
Boiler energy „A“: E4 = V1(T1-T3)k
T1:Inlet
* M2 = V2 (Kmass t3)* only with delivery codes (930…939)!
MULTICAL® 801
38
Kamstrup A/S · Technical Description · 5512-571_R1_GB_11_2016
6.2.2 E8 and E9
E8 and E9 are used as a basis for calculation of volume-based average temperatures in inlet and outlet pipes
respectively. With every integration (every 0.01 m
3
for qp 1.5 m3/h) the registers are accumulated by the product of
m
3
×
°C, which makes E8 and E9 a suitable basis for calculation of volume-based average temperatures.
E8 and E9 can be used for average calculation during any period as long as the volume register is read at the same
time as E8 and E9.
E8= m
3
×
tF E8 is accumulated by the product of m
3
×
tF
E9= m
3
×
tR E9 is accumulated by the product of m
3
×
tR
Resolution of E8 and E9
E8 and E9 depend on the resolution of volume (m
3
)
Volume resolution Resolution of E8 and E9
0000.001 m3
m
3
× °C × 10
00000.01 m3
m
3
× °C
000000.1 m3
m
3
× °C × 0,1
0000001 m3
m
3
× °C × 0,01
Example 1 After a year a heating installation has consumed 250.00 m
3
district heating water and the
average temperatures have been 95°C for inlet and 45°C for outlet.
E8 = 23750 and E9 = 11250.
Example 2 The average temperatures must be measured together with the yearly reading. Therefore, E8 and
E9 are included in the yearly reading.
Date of
reading
Volume E8
Average of inlet
pipe
E9
Average of
outlet pipe
2003.06.01
534.26 m3
48236
18654
2002.06.01
236.87 m3
20123
7651
Yearly
consumption
297.39 m3 28113
28113/297.39
= 94.53°C
11003
11003/297.39
= 36.99°C
Table 1
MULTICAL® 801
Kamstrup A/S · Technical Description · 5512-571_R1_GB _11.2016
39
6.3 Calculator with two flow sensors
MULTICAL 801 can be used in various applications with two flow sensors, e.g. leak surveillance or
open systems. When two ULTRAFLOW
are direct connected to one MULTICAL 801, a close electric
coupling between the two pipes ought to be carried out as a main rule. If the two pipes are installed in
a heat exchanger, close to the flow sensors, however, the heat exchanger will provide the necessary
electric coupling.
Electric coupling
• Inlet and outlet pipes are closely electrically coupled
• No welded joints occur
In installations where the electric coupling cannot be carried out, or where welding in the pipe system
can occur, the cable from one ULTRAFLOW
must be routed through a Pulse Transmitter with galvanic
separation before the cable enters MULTICAL
801.
• Inlet and outlet pipes are not necessarily closely coupled
• Electric welding
*)
can occur
*)
Electric welding must always be carried out with the earth pole closest to the welding point. Our factory
guarantee does not comprise damage to meters due to welding.
MULTICAL® 801
40
Kamstrup A/S · Technical Description · 5512-571_R1_GB_11_2016
6.4 Combined heat/cooling metering
MULTICAL® 801 is available as heat meter (meter type 2xx), cooling meter (meter type 5xx) or combined
heat/cooling meter (meter type 6xx).
Meter type
Heat meter, closed systems (MID)
2
Heat meter, closed systems
4
Cooling meter
5
Heat/cooling meter
6
Volume meter, hot water
7
Volume meter, cooling water
8
Energy meter, open systems
9
Delivery code (language on label etc.)
XX
If MULTICAL
®
801 has been supplied as a combined heat/cooling meter, heat energy (E1) is measured at
positive temperature difference (T1 > T2) whereas cooling energy (E3) is measured at negative
temperature difference (T2 > T1). Temperature sensor T1 (with a red type sign) must be installed in the
hydraulic inlet pipe whereas T2 is installed in the outlet pipe.
The temperature point “T1 limit” is used as a ”filter” for cooling measurement in the way that cooling is
only measured when the current inlet temperature T1 is below T1 limit.
T1 limit is configurable in the temperature range 0.01…180.00°C. T1 limit is configured via METERTOOL.
In combined heat/cooling meters T1 limit ought to correspond to the highest occurring inlet temperature
in connection with cooling, e.g. 25°C. If the meter is to be used for ”purchase and sale of heat”, T1 limit
is adjusted to 180.00°C, which cancels the T1 limit function.
The change between heat and cooling measurement involves no hysteresis (∆T1 limit = 0.00K).
MULTICAL® 801
Kamstrup A/S · Technical Description · 5512-571_R1_GB _11.2016
41
6.5 Flow measurement V1 and V2
MULTICAL 801 calculates current water flow according to two different principles depending on the connected flow
meter type:
•
Quick volume pulses (CCC > 100)
The current water flow for quick volume pulses, without average determination, is calculated as the number of
volume pulses per 10 s multiplied by the scaling factor.
q = (Imp./10 s x flow factor)/65535
[
l/h] or [m3/h]
Example:
- ULTRAFLOW qp 1.5 m
3
/h with 100 imp./l (CCC=119), flow factor = 235926
- Current water flow = 317 l/h, corresponding to 88 Imp./10 s
q = (88 x 235926)/65535 = 316.8, which is displayed as 316
[
l/h]
Current water flow in V1
•
Slow volume pulses (CCC = 0XX)
The current water flow of slow volume pulses (typically from flow meters with reed contact) is calculated without
average determination as a scaling factor divided by the duration between two volume pulses.
q = flow factor/(256 x period of time in s)
[
l/h] or [m3/h]
Example:
- Mechanical flow meter Qn 15 qp m
3
/h with 25 l/imp. (CCC=021), flow factor = 230400
- Current water flow = 2.5 m
3
/h, which corresponds to 36 s of the duration between 2 pulses
q = 230400 /(256 x 36) = 25 which is displayed as 2.5
[
l/h]
V1 and V2 must be the same type (either quick (CCC > 100) or slow (CCC=0XX)) but can have different qp-codings
(CCC).
The actual flow rate on the display will be shown a ”0”, when the period between pulses exceed 15 min.
MULTICAL® 801
42
Kamstrup A/S · Technical Description · 5512-571_R1_GB_11_2016
6.6 Power measurement, V1
MULTICAL 801 calculates current power based on the current water flow and the temperature difference measured
at the latest integration based on the following formula:
P = q (T1 – T2) x k
[kW]
or [MW]
”k” being the heat coefficient of water, which is currently calculated by MULTICAL
801 according to EN 1434:2007.
Example:
- Current water flow, q = 316 l/h and flow meter mounted in outlet pipe
- T1 = 70.00°C and T2 = 30.00°C, k-factor is calculated at 1.156 kWh/m
3
/K
P = 0.316 (70-30) x 1.156 = 14.6
[kW]
Current power in V1
Both heat and cooling power is displayed
numerically (without signs)
MULTICAL® 801
Kamstrup A/S · Technical Description · 5512-571_R1_GB _11.2016
43
6.7 Min. and max. flow and power, V1
MULTICAL 801 registers minimum and maximum flow and power on both monthly and yearly basis. The complete
registration can be read via data communication. Furthermore, a few monthly and yearly registers can be read from
the display, depending on the selected DDD-code.
The min. and max. registrations include the following flow and power values with indication of date:
Type of registration
Max. data Min. data Yearly data Monthly data
Max. this year (since latest target date)
•
•
Max. yearly data, up to latest 15 years
•
•
Min. this year (since latest target date)
• •
Min. yearly data, up to latest 15 years
• •
Max. this month (since latest target date)
•
•
Max. monthly data, up to latest 36 months
•
•
Min. this month (since latest target date)
•
•
Min. monthly data, up to latest 36 months
•
•
All max. and min. values are calculated as biggest and smallest average of a number of current flow or power
measurements respectively. The average period used for all calculations can be selected in the interval 1...1440
min. in 1 min. leaps. 1.440 min. = 24 hours).
Average period and target date must be stated in the order, or be reconfigured by means of METERTOOL. In the
absence of other information with the order, the average period is set to 60 min. and the target date to the standard
value applying to the delivery code used.
At the end of a year and a month the max. and min. values are saved in the data logger, and the current max. and
min. registers are “reset” according to the selected target date and the meter’s internal clock and calendar.
”Reset” is made by setting the max. value to zero and the min. value to 10000,0 kW at e.g. CCC=119.
If the max. or min. registration is used for accounting purposes, we recommend that the clock setting is checked in
connection with the installation as well as once a year. Furthermore, the back-up battery of MULTICAL
801 ought
to be replaced at intervals of max. 10 years.
Date of year-to-date max.
Value of year-to-date max.
Date of this month’s min.
Value of this month’s min.
MULTICAL® 801
44
Kamstrup A/S · Technical Description · 5512-571_R1_GB_11_2016
6.8 Temperature measurement
MULTICAL 801 is fitted with a high-resolution analog/digital converter, which measures the temperatures T1, T2
and T3 with a resolution of 0.01°C. The same measuring circuit is used for all three temperature inputs in order to
obtain the lowest possible measuring error of the temperature difference. Prior to each temperature measurement,
the internal measuring circuit is automatically adjusted based on built-in reference resistors at 0°C and 100°C
respectively. Very accurate measurements and an almost immeasurable long-term stability is hereby obtained.
Current T1
MULTICAL
801 measures all temperatures every 10 seconds if supply voltage is connected. If the supply voltage
is disconnected and the meter is driven by the backup battery, temperature measurements are carried out with
every integration (energy calculation), not at shorter intervals than 10 s however.
The temperature range of the measuring circuit is 0.00°C…185.00°C. For disconnected temperature sensor,
200.00°C is shown and for short-circuited temperature sensor 0.00°C is displayed. In both cases the info code for
sensor error will appear.
In order to reduce the influence of hum, which can e.g. be picked up in long sensor cables, double measurements
with a timing difference of half a period of time are carried out, and the average of the two measurements is the
temperature measurement used for calculation and the one displayed. The hum suppression is optimized to either
50 Hz or 60 Hz depending on the selected country code.
6.8.1 Measuring current and power
Measuring current is only sent through the temperature sensors during the short duration of the temperature
measurement. The effective power which is deposited in the sensor elements is thus very small, and its influence
on the self-heating of the temperature sensors is typically less than 1/1000 K.
Pt100 Pt500
Measuring current
< 3 mA
< 0.5 mA
Peak power
<
1.5 mW
<
0.2 mW
RMS influence
<
10 µW
<
1 µW
MULTICAL® 801
Kamstrup A/S · Technical Description · 5512-571_R1_GB _11.2016
45
6.8.2 Average temperatures
MULTICAL
801 currently calculates the average temperatures of inlet and outlet pipes (T1 and T2) in °C without
decimals, and the background calculations E8 and E9 (m
3
x T1 and m3 x T2) are carried out with every energy
calculation (e.g. with every 0.01 m
3
if the meter size is qp 1.5), whereas the display is updated every 24 hours. The
average temperatures are thereby volume weighted and can, therefore, be used for check purposes directly.
Type of registration
Average Yearly data Monthly data
Year-to-date average (since latest target date)
• •
Month-to-date average (since latest target date)
•
•
Year-to-date average for T1
(Current date with a stipulated line under year or
month is shown immediately BEFORE this reading)
6.8.3 Preprogrammed temperatures
Temperatures T3 and T4 can be programmed into the calculator’s memory, whereby these temperatures can be
used for energy calculation with fixed temperature reference, as used in the calculations of the energy types E4, E5,
E6 and E7 (see application drawings in paragraph 6.2)
The temperatures can be entered from the factory or by means of METERTOOL, in the range 0.01…180°C, after
installation.
MULTICAL® 801
46
Kamstrup A/S · Technical Description · 5512-571_R1_GB_11_2016
6.9 Display functions
MULTICAL 801 is fitted with an easily readable LC-display, including 8 digits, measuring units and information
field. For energy and volume indication 7 digits (8 digits, however, for programming the biggest flow meter types)
and the corresponding measuring units are used, whereas 8 digits are used for indication of e.g. meter number and
serial number.
Basically, accumulated energy is displayed. Activating the pushbuttons, the display reacts at once by calling up
other indications. The display automatically returns to energy indication 4 minutes after the latest activation of the
pushbuttons.
6.9.1 Primary and secondary indications
The top pushbutton is used to change between the primary indications. Consumers normally use the first primary
indications in connection with self-reading for billing purposes.
The bottom pushbutton is used to collect secondary information on the primary indication selected.
Example: If the selected primary indication is ”heat energy”, the secondary indications will be yearly data and
monthly data for heat energy.
MULTICAL® 801
Kamstrup A/S · Technical Description · 5512-571_R1_GB _11.2016
47
Heat energy E1 in MWh
Yearly data, date of LOG1 (latest yearly reading)
Yearly data, value of LOG1 (latest yearly reading)
Monthly data, date of LOG1 (latest monthly reading)
MULTICAL® 801
48
Kamstrup A/S · Technical Description · 5512-571_R1_GB_11_2016
6.9.2 Display structure
The below-mentioned diagram shows the display structure with up to 20 primary readings as well as a series of
secondary readings under most primary indications. The number of secondary readings in connection with yearly
and monthly data has been determined under the DDD-code. In the absence of other information with the order,
readings will consist of 2 yearly data and 12 monthly data. The target date will be the standard date applying to the
delivery code used.
As the display is configured to the customer’s need (selecting the DDD-code) the display will most frequently
include much fewer indications than listed below.
Figure 2
MULTICAL® 801
Kamstrup A/S · Technical Description · 5512-571_R1_GB _11.2016
49
6.9.3 Display grouping
MULTICAL
801 can be configured for many different applications, which creates the need for different display
groups. The table below includes possible
indications [•] of heat meters, cooling meters etc., indications
supported by date stamp as well as the indications, to which the display automatically reverts 4 min. after the latest
activation of the pushbuttons [1•]. (The paragraph is only used for creation of DDD-codes).
Date Stamp
Heat meter
DDD=4xx Cooling meter
DDD=5xx Heat/cooling
DDD=6xx Heatvolume
DDD=7xx Cold volume
DDD=8xx Heat meter
DDD=9xx
1.0
Heat energy (E1)
1 • 1 •
• 1.1
Yearly data
•
• •
•
1.2
Monthly data
•
• •
• 2.0
Cooling energy (E3)
1 •
•
• 2.1
Yearly data
• •
•
•
2.2
Monthly data
• •
•
•
• 3.X
Other energy types
3.1
E2 • 3.2
E4 • 3.3
E5
•
3.4
E6 • 3.5
E7
•
3.6
E8 (m3*tf)
•
• 3.7
E9 (m3*tr)
•
• 4.0
Volume V1
• • •
1 •
1 •
•
4.1
Yearly data
• • • • • • •
4.2
Monthly data
• • • • • • •
4.3
Mass 1
• • • • •
•
4.4
P1
• • • • •
•
5.0
Volume V2
• • •
5.1
Yearly data
•
• • •
5.2
Monthly data
•
• • •
5.3
Mass 2
• • •
5.4
P2
• • •
6.0
Hour counter
• • • • •
•
7.0
T1 (Inlet)
• • •
•
7.1
Year-to-date average
• • •
• 7.2
Month-to-date average
• • •
• 8.0
T2 (Outlet)
• • •
• 8.1
Year-to-date average
• • •
•
8.2
Month-to-date average
• • •
•
9.0
T1-T2 (∆t) - = cooling
• • •
•
10.0
T3
• • •
• 11.0
T4 (prog.)
•
12.0
Flow (V1)
• • • • •
•
12.1
This year’s max.
• • • • • • •
12.2
Max. yearly data
• • • • • • •
12.3
This year’s min.
• • • • • • •
12.4
Min. yearly data
• • • • • • •
12.5
This month’s max.
• • • • • • •
12.6
Max. monthly data
• • • • • • •
12.7
This month’s min.
• • • • • • •
12.8
Min. monthly data
• • • • • • •
13.0
Flow (V2)
•
• • •
14.0
Power (V1)
• • •
• 14.1
This year’s max.
• • •
•
•
14.2
Max. yearly data
• • •
•
• 14.3
This year’s min.
• • •
•
• 14.4
Min. yearly data
• • •
•
• 14.5
This month’s max.
• • •
•
• 14.6
Max. monthly data
• • •
•
•
14.7
This month’s min.
• • •
•
•
MULTICAL® 801
50
Kamstrup A/S · Technical Description · 5512-571_R1_GB_11_2016
14.8
Min. monthly data
• • •
•
•
Date Stamp
Heat meter
DDD=4xx Cooling meter
DDD=5xx Heat/cooling
DDD=6xx Heatvolume
DDD=7xx Cold volume
DDD=8xx Heat meter
DDD=9xx
15.0
VA (Input A)
• • • • •
•
15.1
Meter No. VA
• • • • •
•
15.2
Yearly data
• • • • • • •
15.3
Monthly data
• • • • • • •
16.0
VB (Input B)
• • • • •
•
16.1
Meter No. VB
• • • • •
•
16.2
Yearly data
• • • • • • •
16.3
Monthly data
• • • • • • •
17.0
TA2
• • •
17.1
TL2
•
•
18.0
TA3
• • •
18.1
TL3
•
•
19.0
Info Code
• • • • •
•
19.1
Info event counter
• • • • •
•
19.2
Info logger (36 latest events)
• • • • • • •
20.0
Customer No.
(No 1+2)
• • • • • •
20.1
Date
• • • • •
•
20.2
Hour
• • • • •
•
20.3
Target date
• • • • •
•
20.4
Serial no. (No 3)
• • • • •
•
20.5
Prog. (A-B-CCC-CCC) (No 4)
• • • • •
•
20.6
Config 1 (DDD-EE) (No 5)
• • • • •
•
20.7
Config 2 (FF-GG-M-N) (No 6)
• • • • •
•
20.8
Software edition (No 10)
• • • • •
•
20.9
Software check sum (No 11)
• • • • •
•
20.10
Segment test
• • • • •
•
20.14
Module type 1 (No 30)
• • • • •
•
20.15
Module 1 primary adr. (No 31)
• • • • •
•
20.16
Module 1 secondary adr. (No32)
• • • • •
•
20.17
Module type 2 (No40)
• • • • •
•
20.18
Module 2 primary adr. (No41)
• • • • •
•
20.19
Module 2 secondary adr. (No42)
• • • • •
•
20.20
External module type
(No50)
• • • • •
•
20.21
External module, primary adr.
(No51)
• • • • •
•
20.22
External modulesecondary adr.
(No52)
• • • • •
•
A total survey of existing display codes (DDD) appear from a separate document.
Please contact Kamstrup for further details.
Display example showing
the PROG number.
MULTICAL® 801
Kamstrup A/S · Technical Description · 5512-571_R1_GB _11.2016
51
6.10 Info codes
MULTICAL 801 constantly monitors a series of important functions. If there is a serious error in measuring system
or installation, a flashing “info” will appear in the display until the error has been corrected. The ”Info” field flashes
as long as the error exists, no matter which reading you choose. The ”Info” field automatically disappears when the
reason for the error has been removed.
6.10.1 Examples of info codes in the display
Example: 1
Flashing ”info”
If the information code exceeds 000, a flashing “info”
will appear in the information field.
Example: 2
Current information code
Activating the top (primary) pushbutton several
times, the current information code is displayed
Example: 3
Info event counter
- shows how many times
the information code has
been changed.
Example: 4
Info logger
Pushing the bottom pushbutton once more, the data
logger for information code is displayed.
First, the date of the latest change is shown…
…then the information code set on this dat
e is
displayed. In this case it has been a ”burst alarm” on
1 June 2012.
The data logger saves the latest 50 changes. 3The
latest 36 changes can be displayed. All 50 changes
can be read by means of LogView.
Furthermore, the info code is saved in the programmable logger, in the daily logger, in the monthly logger and in
the yearly logger for diagnosis purposes.
MULTICAL® 801
52
Kamstrup A/S · Technical Description · 5512-571_R1_GB_11_2016
6.10.2 Info code types
Info Code Description Response time
0 No irregularities -
1 Supply voltage has been interrupted -
8
Temperature sensor T1 outside measuring
range
1…10 min
4
Temperature sensor T2 outside measuring
range
1…10 min
32
Temperature sensor T3 outside measuring
range
1…10 min
64 Leak in cold water system 24 hours
256 Leak in heating system 24 hours
512 Burst in heating system 120 s.
ULTRAFLOW
®
X4 info (activated when CCC=4XX)
16 Flow meter V1 communication error After reset and 24 hours (at 00:00)
1024 Flow meter V2 communication error After reset and 24 hours (at 00:00)
2048 Flow meter V1 wrong pulse figure After reset and 24 hours (at 00:00)
128 Flow meter V2 wrong pulse figure After reset and 24 hours (at 00:00)
4096 Flow meter V1, signal too weak (air) After reset and 24 hours (at 00:00)
8192 Flow meter V2, signal too weak (air) After reset and 24 hours (at 00:00)
16384 Flow meter V1 wrong flow direction After reset and 24 hours (at 00:00)
32768 Flow meter V2 wrong flow direction After reset and 24 hours (at 00:00)
If several info codes appear at the same time, the sum of the info codes is displayed. If e.g. both temperature
sensors are outside measuring range, info code 12 is displayed.
During factory configuration, the individual info codes are set active or passive, meaning that a standard heat meter
that does not use T3 cannot set info code 32.
Info = 16-1024-2048-128-4096-8192-16384-32768 functions via data communication between MULTICAL
®
and
ULTRAFLOW
®
54. See paragraph14.2.5, Info code setup, in order to change the settings.
6.10.3 Transport mode
When the meter leaves the factory it is in transport mode, whereby the info codes are active in the display only, not
in the data logger. This prevents ”infoevent” from counting during transportation and non-relevant data from
appearing in the info logger. When the meter has accumulated the volume register the first time after the
installation, the info code automatically becomes active.
MULTICAL® 801
Kamstrup A/S · Technical Description · 5512-571_R1_GB _11.2016
53
6.10.4 Info event counter
Info event counter
Increment with each change of the info code.
The info event counter of a new meter will be 0 as
“transport mode” prevents counting during
transportation.
Info code
”info” in
display
Registration in info, daily,
monthly or yearly logger
Counting of Info event
1
Yes Yes With each “main power” On/Off
4, 8, 32
Yes Yes
When Info 4, 8, 32 is set or removed.
Max. 1 per temperature measurement
64, 256
Yes Yes
When Info is set and when Info is
deleted.
Max. once a day
512
Yes Yes
When Info is set and when Info is
deleted.
Max. once every 120 s.
16, 128, 1024, 2048,
4096, 8192, 16384, 32768
Yes Yes
When Info is set and when Info is
deleted.
Max. once a day
MULTICAL® 801
54
Kamstrup A/S · Technical Description · 5512-571_R1_GB_11_2016
6.11 Tariff functions
MULTICAL 801 has 2 extra registers TA2 and TA3, which can accumulate heat energy (EE=20 accumulates volume)
parallel with the main register, based on a programmed tariff condition. Irrespective of the selected tariff form, the
tariff registers are named TA2 and TA3 in the display. The tariff function can only be used for heat energy (E1).
The main register is always accumulated as it is considered legal billing register, no matter the selected tariff
function. Tariff conditions TL2 and TL3 are monitored with each integration. If the tariff conditions are fulfilled,
consumed heat energy is accumulated in either TA2 or TA3 parallel with the main register.
2 tariff conditions, TL2 and TL3, which are always used in the same tariff type, are connected to each tariff
function. However, it is not possible to “mix” two tariff types.
Example: EE=11 (Power tariff)
TA2 shows energy consumed…
…above power limit TL2 (but below TL3)
Main register
TA2
TA3
0
10
20
30
40
50
60
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30
Power (kW)
Integrations
Power tariff
MULTICAL® 801
Kamstrup A/S · Technical Description · 5512-571_R1_GB _11.2016
55
6.11.1 Tariff types
The below-mentioned table lists the tariff types, for which MULTICAL
801 can be configured:
EE= TARIFF TYPE FUNCTION
00 No active tariff
No function
11 Power tariff
Energy is accumulated in TA2 and TA3 based on the power limits
programmed for TL2 and TL3.
12 Flow tariff
Energy is accumulated in TA2 and TA3 based on the flow limits
programmed for TL2 and TL3.
13 T1-T2 tariff
Energy is accumulated in TA2 and TA3 based on the ∆t-limits programmed
for TL2 and TL3.
14
Inlet temperature tariff
Energy is accumulated in TA2 and TA3 based on the tF-limits programmed
for TL2 and TL3.
15
Outlet temperature tariff
Energy is accumulated in TA2 and TA3 based on the tR-limits programmed
for TL2 and TL3.
19
Time controlled tariff
TL2=Start time for TA2
TL3=Start time for TA3
20
Heat/cooling volume tariff
(TL2 and TL3 are not used)
Volume (V1) is divided into TA2 for heat (T1>T2) and TA3 for cooling
(T1<T2) provided that T1 is below T1 limit.
21 PQ-tariff
Energy if P>TL2 is saved in TA2 and energy if Q>TL3 is saved in TA3
EE=00 No active tariff
If the tariff function is not going to be used, select the setup EE=00.
The tariff function can, however, at a later stage be made active by means of reconfiguration with METERTOOL for
MULTICAL
801. See section 14 METERTOOL.
EE=11 Power controlled tariff
If the current power exceeds TL2 but is lower than or equal to TL3, heat energy is counted in TA2 parallel to the main
register. If the current power exceeds TL3, heat energy is counted in TA3 parallel to the main register.
P ≤ TL2
Accumulation in main register only
TL3 > TL2
TL3 ≥ P > TL2
Accumulation in TA2 and main register
P > TL3
Accumulation in TA3 and main register
Setting up data TL3 must always include a higher value than TL2. The power-controlled tariff is e.g. used as a basis
for the individual heat consumer’s connection fee. Furthermore, this tariff type can provide valuable statistical data
if the heating station considers new construction activities.
EE=12 Flow controlled tariff
If the current water flow exceeds TL2 but is lower than or equal to TL3, heat energy is counted in TA2 parallel to the
main register. If the current water flow exceeds TL3, heat energy is counted in TA3 parallel to the main register.
Setting up data TL3 must always include a higher value than TL2.
q ≤ TL2
Accumulation in main register only
TL3 > TL2
TL3 ≥ P > TL2
Accumulation in TA2 and main register
q > TL3
Accumulation in TA3 and main register
The flow controlled tariff is e.g. used as a basis for the individual heat consumer’s connection fee. Furthermore, this
tariff type can provide valuable statistical data if the heating station considers new construction activities.
If either power or flow tariff is used you obtain an overview of the total consumption compared to the part of the
consumption used above tariff limit.
MULTICAL® 801
56
Kamstrup A/S · Technical Description · 5512-571_R1_GB_11_2016
EE=13 T1-T2 tariff (∆t)
If the current T1-T2 (∆t) is lower than TL2 but exceeds TL3, heat energy is counted in TA2 parallel to the main register.
If the current cooling falls below or is equal to TL3, heat energy is counted in TA3 parallel with the main register.
∆t ≥ TL2
Accumulation in main register only
TL3 < TL2
TL3 < ∆t < TL2
Accumulation in TA2 and main register
∆t ≤ TL3
Accumulation in TA3 and main register
Setting up tariff limits TL3 must always be lower than TL2.
The T1-T2 tariff can be used as a basis for weighted user charge. Low ∆t (small difference between inlet and outlet
temperatures) is uneconomical for the heat supplier.
EE=14 Inlet tariff
If the current inlet temperature (T1) exceeds TL2 but is lower than or equal to TL3, heat energy is counted in TA2
parallel to the main register. If the current inlet temperature exceeds TL3, heat energy is counted in TA3 parallel to
the main register.
T1 ≤ TL2
Accumulation in main register only
TL3 > TL2
TL3 ≥ P > TL2
Accumulation in TA2 and main register
T1 > TL3
Accumulation in TA3 and main register
Setting up data TL3 must always include a higher value than TL2.
The inlet temperature tariff can be used as a basis for billing consumers who are guaranteed a certain inlet
temperature. If the “guaranteed” minimum temperature is entered as TL3, the payable consumption is accumulated
in TA3.
EE=15 Outlet temperature tariff
If the current outlet temperature (T2) exceeds TL2 but is lower than or equal to TL3, heat energy is counted in TA2
parallel to the main register. If the current outlet temperature exceeds TL3, heat energy is counted in TA3 parallel
to the main register.
T2 ≤ TL2
Accumulation in main register only
TL3 > TL2
TL3 ≥ T2 > TL2
Accumulation in TA2 and main register
T2 > TL3
Accumulation in TA3 and main register
Setting up data TL3 must always be bigger than TL2.
The outlet temperature tariff can be used as a basis for weighted user charge. A high outlet temperature indicates
insufficient heat utilization, which is uneconomical for the heat supplier.
MULTICAL® 801
Kamstrup A/S · Technical Description · 5512-571_R1_GB _11.2016
57
EE=19 Time-controlled tariff
The time-controlled tariff is used for time division of the heat consumption. If TL2 = 08:00 and TL3 = 16:00, the
daily consumption from 8 a.m. to 4 p.m. is accumulated in TA2, whereas the consumption during the evening and
night from 16:01 to 07:59 will be accumulated in TA3.
TL2 must include a lower hour value than TL3.
TL 3 ≥ Clock ≥ TL2
Accumulation in TA2 and main register
TL3 > TL2
TL 2 > Clock > TL3
Accumulation in TA3 and main register
The time tariff is suitable for billing in housing areas close to industrial areas with large district heating consumption
as well as billing industrial customers.
The adjustment of the clock ought to be checked in order to secure correct time as a basis for the time tariff.
EE=20 Heat/cooling volume tariff
Heat/cooling volume tariff is used for division of volume into heat and cooling consumption. TA2 accumulates the
volume consumed together with E1 (heat energy) and TA3 accumulates the volume consumed together with E3
(cooling energy).
T1 ≥ T2
Volume is accumulated in TA2 and V1
TL2 and TL3 are
not used
T2 > T1 and T1 < T1 limit
Volume is accumulated in TA3 and V1
T2 > T1 and T1 > T1 limit
Volume is accumulated in TA2 and V1
For combined heat/cooling metering the total volume is accumulated in the register V1, whereas heat energy is
accumulated in E1 and cooling energy in E3. The heat/cooling tariff is used for dividing the consumed volume into
heat and cooling volume.
EE=20 ought always to be selected together with heat/cooling meters, type 67-xxxxxxx-6xx.
EE=21 PQ tariff
The PQ tariff is a combined power and flow tariff. TA2 functions as power tariff and TA3 functions as flow tariff.
P ≤ TL2 and q ≤ TL3
Accumulation in main register only
TL2 = power limit (P)
TL3 = flow limit (q)
P > TL2
Accumulation in TA2 and main register
q > TL3
Accumulation in TA3 and main register
P > TL2 and q > TL3
Accumulation in TA2, TA3 and main
register
The PQ tariff can e.g. be used for customers paying a fixed charge based on max. power and max. flow.
MULTICAL® 801
58
Kamstrup A/S · Technical Description · 5512-571_R1_GB_11_2016
6.12 Data loggers
MULTICAL 801 includes a permanent memory (EEPROM), in which the values from various data loggers are saved.
The meter includes the following data loggers:
Data logging interval Data logging depth Logged value
Yearly logger 15 years Counter register
•
Monthly logger 36 months Counter register
•
- Daily logger 460 days and nights
Consumption (increase)/day
♦
Programmable data logger
1080 loggings
(e.g. 45 days' hour loggings or
11 days’ 15 min. loggings)
30 registers and values
•
Info logger 50 Events (36 Events can be displayed) Info code and date
The loggers are static ones and the register types can, therefore, not be changed, the same applies to the logging
intervals. When the last record has been written into the EEPROM the oldest one will be overwritten.
6.12.1 Yearly, monthly, daily loggers
The following registers are logged every year and every month on target date as counter values. Furthermore, the
increases of day and hour are logged at midnight.
Register type Description
Yearlylogg
er
Monthly
logger
Daily
logger
Prog.
logger
Date (YY.MM.DD)
Year, month and day for logging time
• •
♦
•
Clock (hh.mm.ss.) Time
-
-
-
•
Log Info Status, quality stamping of log record
-
-
-
•
E1
E1=V1(T1-T2)k Heat energy
• •
♦
•
E2
E2=V2(T1-T2)k Heat energy
• •
♦
•
E3
E3=V1(T2-T1)k Cooling energy
• •
♦
•
E4
E4=V1(T1-T3)k Forwarded energy
• •
♦
•
E5
E5=V2(T2-T3)k Returned energy or tap from outlet pipe
• •
♦
•
E6
E6=V2(T3-T4)k Tap water energy, separate
• •
♦
•
E7
E7=V2(T1-T3)k Returned energy or tap from inlet pipe
• •
♦
•
E8
E8=m3 x T1 (inlet)
• •
♦
•
E9
E9=m3 x T2 (outlet)
• •
♦
•
TA2
Tariff register 2
• •
-
-
TA3
Tariff register 3
• •
-
-
V1
Volume register for Volume 1
• •
♦
•
V2
Volume register for Volume 2
• •
♦
•
VA
Extra water or electricity meter connected to Input A
• •
♦
•
VB
Extra water or electricity meter connected to Input B
• •
♦
•
M1
Mass corrected V1
- -
♦
•
M2
Mass corrected V2
- -
♦
•
INFO
Information code
• •
♦
•
DATE FOR MAX. FLOW V1 Date stamp for max. flow during period
• •
-
-
MAX. FLOW V1
Value of max. flow during period
• •
-
-
DATE FOR MAX. FLOW V1 Date stamp for min. flow during period
• •
-
-
MIN. FLOW V1
Value for min. flow during period
• •
-
-
DATE FOR MAX. POWER V1 Date stamp for max. power during period
• •
-
-
MAX. POWER V1
Value of max. power during period
• •
-
-
DATE FOR MAX. POWER V1 Date stamp for min. power during period
• •
-
-
MIN. POWER V1
Value for min. power during period
• •
-
-
T1avg
Time average of T1
- -
♦
-
T2avg
Time average of T2
- -
♦
-
T3avg
Time average of T3
- -
♦
-
P1avg
Time average of P1
- -
♦
-
MULTICAL® 801
Kamstrup A/S · Technical Description · 5512-571_R1_GB _11.2016
59
P2avg
Time average of P2
- -
♦
-
Operating hour counter
Accumulated number of operating hours
- -
-
•
T1
Current value of T1
- -
-
•
T2
Current value of T2
- -
-
•
T3
Current value of T3
- -
-
•
T4
Current value of T4
- -
-
•
T1-T2 (∆t)
Current differential value
- -
-
•
Flow (V1)
Current water flow of V1
- -
-
•
Flow (V2)
Current water flow of V2
- -
-
•
Power (V1)
Actual power
- -
-
•
P1
Current pressure of inlet
- -
-
•
P2
Current pressure of outlet
- -
-
•
Note: Continuous maximum water flow and permanent ∆Θ > 75 K may cause overflow in the daily data logger at
CCC=010-011-012-013-150-202-205-206. With these combinations, we recommend you to use the built-in Prog.
data logger.
6.12.2
6.12.3 Info logger
Every time the information code is changed date and info code are logged. Thus, it is possible, via METERTOOL, to
read the latest 50 changes of the information code as well as the date the change was made.
Register type Description
Date (YY.MM.DD)
Year, month and day of logging time
info
Information code on above date
When the info logger is read in the display the latest 36 changes including dates can be read.
MULTICAL® 801
60
Kamstrup A/S · Technical Description · 5512-571_R1_GB_11_2016
6.13 Leak surveillance
6.13.1 District heating system
The leak surveillance system is primarily used for direct connected district heating systems, i.e. systems without
exchangers between the district heating network and the heating system of the house. The surveillance equipment
consists of two ultrasonically based water meters placed in inlet and outlet pipe respectively as well as temperature
sensors in both pipes. Furthermore, the electronic unit of MULTICAL
801, which calculates the heat energy, also
monitors the mass difference (temperature corrected volume) which can be found between inlet and outlet pipe.
If a difference that exceeds 20 % of the measuring range (corresponding to 300 l/h for a single-family house) is
registered, an alarm will be sent within 120 s via remote communication.
Small leaks from 15 kgs/h and upwards for qp 1.5 m
3
/h are monitored on the basis of daily average in order to
exclude erroneous alarms due to air pockets and quick flow changes from e.g. hot water exchangers.
District heating leak surveillance (V1-V2)
M=
Sensitivity of leak
search
0
OFF 1 1.0 % qp + 20 % q
2
1.0 % qp + 10 % q
3
0.5 % qp + 20 % q
4
0.5 % qp + 10 % q
Note: M=2 is the default value when leak surveillance is used. Increased sensitivity, e.g. M=4, can only be achieved
by means of METERTOOL.
Info codes for leakage/burst are only active when M > 0 or N > 0 respectively.
Tap water meter
with pulse output
For radiators and
tank/exchanger
District heating
connection
Cold water-
connection
Ultrasonic meters in
flow and outlet
MULTICAL
heat meter with
remote reading
(e.g. integral radio module)
Main tap
Tap
Shut-off valves
Check valve
MULTICAL® 801
Kamstrup A/S · Technical Description · 5512-571_R1_GB _11.2016
61
Example: The below graph illustrates the difference between Mass V1 and Mass V2 during 60 days before the
leakage of an under-floor heating pipe caused a leak alarm. During the first 43 days, there is fluctuation of approx.
± 1 kg/h, which is the normal fluctuation of systems without leaks.
-2
0
2
4
6
8
10
12
14
16
400 410 420 430 440 450 460
Number of days
Leakage in kgs/hour
-2
0
2
4
6
8
10
12
14
16
400
410
420
430
440
450
460
Number of days
Leakage in kgs/hour
6.13.2 District heating burst
Every 30 seconds the current flow of the inlet pipe is compared to that of the outlet pipe. If the difference exceeds
20 % of the nominal flow at four successive measurements (120 s), info = 00512 is set and a ”burst alarm” is sent
via remote communication.
6.13.3 Cold water systems
In addition to the above-mentioned functions, MULTICAL
801 can be connected to the pulse signal from the coldwater meter of the house. It can thus monitor the cold-water consumption. Possible running cisterns, untight
heating spirals of tap water tanks or other untightnesses will cause pulses to be received from the cold water meter
24 hours a day.
If MULTICAL
801 does not register, e.g. at least one continuous hour/day without pulses from the water meter, this
implies a leakage in the water system and an alarm will be sent via remote communication.
Cold water leak surveillance (VA)
N=
Constant leakage at no consumption (pulse
resolution 10 l/imp)
0
OFF 1 20 l/h (30 min. without pulses)
2
10 l/h (1 hour without pulses)
3
5 l/h (2 hours without pulses)
Note: N=2 is the default value in connection with leak surveillance. Increased sensitivity, e.g. N=3, can only be
achieved by means of METERTOOL. Info codes for leakage/burst are only active when M > 0 eller N > 0 respectively.
6.13.4 Receipt of alarm messages
When the meter has registered a leak or burst, it sends an alarm message to a receiving station, where incoming
alarms are processed according to an encoded action pattern, which is determined for each customer, e.g. starting
with an SMS message to the customer’s mobile phone parallel with the heating station on guard receiving the
message. Regular data readings from MULTICAL
801 to receiving station/control centre ensure that defective
remote readings, if any, are detected.
MULTICAL® 801
62
Kamstrup A/S · Technical Description · 5512-571_R1_GB_11_2016
6.13.5 Surveillance, but no automatic blocking
The leak surveillance system is based on installation at a big number of private district heating customers. Normally
the individual district heating stations install and maintain leak surveillance as an integral part of the compulsory
heat metering of all district heating customers in their area. Therefore, the individual private district heating
customers need not take care of maintenance or other task of technical character in connection with the installed
leak surveillance system, and the surveillance system must not involve increased risk of erroneous closing, which
may lead to frost burst. Due to this fact, the stability and reliability of the complete system must make 12 years
operation without further maintenance possible. As neither thermically or electrically activated closing valves can
be expected to have so long a lifetime it is not possible to use automatic closing.
6.13.6 First day after reset
The first day after the installation (the meter having been without supply voltage), no info codes will be sent or
alarms set in case of a calculated district heating or cold water leak.
This limitation has been introduced in order to avoid erroneous alarms due to the installation and the shortened
measuring period.
The alarm function can be tested via remote communication by pressing both pushbuttons at a time until “Call” is
displayed.
MULTICAL® 801
Kamstrup A/S · Technical Description · 5512-571_R1_GB _11.2016
63
6.14 Reset functions
6.14.1 Resetting the hour counter
The operating hour counter can be reset in connection with e.g. change
of backup battery.
As the hour counter is often used to check whether the meter has been
in operation during the whole billing period (e.g. 1 year = 8760 hours)
the district heating supplier must always be informed, inwhich meters
the hour counter has been reset
In order to reset the operating hour counter switch off the supply voltage and disconnect the backup battery, then
wait until the display goes blank.
Connect the backup battery whilst activating the top pushbutton for min. 10 s until e.g.
energy is displayed.
Do not forget to switch on the supply voltage again. The operating hour counter has
been reset.
6.14.2 Resetting data loggers
Separate reset of data loggers, info loggers, max. & min. logger (without resetting the legal registers) can only be
carried out by means of METERTOOL. See paragraph 14 for further information.
6.14.3 Reset of all registers (total reset)
All legal and non-legal registers, including all data loggers, info logger, max. & min. logger can be reset by means
of METERTOOL or a short-circuit pen if the verification seal is broken and the internal “total programming lock” is
short-circuited.
Important! As the verification seal is broken, competent laboratories/utility companies with authorization to reseal
the meter must carry out this reset!
The following registers are reset: All legal and non-legal registers, including all data loggers, info logger, max. and
min. logger (max. values are set to zero, whereas min. values are set to 100000).
Note: ”Date” is after reset set to 2000.01.01 and subsequently changed to current date/time from the PC used for
the task. Therefore, do not forget to check correct date/time (technical normal time = ”winter time”) of the PC before
starting the reset function via METERTOOL.
MULTICAL® 801
64
Kamstrup A/S · Technical Description · 5512-571_R1_GB_11_2016
6.14.4 Reset of all registers (with short-circuit pen)
The supply voltage (230 VAC or 24 VAC) is switched off, but the backup battery must be in working order. A shortcircuit pen (type: 66-99-278) is used to break the seal and short-circuit the two contact points for approx. 10 s, until
CLR is displayed.
Figure 3
The short-circuit pen functions in >back-up mode< as
”Total reset” and >with supply voltage< as ”Total Prog”
Do not forget to switch on the supply voltage again.
Note: ”Date” is after reset set to 2000.01.01. Therefore, do not forget to adjust date/time via hand-held terminal or
PC with METERTOOL if correct time is important for the application in question.
6.15 SMS commands
MULTICAL® 801 can be read by means of an SMS. In order to do so, a GSM-module fitted with a SIM-card must be
mounted in the meter (see paragraph 11.1.5). You send an SMS from a mobile phone direct to the meter.
Subsequently, you receive a reply with the following values:
• Acc. energy: [kWh], [MWh], [GJ] or [Gcal]
• Current power: [kW] or [MW]
• Hour counter
• Meter number
It is also possible to read the modem’s signal strength by means of an SMS. You receive a reply with the modem’s
current signal strength on a scale of 0 to 31, the best value being 31. The signal strength must be minimum 12.
See the examples on the next page.
NOTE: SMS commands must be written in either capital letters or small letters, i.e. an SMS command must not
include a mixture of capital and small letters.
MULTICAL® 801
Kamstrup A/S · Technical Description · 5512-571_R1_GB _11.2016
65
READ_HEAT_METER – for reading a MULTICAL ® 801
Syntax
=READ_HEAT_METER#
Return reply, error
NO ANSWER
Example of SMS command
=READ_HEAT_METER#
Example of correct reply
12.067Gj, 120.0kW
6930 Hours,
Meter No.: 6055524
SIGNAL – for reading the signal strength
Syntax, command
=SIGNAL#
Return reply, error
NO ANSWER
Example of SMS command
=SIGNAL#
Example of correct reply
Signal: 16(0-31)
MULTICAL® 801
66
Kamstrup A/S · Technical Description · 5512-571_R1_GB_11_2016
7 Flow meter connection
MULTICAL 801 can be used with up to 4 pulse inputs, of which V1 and V2 are used for energy calculation and leak
surveillance, whereas VA and VB are used to accumulating pulses from e.g. cold water meters and electricity meters.
V1 and V2 can either be used for quick pulses (CCC > 100) or slow pulses (CCC = 0XX). Quick and slow pulses
cannot be used at a time.
7.1 Volume inputs V1 and V2
MULTICAL 801 can be connected with one or two flow sensors, depending on the required application. Typical
heating installations with one flow sensor are always connected to V1, no matter if this flow sensor is installed in
inlet or outlet pipe.
Almost all available flow sensor types with pulse output can be connected as the standard connection circuit can
receive pulses from both electronic and mechanical meters.
7.1.1 Flow sensor with transistor or FET output
The signal transmitter is normally an optocoupler with transistor or FET output. V1 is connected to terminals 10(+)
and 11(-), V2 is connected to terminals 69(+) and 11(-). Terminal 9 is not used in this application.
The leak current of transistor or FET output must not exceed 1µA in OFF-state and it must be max. 0.4 V in ON-state.
A suitable CCC-kode with the same number of imp./litre as the flow sensor must be selected and for this flow meter
type the CCC-code must be CCC > 100.
Example: CCC=147 is suitable for an electronic meter with 1 imp./litre and qp 150 m
3
/h.
7.1.2 Flow sensor with reed contact output
The transmitter is a reed contact, which is normally mounted on vane wheel and Woltmann meters, or a relay output
from e.g. a magnetic inductive flow sensor. V1 is connected to terminals 10(+) and 11(-), V2 is connected to
terminals 69(+) and 11(-). Terminal 9 is not used in this application.
The leak current must not exceed 1µA in OFF state and it must be max 10 kΩ in ON-state.
A suitable CCC-code with the same number of litres/imp as the flow sensor must be selected and for this flow meter
type the CCC-code must be in the area 010 ≤ CCC ≤ 022.
Example: CCC=012 is suitable for a mechanical flow meter with 100 litres/imp. Flow sensors with Qmax. in the
range of 10…300 m
3
/h can use this CCC-code.
MULTICAL® 801
Kamstrup A/S · Technical Description · 5512-571_R1_GB _11.2016
67
7.1.3 Flow sensor with active output, supplied through MULTICAL
This connection is used together with both Kamstrup’s ULTRAFLOW and Kamstrup’s electronic pick-up units for vane
wheel meters. The current consumption of these units is very low and furthermore adapted to the battery lifetime
of MULTICAL
.
A suitable CCC-code with the same number of imp/litre as the flow sensor must be selected and for this flow meter
type the CCC-code must be CCC > 100.
Example: CCC=119 suits an electronic meter with 100 imp/litre and normally qp 1.5 m
3
/h.
V1 and V2 are connected as shown in the table below.
V1
V2
Red (3.6 V)
9
9
Yellow (signal)
10
69
Blue (GND)
11
11
Table 2
7.1.3.1 Use of Pulse Transmitter between ULTRAFLOW
®
and MULTICAL®
In general, it is permissible to use up to 10 m cable between MULTICAL
®
and ULTRAFLOW®. If longer cable is
required, a Pulse Transmitter can be inserted between ULTRAFLOW
®
and MULTICAL®. In this way, the cable length
can be extended up to 50 m.
When a Pulse Transmitter is used between ULTRAFLOW
®
and MULTICAL®, volume pulses from the flow meter will be
transferred to the calculator. However, data communication between the calculator and the flow meter is disabled.
In order to avoid erroneous info codes it is, therefore, necessary to deselect the info codes, which are based on
data communication between MULTICAL
®
and ULTRAFLOW® 54 (Info = 16-1024-2048-128-4096-8192-16384-
32768).
The above-mentioned info codes can be deselected by means of the PC-program METERTOOL, either by changing
from CCC-code 4xx to 1xx, or by using the ”Info code setup” function under ”Utility”. See paragraph 14.2.3 Info
code setup.
7.2 Flow meter with active 24 V pulse output
MULTICAL 801 can be direct connected to ”industrial” flow sensors with 24 V active pulse output on terminals 10B
and 11B for V1 and terminals 69B and 79B for V2. If the only output of the flow meter used is a passive one,
MULTICAL
801’s internal auxiliary supply on terminals 97A and 98A is used.
Technical data for the optoisolated pulse inputs
Pulse input voltage
12…32 V
Pulse current
Max. 12 mA at 24 V
Pulse frequency
Max. 128 Hz
Pulse duration:
Min. 3 ms
Cable length V1 and V2
Max. 100 m
(drawn with min. 25 cm distance to other cables)
Galvanic isolation
Inputs V1 (10B and 11B) and V2 (69B and 79B) are both individually
isololated and isolated from MULTICAL
Insulation voltage
2 kV
MULTICAL® 801
68
Kamstrup A/S · Technical Description · 5512-571_R1_GB_11_2016
7.2.1 Connection examples
Figure 4
The active pulse output is direct connected to the not galvanically separated flow sensor input. This permits a
cable length of up to 10 m between flow sensor and calculator.
Figure 5
Auxiliary voltage from terminals 97A and 98A is added to the passive contact output on terminals 10A and 11A
before the signal is connected to the galvanically separated flow sensor input. This permits a cable length of up to
100 m between flow sensor and calculator.
Figure 6
The active pulse output is direct connected to the galvanically separated flow sensor input. This permits a cable
length of up to 100 m between flow sensor and calculator.
MULTICAL® 801
Kamstrup A/S · Technical Description · 5512-571_R1_GB _11.2016
69
Figure 7
The active pulse output is direct connected to the galvanically separated flow sensor input. This permits a cable
length of up to 100 m between flow sensor and calculator.
Heat energy Cooling energy
Same ΔΘ polarity E2 = V2 (T1-T2)k E1 = V1 (T1-T2)k
Changed ΔΘ polarity E2 = V2 (T1-T2)k E3 = V1 (T2-T1)k
Figure 8
The active pulse output is direct connected to the galvanically separated flow sensor input. This permits a cable
length of up to 100 m between flow sensor and calculator.
Figure 9
Auxiliary voltage from E+ and E- is added to the passive contact output P before the signal is connected to the
galvanically separated flow sensor input. This permits a cable length of up to 100 m between flow sensor and
calculator.
MULTICAL® 801
70
Kamstrup A/S · Technical Description · 5512-571_R1_GB_11_2016
Figure 10
The active pulse output is direct connected to the galvanically separated flow sensor input. This permits a cable
length of up to 100 m between flow sensor and calculator.
Figure 11
The passive contact output on terminals 56 and 57 is direct connected to the not galvanically separated flow
sensor input. This permits a cable length of max
10-20 m between flow sensor and calculator.
Figure 12
Auxiliary voltage from terminals 97A and 98A is added to the passive contact output on terminals 56 and 57
before the signal is connected to the galvanically separated flow sensor input. This permits a cable length of up to
100 m between flow sensor and calculator.
MULTICAL® 801
Kamstrup A/S · Technical Description · 5512-571_R1_GB _11.2016
71
Figure 13
Auxiliary voltage from terminals 97A and 98A is added to the passive contact output on terminals 24 and 25
before the signal is connected to the galvanically separated flow sensor input. This permits a cable length of up to
100 m between flow sensor and calculator.
Heat energy Cooling energy
Same ΔΘ polarity E2 = V2 (T1-T2)k E1 = V1 (T1-T2)k
Changed ΔΘ polarity E2 = V2 (T1-T2)k E3 = V1 (T2-T1)k
Figure 14
The two ULTRAFLOW
®
are installed ”back to back”, whereby one of the meters will measure flow, which one
depends on the flow direction.
ULTRAFLOW
®
is connected to the non-galvanically separated inputs. Up to 10 m cable length between flow
meter and calculator is thus possible.
MULTICAL® 801
72
Kamstrup A/S · Technical Description · 5512-571_R1_GB_11_2016
7.2.2 Flow sensor coding
Installing the sensor it is important that both flow sensor and MULTICAL
are correctly programmed. The below-
mentioned table lists the most frequently used flow sensor codes:
Number of decimals in display
CCC
No.
Pre-
counter
Flow
factor
MWh
Gcal
GJ m³
[ton]
m³/h MW l/imp Imp./l
Qp range [m³/h]
Qs
[m³/h]
Type Flow
sensor
201 100 235926 2 1 1 1 2 1 1 10…100
75 FUS380
DN50-65
N
202 40 589815 2 1 1 1 2 2.5 0.4 40…200
240 FUS380
DN80-100
N
203 400 589815 1 0 0 1 2 2.5 0.4 100…400
500 FUS380
DN125
N
204 100 235926 1 0 0 0 1 10 0.1 150…1200
1600 FUS380
DN150-250
N
205 20 1179630 1 0 0 0 1 50 0.02 500…3000
3600 FUS380
DN300-400
N
206 100 2359260 0 x10 x10 0 1 100 0.01 1400…18000 36000 FUS380
DN500-1200
N
Table 3
MULTICAL® 801
Kamstrup A/S · Technical Description · 5512-571_R1_GB _11.2016
73
7.3 Pulse inputs VA and VB
In addition to pulse inputs V1 and V2, MULTICAL 801 has two extra pulse inputs, VA and VB, for collection and
remote accumulation of pulses from e.g. cold-water meters and electricity meters. The pulse inputs are physically
placed in ”Module 1” like e.g. in ”M-Bus + pulse inputs” which can be placed in the connection bracket, but
accumulation and data logging of values is carried out by the calculator.
Pulse inputs VA and VB function independently of the other inputs/outputs and are therefore not included in any
energy calculation either.
The two pulse inputs are identically constructed and can be individually set up to receive pulses from water meters
with max. 1 Hz or pulses from electricity meters with max. 3 Hz.
Configuration for correct pulse value has been carried out from the factory based on order information or is
configured by means of METERTOOL. See paragraph 3.6 concerning configuration of VA (FF-codes and VB (GGcodes).
MULTICAL 801 registers the accumulated consumption of the meters connected to VA and VB and saves the
counter values every month and every year on target date. In order to facilitate the identification during data reading
it is also possible to save the meter numbers of the two meters connected to VA and VB. Programming is carried
out with METERTOOL.
The registration, which can both be read from the display (selecting a suitable DDD-code) and via data
communication, includes the following as well as date indication of yearly and monthly data:
Type of registration
Counter value Identification Yearly data Monthly data
VA (accumulated register)
•
Meter number VA
•
Yearly data, up to latest 15 years
•
Monthly data, up to latest 36 months
•
VB (accumulated register)
•
Meter number VB
•
Yearly data, up to latest 15 years
•
Monthly data, up to latest 36 months
•
Counter values VA and VB can be preset to the value of the connected meters at the time of commissioning by
means of METERTOOL.
MULTICAL® 801
74
Kamstrup A/S · Technical Description · 5512-571_R1_GB_11_2016
7.3.1 Display example, VA
In the example below VA is configured as FF=24, which matches 10 litres/pulse and a max. flow of 10 m
3
/h. The
meter connected to VA has meter no. 75420145, which is saved in the internal memory of MULTICAL
801 by means
of METERTOOL.
Accumulated register of VA (Input A)
Meter no. of VA (max. 8 digits
Yearly data, date of LOG1 (latest target date)
Yearly data, value of LOG1 (latest yearly reading)
This is the accumulated volume registered on 1 June
2012
MULTICAL® 801
Kamstrup A/S · Technical Description · 5512-571_R1_GB _11.2016
75
8 Temperature sensors
MULTICAL 801 uses either Pt100 or Pt500 temperature sensors according to EN 60751 (DIN/IEC 751). A Pt100 or
Pt500 temperature sensor respectively is a platinum sensor, of which the nominal ohmic resistance is 100.000 Ω
and 500,000 Ω at 0.00°C and 138.506 Ω and 692,528 Ω at 100.00°C respectively. All ohmic resistance values are
determined in the international standard IEC 751, applying to Pt100 temperature sensors. The ohmic resistance
values of Pt500 sensors are five times higher. The tables below include resistance values for each degree celcius
in [Ω] for both Pt100 and Pt500 sensors:
Pt100
°
C
0 1 2 3 4 5 6 7 8 9
0
100.000 100.391 100.781 101.172 101.562 101.953 102.343 102.733 103.123 103.513
10
103.903 104.292 104.682 105.071 150.460 105.849 106.238 106.627 107.016 107.405
20
107.794 108.182 108.570 108.959 109.347 109.735 110.123 110.510 110.898 111.286
30
111.673 112.060 112.447 112.835 113.221 113.608 113.995 114.382 114.768 115.155
40
115.541 115.927 116.313 116.699 117.085 117.470 117.856 118.241 118.627 119.012
50
119.397 119.782 120.167 120.552 120.936 121.321 121.705 122.090 122.474 122.858
60
123.242 123.626 124.009 124.393 124.777 125.160 125.543 125.926 126.309 126.692
70
127.075 127.458 127.840 128.223 128.605 128.987 129.370 129.752 130.133 130.515
80
130.897 131.278 131.660 132.041 132.422 132.803 133.184 133.565 133.946 134.326
90
134.707 135.087 135.468 135.848 136.228 136.608 136.987 137.367 137.747 138.126
100
138.506 138.885 139.264 139.643 140.022 140.400 140.779 141.158 141.536 141.914
110
142.293 142.671 143.049 143.426 143.804 144.182 144.559 144.937 145.314 145.691
120
146.068 146.445 146.822 147.198 147.575 147.951 148.328 148.704 149.080 149.456
130
149.832 150.208 150.583 150.959 151.334 151.710 152.085 152.460 152.835 153.210
140
153.584 153.959 154.333 154.708 155.082 155.456 155.830 156.204 156.578 156.952
150
157.325 157.699 158.072 158.445 158.818 159.191 159.564 159.937 160.309 160.682
160
161.054 161.427 161.799 162.171 162.543 162.915 163.286 163.658 164.030 164.401
170
164.772 165.143 165.514 165.885 166.256 166.627 166.997 167.368 167.738 168.108
Pt100, IEC 751 Amendment 2-1995-07
Table 4
MULTICAL® 801
76
Kamstrup A/S · Technical Description · 5512-571_R1_GB_11_2016
Pt500
°
C
0 1 2 3 4 5 6 7 8 9
0
500.000 501.954 503.907 505.860 507.812 509.764 511.715 513.665 515.615 517.564
10
519.513 521.461 523.408 525.355 527.302 529.247 531.192 533.137 535.081 537.025
20
538.968 540.910 542.852 544.793 546.733 548.673 550.613 552.552 554.490 556.428
30
558.365 560.301 562.237 564.173 566.107 568.042 569.975 571.908 573.841 575.773
40
577.704 579.635 581.565 583.495 585.424 587.352 589.280 591.207 593.134 595.060
50
596.986 598.911 600.835 602.759 604.682 606.605 608.527 610.448 612.369 614.290
60
616.210 618.129 620.047 621.965 623.883 625.800 627.716 629.632 631.547 633.462
70
635.376 637.289 639.202 641.114 643.026 644.937 646.848 648.758 650.667 652.576
80
654.484 656.392 658.299 660.205 662.111 664.017 665.921 667.826 669.729 671.632
90
673.535 675.437 677.338 679.239 681.139 683.038 684.937 686.836 688.734 690.631
100
692.528 694.424 696.319 698.214 700.108 702.002 703.896 705.788 707.680 709.572
110
711.463 713.353 715.243 717.132 719.021 720.909 722.796 724.683 726.569 728.455
120
730.340 732.225 734.109 735.992 737.875 739.757 741.639 743.520 745.400 747.280
130
749.160 751.038 752.917 754.794 756.671 758.548 760.424 762.299 764.174 766.048
140
767.922 769.795 771.667 773.539 775.410 777.281 779.151 781.020 782.889 784.758
150
786.626 788.493 790.360 792.226 794.091 795.956 797.820 799.684 801.547 803.410
160
805.272 807.133 808.994 810.855 812.714 814.574 816.432 818.290 820.148 822.004
170
823.861 825.716 827.571 829.426 831.280 833.133 834.986 836.838 838.690 840.541
Pt500, IEC 751 Amendment 2-1995-07
Table 5
8.1 Sensor types
MULTICAL
801 Type 67-
Pt500 sensor pair (2-wire sensors)
No sensor pair
0
Pocket sensor pair with 1.5 m cable
A
Pocket sensor pair with 3.0 m cable
B
Pocket sensor pair with 5 m cable
C
Pocket sensor pair with 10 m cable
D
Short direct sensor pair with 1.5 m cable
F
Short direct sensor pair with 3.0 m cable
G
Set of 3 pocket sensors with 1.5 m cable
L
Set of 3 short direct sensors with 1.5 m cable
Q3
MULTICAL® 801
Kamstrup A/S · Technical Description · 5512-571_R1_GB _11.2016
77
8.2 Cable influence and compensation
8.2.1 Two-wire sensor pair
MULTICAL
801 is in standard version fitted with 4-wire sensor inputs for all three inputs, T1-T2-T3. Mostly only
relatively short temperature sensor lengths are needed for small and medium-size heat meters, which means that
2-wire sensor sets can be used with advantage.
Figure 15
Connection of 2-wire sensors by means
of jumpers (type: 66-99-209)
Cable lengths and cross sections of the two sensors, which are used as temperature sensor pair for a heat meter,
must always be identical, and cable sensors must neither be shortened nor extended.
The limitations connected to the use of 2-wire sensor sets according to EN 1434-2 appear from the table below.
Kamstrup supply Pt500 sensor sets with up to 10 m cable (2 x 0.25 mm
2
)
Cable cross
section
[
mm
2
]
Pt100 sensors
Pt500 sensors
Max. cable length
[m]
Temperature
increase [K/m]
Copper @ 20
°
C
Max. cable length
[m]
Temperature
increase [K/m]
Copper @ 20
°
C
0.25 2.5
0.450
12.5
0.090
0.50 5.0
0.200
25.0
0.040
0.75 7.5
0.133
37.5
0.027
1.50 15.0
0.067
75.0
0.013
Table 6
8.2.2 4-wire sensor pair
For installations, requiring longer cables than listed in the table above, we recommend the use of 4-wire sensor
sets.
MULTICAL
801 has a ”real” 4-wire construction, which uses two conductors for measuring current and the two
conductors for measuring signal, which means that the construction is in theory uninfluenced by long sensor
cables. In practice, cables ought not to be longer than 100 m and we recommend the use of 4 x 0.25 mm
2
.
MULTICAL® 801
78
Kamstrup A/S · Technical Description · 5512-571_R1_GB_11_2016
The connection cable ought to have an outer diameter of 5-6 mm in order to obtain optimum tightness of both
MULTICAL
801 and the screw-joint for the 4-wire sensor. The isolation material/cover of the cable ought to be
selected based on the maximum temperature in the installation. PVC cables are normally used up to 80°C and for
higher temperatures, silicone cables are often used.
Kamstrup’s 4-wire sensor pair has a replaceable sensor insert and is available in lengths of 90, 140 and 180 mm.
MULTICAL® 801
Kamstrup A/S · Technical Description · 5512-571_R1_GB _11.2016
79
8.3 Pocket sensors
The Pt500 cable sensor is constructed with 2-wire silicone cable and closed with a D 5.8 mm shrunk on stainless
steel tube, which protects the sensor element.
The steel tube is mounted in a sensor pocket (immersion pipe) which has an inner diameter of 6 mm and an outer
diameter of 8 mm. Sensor pockets are available with R½ (conical ½”) connection in stainless steel i lengths of 65,
90 and 140 mm. The sensor construction with separate immersion pipe permits replacement of sensors without
having to switch off the flow. Furthermore, the wide range of immersion pipe lengths ensures that the sensors can
be mounted in all existing pipe dimensions.
Figure 16 Figure 17
The stainless steel pockets can be for mounting in PN25 systems!
The plastic tube on the sensor
cable is placed opposite the
sealing screw and the screw is
tightened lightly by hand before
sealing.
MULTICAL® 801
80
Kamstrup A/S · Technical Description · 5512-571_R1_GB_11_2016
8.4 Pt500 short direct sensor pair
The Pt500 short direct sensor has been constructed according to the European heat meter standard EN 1434-2. The
sensor has been designed for direct mounting in the measuring medium, i.e. without sensor pocket, whereby a very
fast response to temperature changes from e.g. domestic water exchangers is obtained.
The sensor is based on two-wire silicone cable. The sensor pipe is made of stainless steel and has a diameter of 4
mm at the point where the sensor element is placed. Furthermore, it can be direct mounted in many flow sensor
types, which reduces the installation costs.
Figure 18
Figure 19
Figure 20
The sensor can be mounted in special T-sections
which are available for ½”, ¾” and 1” pipe
installations.
In addition, the short direct sensor can be
mounted by means of a R½ or R¾ for M10
nipple in a standard 90
° tee.
To obtain the best serviceability during meter replacement, the short
direct sensor can be placed in a ball valve with a sensor connecting piece.
Ball valves with sensor connecting piece are available in G½, G¾, G1,
G1¼ and G1½
No.
6556-474
6556-475
6556-476
6556-526
6556-527
G½
G¾
G1
G1¼
G1½
Recommended
temperature sensor
DS 27.5 mm DS 27.5 mm DS 27.5 mm DS 38 mm DS 38 mm
Max. 130 °C and PN16
MULTICAL® 801
Kamstrup A/S · Technical Description · 5512-571_R1_GB _11.2016
81
9 Other connections
9.1 Pulse outputs CE and CV [16-19]
MULTICAL® 801 has pulse outputs for energy and volume pulses respectively. CE on terminals 16-17 releases one
pulse per least significant digit in the energy count of the display. CV on terminals 18-19 releases one pulse per
least significant digit in the volume count of the display.
For CCC codes with 8-digit counter (e.g. CCC=206) energy pulses (GJ) and volume pulses (m3) will be generated
with every least significant digit but one.
If a higher resolution of pulse outputs is required, a high-resolution CCC code must be selected.
The pulse outputs are passive, optoisolated and tolerate 30 VDC and 10 mA. If active pulse outputs are required,
the internal supply on terminals 97A-98A can be used.
Passive pulse outputs connected via external supply Active pulse outputs connected via internal supply
By means of the PC-programm METERTOOL you can choose between 32, 100 and 247 ms in addition to the option
of pulses for combined heat/cooling measurement (CE- and CV-).
9.2 Analog outputs [80-87]
MULTICAL® 801 is available with 4 analog outputs. The outputs are active 0-20 mA or 4-20 mA, can be loaded with
0…500 Ω and are optoisolated in relation to the supply. The 4 analog outputs, however, are not mutually isolated.
All values of the four analog outputs are updated every 10 seconds. The total response time however, may be up
to 30-40 seconds including the response time for the flow sensor, the calculator and the digital to analog
conversion. This response time has to be considered when using the analog outputs for other purposes than remote
displaying.
The analog outputs can be configured as power, flow (V1, V2), T1, T2, T3 or T1-T2, and the measuring range can be
configured. All relevant configurations can be set up from the factory or on site by means of METERTOOL.
After reconfiguration of the analog outputs, the meter must be reset. A reset can be effected in two different ways:
1) Switch off the mains supply and remove the plug to the back-up battery. The new values will not be saved in the
meter’s memory until back-up battery and mains supply have been reconnected.
2) By means of METERTOOL a ”normal reset” is carried out under ”UTILITY Reset”. After this, the new values
have been stored in the meter’s memory.
Example of
configuration of the
analog outputs:
MULTICAL® 801
82
Kamstrup A/S · Technical Description · 5512-571_R1_GB_11_2016
The analog outputs can also be coupled with common ground.
9.3 Data connection [62-64]
MULTICAL® 801 has data connection on terminals 62-63-64. The data connection is passive and optoisolated, as
shown in the block diagram below. Adaption to RS 232 level is possible via data cable type 66-99-106. Adaption
to USB is possible via data cable 66-99-098.
The data connection uses the KMP protocol. Please contact Kamstrup for further details on the KMP protocol.
9.4 Valve control [16B-18B]
MULTICAL® 801 has a built-in valve control, which makes it possible to automatically restrict power, flow,
differential or outlet temperature to a preprogrammed limit.
Note: 24 VAC
For further details about installation and setup, you can order installation instructions 5512-498.
MULTICAL® 801
Kamstrup A/S · Technical Description · 5512-571_R1_GB _11.2016
83
9.5 Auxiliary supply [97A-98A]
MULTICAL® 801 comprises a built-in auxiliary supply on terminals 97A-98A. The auxiliary supply is based on an
unstabilized power supply. This means that the output voltage varies depending on load.
The output current must not exceed 50 mA and the nominal output current is 35 mA.
The auxiliary supply is suitable for e.g. supplying a Lon-module or a passive flow meter output.
The built in auxiliary supply is available on terminals 97A-98A.
The voltage on terminals 97A-98A varies according to load.
MULTICAL® 801
84
Kamstrup A/S · Technical Description · 5512-571_R1_GB_11_2016
10 Power supply
MULTICAL® 801 is available for 24 VAC or 230 VAC supply voltage.
MULTICAL
801 Type 67-
Supply
230 VAC supply
7
24 VAC supply
8
As the connection PCB of MULTICAL
®
801 is equipped with either a 24 VAC or a 230 VAC transformer, it is not
possible to change the supply voltage of a previously supplied meter.
10.1 Built in battery backup
The built-in backup battery maintains all basic energy meter functions, including flow meter supply on terminal
11-9-10 (V1) as well as terminal 11-9-69 (V2) during power failure. The battery backup does not support functions
with high power consumption, such as back illumination of display and analog outputs.
The type number of the backup battery is 66-99-619 (2xA lithium battery with plug)
The lifetime of the backup partly depends on how long MULTICAL
®
801 remains without mains supply and partly on
the temperature, to which the battery is exposed.
Backup, expected lifetime
With supply
Without supply
MULTICAL® 801
10 years
1 year
The expected back-up lifetime is reduced proportionally to the time the meter remains in stock. After a long period
in stock, or if in doubt, the back-up battery ought to be replaced before the meter is installed. Having changed the
back-up battery, the clock must be adjusted via METERTOOL.
If the meter is to be in stock for a long period, it is possible to disconnect the back-up battery. Before installation,
the back-up battery must be reconnected, and the clock must be adjusted and the data logger reset via METERTOOL.
After a storage period of three years, we recommend that you scrap the back-up battery.
MULTICAL® 801
Kamstrup A/S · Technical Description · 5512-571_R1_GB _11.2016
85
10.2 230 VAC supply
Includes a double-chamber safety transformer that fulfils the requirements to double-isolation. The power
consumption is lower than 3 W (without analog outputs) or less than 9 W with analog outputs.
National regulations for electric installations must be observed. The heating station’s personnel can connect/
disconnect the 230 VAC module, whereas an authorized electrician must carry out the fixed 230 V installation into
the meter panel.
10.3 24 VAC supply
Includes a double-chamber safety transformer, which fulfils the double-isolation requirements. The power
consumption is lower than 3 W (without analog outputs) or less than 9 W with analog outputs.
National regulations for electric installations must be observed. The 24 VAC module can be
connected/disconnected by the heating station’s personnel, whereas the fixed 230/24 V installation into the meter
panel must be carried out by an authorized electrician.
MULTICAL® 801
86
Kamstrup A/S · Technical Description · 5512-571_R1_GB_11_2016
MULTICAL® 801 is specially suited for installation together with a 230/24 V safety transformer, e.g. type 6699-403,
which can be installed in the meter panel in front of
the safety relay. When the transformer is used, the power
consumption will be lower than 3 W (without analog outputs) or lower than 9 W with analog outputs, for the
complete meter incl. 230/24 V transformer.
Note: The safery transformer 6699-403 is suitable for MULTICAL® 801 either with analog outputs or with high-power
communication.
For MULTICAL
®
801 with both analog outputs and high-power communication we recommend a stronger
transformer, e.g. type 5920-161.
Maximum cable length between 230/24 VAC transformer e.g. Kamstrup type 6699-403 and MULTICAL
®
.
Cable type
Maximum length
2 x 0.75 m
50 m
2 x 1.5 mm2
100 m
MULTICAL® 801
Kamstrup A/S · Technical Description · 5512-571_R1_GB _11.2016
87
10.4 Danish regulations for the connection of mains operated meters
Installation to mains connected equipment for registration of consumption (Text from The Danish National Safety
Board, 2004-12-06)
The consumption of energy and resources (electricity, heat, gas and water) of the individual consumer is to an
increasing extent registered by electronic meters, and often equipment for remote reading and remote control of
both electronic and non-electronic meters is used.
General regulations for carrying out installations must be observed. However, the following modifications are
permitted:
• If meter or equipment for remote reading or remote control are double-isolated, it is not necessary to draw
the protective conductor all the way to the connection point. This also applies if the connection point is a
plug socket provided that it is placed in a canning which is sealable or can be opened with key or tool only.
If meter or equipment for remote reading and remote control, which is connected to a safety transformer mounted
in the panel and direct connected to the branch conductor, is used, no on-off-switch or separate overcurrent
protection in either primary or secondary circuit is required provided that the following conditions are fulfilled:
• The safety transformer must either be inherently short-circuit-proof or fail-safe
• The conductor of the primary circuit must be either short-circuit-protected by the overcurrent protection of
the branch conductor or short-circuit safely drawn.
• The conductor of the secondary circuit must have a cross section of at least 0.5 mm² and a current value
which exceeds the absolute maximum current deliverable by the transformer
• It must be possible to separate the secondary circuit by separators or it must appear form the installation
instructions that the secondary circuit can be disconnected at the transformer’s terminals
General information. An authorized electrician must carry out Work on the fixed installation, including any
intervention in the group panel.
It is not required that service work on equipment comprised by this message as well as connection and
disconnection of the equipment outside the panel is carried out by an authorized electrician. This task can also be
carried out by persons or companies, who professionally produce, repair or maintain equipment if only the person
carrying out the work has the necessary expert knowledge.
MULTICAL® 801
88
Kamstrup A/S · Technical Description · 5512-571_R1_GB_11_2016
11 Plug-in modules
Two plug-in modules can be mounted in the connection base of MULTICAL 801, in this way the meter can be
adapted to various applications.
All plug-in modules are included in the comprehensive type test, to which MULTICAL
®
801 has been subjected.
Within the framework of the type approval, the CE-declaration and the manufacturer’s guarantee no other types of
plug-in modules than the ones listed below can be used.
11.1 Plug-in modules
MULTICAL 801 Type 67-
Module 2 (VA and VB are not available in module position 2)
No module
0
Siox module (Auto detect Baud rate)
M
M-Bus (Alternative. registre)
P
M-Bus module with MCIII data package
Q
M-Bus
V
RadioRouter
W
LonWorks, FTT-10A
Y
GSM/GPRS (GSM6H)
Z 3G GSM/GPRS (GSM8H)
U
Ethernet/IP modul (IP201)
T
Module 1 (VA and VB are available in module position 1)
No module
00
M-Bus + pulse inputs
20
RadioRouter + pulse inputs
21
Data logger + 4-20 mA inputs + pulse inputs
22
LonWorks, FTT-10A + pulse inputs
24
M-Bus module with alternative registers + pulse inputs
27
M-Bus module with MC-III data package + pulse inputs
29
Wireless M-Bus Mode C1 + pulse inputs
30
Wireless M-Bus Mode T1 OMS 15 min. (Individual key)
31
Wireless M-Bus Mode C1 Alt. reg. (Individual key) + pulse inputs
35
Wireless M-Bus Mode C1 Fixed Network (Individual key)
38
ZigBee 2.4 GHz int.ant. + pulse inputs
60
Metasys N2 (RS485) + pulse inputs
62
Siox module (Auto detect Baud rate)
64
BACnet MS/TP + pulse inputs
66
Modbus RTU + pulse inputs
67
High Power Radio Router + pulse inputs
84
MULTICAL® 801
Kamstrup A/S · Technical Description · 5512-571_R1_GB _11.2016
89
MULTICAL® 801
90
Kamstrup A/S · Technical Description · 5512-571_R1_GB_11_2016
11.1.1 Possible combinations of module 1 and module 2
2 ⇒
1
⇓
67-0W
RadioRouter
67-0Y
LonWorks
67-0Z
GSM/GPRS
67-0U
3G GSM/GPRS
(GSM8H)
65-0M
SIOX
67-0T
Ethernet/IP
(IP201)
67-0P
M-Bus
(Alt. reg.)
67-0V
M-Bus
67-0Q
M-Bus MCIII data
67-00-20/27/29
M-Bus
+ pulsindg.
OK OK OK OK OK OK OK
67-00-21
RadioRouter
+ pulse input
N/A OK N/A N/A OK OK OK
67-00-22
0/4-20 Input
OK OK OK OK OK OK OK
67-00-24
LonWorks
+ pulse input
OK OK OK OK OK OK OK
67-00-30/31/35/38
wM-Bus
+ pulse input
OK OK OK OK OK OK OK
67-00-60
ZigBee
+ pulse input
OK OK OK OK OK OK OK
67-00-62
Metasys N2
OK OK OK OK OK OK OK
67-00-64
SIOX
OK OK OK OK OK OK OK
67-00-66
BACnet MS/TP +
pulse inputs
OK OK OK OK OK OK OK
67-00-67
Modbus RTU +
pulse inputs
OK OK OK OK OK OK OK
67-00-84
High Power Radio
Router + pulse input
N/A OK N/A N/A OK N/A OK
11.1.2 Options of external communication unit connected to data output (62-63-64)
Ext. box ⇓
Serial DATA
62-63-64
Comments/limitations in use
67-0W
RadioRouter
No limitations
67-0Y
LonWorks
No limitations
67-0M
SIOX
No limitations
67-0Z
GSM/GPRS
Supply unit for GSM/GPRS module must be included in the external communication unit
67-0U
3G GSM/GPRS
(GSM8H)
Supply unit for GSM/GPRS module must be included in the external communication unit
67-0T
Ethernet/IP
(IP201)
Supply unit for GSM/GPRS module must be included in the external communication unit
67-0Q
M-Bus MCIII data
67-0V
M-Bus
67-0P
M-Bus
(Alternative registre)
No limitations
Note: Pulse input VA and VB (terminals 65-66-67-68) is not connected if the module is used in an external
communication unit.
MULTICAL® 801
Kamstrup A/S · Technical Description · 5512-571_R1_GB _11.2016
91
11.1.3 M-Bus + pulse inputs (67-00-20) (67-0V) (PCB - 5550-831)
The M-bus module is supplied through the M-bus network and is thus independent of the meter’s internal supply.
Two-way communication between M-bus and energy meter is carried out via optocouplers providing galvanic
separation between M-bus and meter. The module supports both primary, secondary and enhanced secondary
addressing.
The M-bus module has two extra inputs, which can only be used if modules are mounted in module position 1. See
paragraph “7.3 Pulse inputs VA and VB” concerning the function of the pulse inputs.
Limitations
The maximum register value of the M-Bus Protocol is "2147483647", with the following main units: "10xm3",
"10xkWh" and "10xMJ".
This means that energy meters with 8-digit energy register in MWh or GJ cannot be read through the M-Bus. This
applies, e.g. for MULTICAL
®
801 with CCC code 206.
11.1.4 RadioRouter + pulse inputs (67-00-21) (67-0W) (PCB - 5550-805)
The radio module is available for operation in licence-free frequency bands and for licence demanding frequencees.
The module is available with internal antenna as well as connection for external antenna.
The radio module is prepared to form part of a Kamstrup radio network, the read data being automatically
transferred to system software via the network component/network unit RF Concentrator.
The radio module has two extra inputs, which can only be used if modules are placed in module area 1. See
paragraph “7.3 Pulse inputs VA and VB” concerning the function of the pulse inputs.
The RadioRouter module must be used with mains supply.
11.1.5 Prog. data logger + RTC + 4…20 mA inputs + pulse inputs (67-00-22) (PCB - 5550-925)
The module has connection possibility for two pressure transmitters on terminals 57, 58 and 59 and can be
adjusted for current reading or pressure ranges of 6, 10 or 16 bar.
The module is prepared for remote reading, data from meter/module being transferred to the system software via
the connected external GSM/GPRS modem on terminals 62, 63 and 64.
The module has two extra pulse inputs, which can only be used, however, if modules are mounted in module
position 1, see paragraph 7.2: Pulse inputs VA and VB as to function. The module must be powered by 24 VAC.
Pressure transmitter requirements: 4…20 mA, 2-wire, loop-powered, loop voltage max. 16 VDC
(e.g. type CTL from Baumer A/S)
MULTICAL® 801
92
Kamstrup A/S · Technical Description · 5512-571_R1_GB_11_2016
11.1.6 LonWorks, FTT-10A + pulse inputs (67-00-24) (67-0Y) (PCB - 5550-1128)
The LonWorks module is used for data transfer from MULTICAL
801, either for data reading/registration or
regulation purposes via the Lon-Bus.
Furthermore, the module has two extra pulse inputs, which can only be used, however, if modules are mounted in
module position 1, see paragraph 7.3: Pulse inputs VA and VB as to function. The module must be powered by 24
VAC/DC or 12 VDC from terminals 97A-98A.
A list of network variables (SNVT) and further details about the LonWorks module appear from data sheet
5810-1043 (GB). Regarding mounting, we refer to installation instructions 5512-1105 (GB).
11.1.7 M-Bus module with alternative registers + pulse inputs (67-00-27) (670P) (PCB - 5550-997)
The M-Bus module is supplied via the M-Bus network and is independent of the meter’s own supply. M-Bus and
the energy meters communicate two-way via opto couplers, which gives galvanically separation between M-Bus
and the meter. The module supports primary, secondary and enhanced secondary addressing.
The M-Bus module has two extra inputs. See paragraph 7.3 Pulse inputs VA and VB concerning functioning of the
pulse inputs.
11.1.8 M-Bus module with MC-III data package + pulse inputs (67-00-29) (67-0Q) (PCB - 5550-1125)
The M-Bus module 670029 comprises the same data packet as M-Bus module 6604 for MC III/66-C and module
660S for MCC/MC 401.
The module can e.g. be used together with the old M-Bus master with display, old regulators and old reading
systems not supporting the newer M-Bus modules.
MULTICAL® 801
Kamstrup A/S · Technical Description · 5512-571_R1_GB _11.2016
93
11.1.9 Wireless M-Bus + 2 pulse inputs (67-00-30) (67-00-35) (PCB - 5550-1097 / -1200)
The radio module has been designed to form part of Kamstrup's hand-held Wireless M-Bus Reader systems, which
operate within the unlicensed frequency band in the 868 MHz area.
The module fulfils the C-mode specifications of EN13757-4:2013 and can thus form part of other systems using
Wireless M-Bus C-mode communication.
The radio module comes with internal antenna and external antenna connection as well as two pulse inputs
(VA + VB)
Paragraph 7.3 “Pulse inputs VA and VB” describes how the pulse inputs function.
11.1.10 Wireless M-Bus (67-00-31) (PCB 5550-1386)
The Wireless M-Bus module has been developed to be integrated in an ”Open Metering System” (OMS) solution
without further configuration, and operates within the unlicensed frequency band in the 868 MHz area.
The communication protocol is T-mode according to OMS specifications: Volume 2: Primary Communication
Version 4.0.2, and the module uses one-way communication, data being automatically sent from the meter after
installation, every 15 minutes from module 67-00-31.
The T1 OMS module supports individual encryption and comes with internal antenna as well as MCX connection
for external antenna.
Kamstrup recommend that an external antenna is mounted on this module if the meter is fitted with a top module
too. This ensures the best possible radio range.
Photo see above paragraph 11.1.9.
11.1.11 Wireless M-Bus (67-00-38) (PCB 5550-1356)
This Wireless M-Bus module has been specifically developed for integration in a Wireless M-Bus network (Radio
Link/READy Network) and operates within the unlicensed frequency band in the 868 MHz area.
The communication protocol is C-mode according to the standard EN13757-4, and the module uses one-way
communication. After installation, data is automatically sent from the meter every 96 seconds.
The Wireless M-Bus module for fixed network supports individual encryption and comes with internal antenna as
well as MCX connection for external antenna.
Kamstrup recommend that an external antenna is mounted on this module if the meter is fitted with a top module
too. This ensures the best possible radio range.
MULTICAL® 801
94
Kamstrup A/S · Technical Description · 5512-571_R1_GB_11_2016
11.1.12 ZigBee + 2 pulse inputs (67-00-60) (PCB - 5550-992)
The ZigBee module is mounted direct in the meter and is powered by the meter's supply. The module operates
within the 2.4 GHz area and is ZigBee Smart Energy certified. The certification secures that the meter can form part
of other ZigBee networks, e.g. reading several meter types from different meter suppliers.
To be able to offer a compact solution the module uses an internal antenna.
Paragraph 7.3 “Pulse inputs VA and VB” describes how the pulse inputs function.
11.1.13 Metasys N2 (RS485) + 2 pulse inputs (VA, VB) (67-00-62) (PCB - 5550-1110)
The N2 module is used for data transfer from MULTICAL
heat and cooling meters to an N2 Master in a Johnson
Controls System. The N2 module transfers accumulated energy and volume, current temperatures, flow and power
from the heat or cooling meter to an N2 Master. N2 Open from Johnson Controls is a widespread and established
field bus protocol used within building automation. The N2 module for MULTICAL
ensures simple integration from
Kamstrup’s heat and cooling meters to N2 Open based systems. Adress area is 1-255 determined by the last three
digits of the meters customer number.
Further details about the Metasys N2 module appear from data sheet 5810-925, GB-version.
11.1.14 SIOX module (Auto detect Baud rate) (67-00-64) (67-0M) (PCB - 5920-193)
SIOX is used for data reading of small and medium size groups of heat meters via cable, the data reading being
presented by the main system, e.g. MCom, Fix or Telefrang. Further information on these systems can be ordered
from the supplier in question. Furthermore, a configuration tool is available from Telefrang.
The two-wire serial SIOX bus connection is optoisolated from the meter and is connected without regard to
polarity (i.e. the polarity is unimportant). The module is powered by the SIOX bus. Communication speed between
300 and 19,200 baud. The module automatically uses the highest possible communication speed. The module
converts data from KMP protocol to SIOX protocol.
MULTICAL® 801
Kamstrup A/S · Technical Description · 5512-571_R1_GB _11.2016
95
11.1.15 BACnet MS/TP (B-ASC) RS485 + 2 pulse inputs (VA, VB) (67-00-66) (PCB- 5550-1240)
The BACnet module is used for data transfer from MULTICAL
heat cooling and water meters into BACnet systems.
The BACnet module transfers Meter number (programmable), Serial number, Accumulated heat energy (E1),
Accumulated cooling energy (E3), Accumulated volume flow (V1), Flow temperature, Outlet temperature,
Temperature difference, Actual flow, Actual power, Accumulated values from additional meters via puls InA, InB,
Info codes from the heat, cooling and water meter to the BACnet system. BACnet is a widespread and established
field bus protocol used within building automation. The BACnet module for MULTICAL
ensures simple integration
from Kamstrup’s heat, cooling and water meters to BACnet based systems. The Module can be used as either master
or slave, depending on the used MAC address.
Further details about the BACnet MS/TP module appear from data sheet 5810-1055, GB-version.
11.1.16 Modbus RS485 RTU* Slave Module with 2 pulse inputs (VA, VB) (67-00-67) (PCB 5550-1277)
The Modbus base module for MULTICAL
®
ensures simple integration from Kamstrup’s heat, cooling and water
meters into a Modbus based system.
Modbus is an open, widespread and well-established serial communication protocol used within building
automation.
Further details about the Modbus MS/TP module appear from data sheet 5810-1253, GB-version.
*) RTU: Remote Terminal Unit
11.1.17 GSM/GPRS module (GSM6H) (67-0Z) (PCB - 5550-1137)
The GSM/GPRS module functions as transparent communication path between reading software and
MULTICAL
801 and is used for data reading. The module includes an external dual-band GSM antenna, which must
always be used. The module itself includes a line of light emitting diodes indicating signal strength, which are very
useful during installation.
Further details about the GSM/GPRS module appear from data sheet 5810-627. GB-version 5810-628, DE-version
5810-629, SE-version 5810-630.
Regarding mounting, we refer to installation instructions DK-version 5512-686, GB-version 5512-687, DE-version
5512-688.
Sim card
MULTICAL® 801
96
Kamstrup A/S · Technical Description · 5512-571_R1_GB_11_2016
11.1.18 3G GSM/GPRS module (GSM8H) (67-0U) (PCB - 5550-1209)
Like GSM6H this module functions as transparent communication path between reading software and
MULTICAL
801 and is used for data reading.
However, this module supports both 2G (GSM/GPRS) and 3G (UMTS) which makes it applicable in areas with 3G
coverage only.
The module requires an external Antenna, which covers both 900 MHz, 1800 MHz and 2100 MHz.
The module itself is fitted with a line of light emitting diodes indicating signal strength, which are very useful during
installation. Furthermore, it is indicated whether the module is connected to a 2G or a 3G network.
Additional details about the 3G module appear from data sheet 58101057 DK-version, 55101058 GB-version,
58101059 DE-version, 58101061 FI-version and 58101060 SE-version.
Regarding mounting, we refer to installation instructions 55121121 DK-version, 55121122 GB-version, 55121123
DE-version, 55121124 FI-version and 55121125 SE-version.
11.1.19 Ethernet/IP module (IP201) (67-0T) (PCB - 5550-844)
The IP module functions as transparent communication between reading software and MULTICAL ®801 and is used
for data reading. The module supports both dynamic and static addressing. This is specified in the order or selected
during subsequent configuration. The module has no built-in security and must, therefore, always be used in
connection with a firewall or NAT.
Further details appear from the data sheet, DK-version 5810-541, GB-version 5810-542, DE-version 5810-543, SEversion 5810-544. As far as installation is concerned we refer to installation instructions, DK version 5512-934, GBversion 5512-937, DE-version 5512-938, SE-version 5512-939.
11.1.20 High Power Radio Router + 2 pulse inputs (VA, VB) (67-00-84) (PCB - 5550-1221)
The High Power RadioRouter module has built-in router functionality and is thus optimized to form part of a
Kamstrup radio network, the read data being automatically transferred to system software via the network unit RF
Concentrator.
Furthermore, the module can be read by Kamstrup’s hand-held reading systems, e.g. USB Meter Reader and MT
Pro.
The RadioRouter module is available for operation in both licence-free and licence demanding frequences
permitting a transmitting strength of up to 500 mW. The module is by default fitted with internal antenna,
connection for external antenna, and two extra pulse inputs.
See paragraph 7.3 Pulse inputs VA and VB regarding the function of the pulse inputs.
MULTICAL® 801
Kamstrup A/S · Technical Description · 5512-571_R1_GB _11.2016
97
11.2 Retrofitting modules
Modules for MULTICAL 801 are also supplied separately for retrofitting. The modules are configured and ready for
installation from the factory. However, some of the modules need individual configuration after installation, which
is possible by means of METERTOOL.
Module 1 (Module 2)
Possible configuration after installation
M-Bus + pulse inputs 20 (V)
Pulse values of VA and VB are changed via METERTOOL.
Primary and secondary M-Bus addresses can be changed via
METERTOOL or M-Bus. Furthermore, monthly logger data can
be selected instead of yearly logger data via M-bus.
RadioRouter + pulse inputs
21 (W)
Pulse values of VA and VB are changed via METERTOOL.
Prog. data logger + RTC + 4…20 mA inputs +
pulse inputs
22 -
Clock adjustment.
Pulse values of VA and VB are changed via METERTOOL.
LonWorks, FTT-10A + pulse inputs
24 (Y)
Pulse values of VA and VB are changed via METERTOOL. All
other configurations are made via LonWorks.
M-Bus module with alternative registers + pulse
inputs
27 (P)
Pulse values of VA and VB are changed via METERTOOL.
Primary and secondary M-Bus addresses can be changed via
METERTOOL or M-Bus. Furthermore, monthly logger data can
be selected instead of yearly logger data via M-Bus
M-Bus module with MC-III data package + pulse
inputs
29 (Q)
Pulse values of VA and VB are changed via METERTOOL.
Primary and secondary M-Bus addresses can be changed via
METERTOOL or M-Bus.
Wireless M-Bus + pulse inputs
30/35/38
Pulse values of VA and VB are changed via METERTOOL
Wireless M-Bus 31 N/A
ZigBee 2.4 GHz internal antenna + pulse inputs
60
Pulse values of VA and VB are changed via METERTOOL
Metasys N2 (RS485) + pulse inputs 62 Pulse values of VA and VB are changed via METERTOOL
SIOX module
64 (M)
N/A
BACnet MS/TP + pulse inputs 66
Configuration of communication address via Module
Programmer or METERTOOL.
Modbus RTU + pulse inputs
67
Configuration of communication address etc. via Module
Programmer or METERTOOL.
High Power Radio Router + pulse inputs 84 Pulse values of VA and VB are changed via METERTOOL
MULTICAL® 801
98
Kamstrup A/S · Technical Description · 5512-571_R1_GB_11_2016
Data modules are retrofitted by placing the module in the PCB holder in the left side of the meter and "clicking" on
the module.
Insert module
Module and meter are electrically connected using a 6-pole jumper:
Add jumper
MULTICAL® 801
Kamstrup A/S · Technical Description · 5512-571_R1_GB _11.2016
99
12 Data communication
12.1 MULTICAL
801 Data Protocol
Internal data communication in MULTICAL
801 is based on the Kamstrup Meter Protocol (KMP), which partly
provides a quick and flexible reading structure and partly fulfils future requirements to data reliability.
The KMP protocol is used in all Kamstrup consumption meters launched in 2006 and later. The protocol is used on
the optical eye and via plug pins for the modules. Thus, modules with e.g. M-bus interface use the KMP protocol
internally and the M-bus protocol externally.
The KMP protocol has been constructed to handle point-to-point communication in a master/slave system (e.g. a
bus system) and is used for data reading of Kamstrup energy meters.
Software and parameter protection
The meter’s software is implemented in a ROM and cannot be changed, neither deliberately nor by mistake.
The legal parameters cannot be changed via data communication without breaking the legal seal and short
circuiting the ”total programming lock”.
Software conformity
Software checksum, based on CRC16, is available via data communication and in the display.
Integrity and authenticity of data
All data parameters include type, measuring unit, scaling factor and CRC16 checksum.
Every produced meter includes a unique identification number.
Two different formats are used in the communication between master and slave, either a data frame format or an
application acknowledgement format.
• A request from master to slave is always sent in a data frame.
• The response from the slave can be sent either in a data frame or as an application acknowledgement.
The data frame is based on the OSI model using the physical layer, the data link layer and the application layer.
Number of bytes in
each field
1 1 1
0-?
2
1
Field designation
Start byte
Destination
address
CID
Data
CRC
Stop byte
OSI – layer
Application layer
Data link layer
Physical layer
The protocol is based on half-duplex serial synchroneous communication with setup: 8 data bits, no parity and 2
stop bits. The data bit rate is 1200 or 2400 baud. CRC16 is used in both request and response.
Data is transferred byte for byte in a binary data format, of which the 8 data bits represent one byte of data.
Byte Stuffing is used for extending the value range.
12.1.1 The register IDs of MULTICAL
801
MULTICAL® 801
100
Kamstrup A/S · Technical Description · 5512-571_R1_GB_11_2016
ID
Register
Description
1003
DATE
Current date (YYMMDD)
60
E1
Energy register 1: Heat energy:
94
E2
Energy register 2: Control energy:
63
E3
Energy register 3: Cooling energy:
61
E4
Energy register 4: Forward energy:
62
E5
Energy register 5: Return energy:
95
E6
Energy register 6: Tap water energy:
96
E7
Energy register 7: Heat energy Y
97
E8
Energy register 8: [m
3
x T1]
110
E9
Energy register 9: [m
3
x T2]
64
TA2
Tariff register 2
65
TA3
Tariff register 3
68
V1
Volume register V1
69
V2
Volume register V2
84
VA
Input register VA
85
VB
Input register VB
72
M1
Mass register V1
73
M2
Mass register V2
1004
HR
Operating hour counter
113
INFOEVENT
Info event counter
1002
CLOCK
Current hour (hhmmss)
99
INFO
Info code register, current
86
T1
Current inlet temperature
87
T2
Current outlet temperature
88
T3
Current temperature T3
122
T4
Current temperature T4
89
T1-T2
Current differential temperature
91
P1
Pressure in inlet
92
P2
Pressure in return
74
FLOW1
Current inlet flow
75
FLOW2
Current outlet flow
80
POWER1
Current power calculated on the basis of V1-T1-T2.
123
MAX FLOW1DATE/YEAR
Date of this year’s min.
124
MAX FLOW1DATE/YEAR
This year’s max. value
125
MIN FLOW1DATE/YEAR
Date of this year’s min.
126
MIN FLOW1/YEAR
This year’s min. value
127
MAX POWER1DATE/YEAR
Date of this month’s max.
128
MAX POWER1/YEAR
This year’s max. value
129
MIN POWER1DATE/YEAR
Date of this year’s min.
130
MIN POWER1/YEAR
This year’s min. value
138
MAX FLOW1DATE/MONTH
Date of this month’s max.
139
MAX FLOW1/MONTH
This month’s max. value
140
MIN FLOW1DATE/MONTH
Date of this month’s min.
141
MIN FLOW1/MONTH
This month’s min. value
142
MAX POWER1DATE/MONTH
Date of this month’s max.
143
MAX POWER1/MONTH
This month’s max. value
144
MIN POWER1DATE/YEAR
Date of this month’s min.
145
MIN POWER1/MONTH
This month’s min. value
146
AVR T1/YEAR
Year-to-date average for T1
147
AVR T1/YEAR
Year-to-date average for T2
149
AVR T1/MONTH
Month-to-date average for T1
150
AVR T2/MONTH
Year-to-date average for T2
66
TL2
Tariff limit 2
67
TL3
Tariff limit 3
98
XDAY
Target date (reading date)
152
PROG NO
Prog. no. ABCCCCCC
153
CONFIG NO 1
Config no. DDDEE
168
CONFIG NO 2
Config. no. FFGGMN
1001
SERIAL NO
Serial no. (unique number of each meter)
112
METER NO 2
Customer number (8 most significant digits)
1010
METER NO 1
Customer number (8 least significant digits)
114
METER NO VA
Meter no. of VA
104
METER NO VB
Meter no. of VB
1005
METER TYPE
Software edition
154
CHECK SUM 1
Software check sum
155
HIGH RES
High-resolution energy register for test purposes
157
TOP MODULE ID
ID number of top m odule
158
BOTMODULE ID
ID number of base module
Loading...