Power Supply Parameters; Actual Values, Flow Temperature Sensor; Actual Values, Outside Temperature Sensor; System Integration Of The Mcm10 - Buderus MCM10 Instrucciones De Instalación

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2
Details about the MCM10 module
I
MCM10 no. 1 (master module)
II
MCM10 no. 2 (slave module)
III
MCM10 no. 3 (slave module)
IV
MCM10 no. 4 (slave module)
1...16 Boiler
17
Low loss header
18
Common flow temperature sensor
19
Heating circuit pump
20
Junction box
21
Further subscribers at the heating controller BUS
22
Fuse for heating circuit pump connection
23
Spare fuse
24
Heating circuit
25
Function jumper
A
Power supply
B
Power supply for additional modules MCM10
C
Heating circuit pump connection
D
Remote fault indicator connection
E
Flow temperature sensor connection
F
Outside temperature sensor connection
G
External switching contact connection
H
ON/OFF contact connection
I
Building management system (0 - 10 V interface)
connection
J
Heating circuit controller connection (RC35, WM10,
MM10) with EMS BUS switching
K
Connection from the previous module MCM10
L
Connection to the next module MCM10
M
Boiler connection
2.6.4

Power supply parameters

Posi-
tion
Interface
Terminals
A
Input
B
Output
C
Output
D
Output
E
Input
1-2
F
Input
3-4
G
Input
5-6
H
Input
7-8
I
Input
9-10
J
EMS BUS
11-12
K
EMS BUS
13-14
L
EMS BUS
15-16
M
EMS BUS
17-18, 19-20,
21-22, 23-24
Tab. 3 Power supply parameters
2.6.5

Actual values, flow temperature sensor

Ω
°C
20
12490
25
10000
30
8057
35
6531
40
5327
45
4369
50
3603
55
2986
Tab. 4 Actual values, flow temperature sensor
60
Values
230 V AC, max. 16 A
230 V AC, max. 16 A
230 V AC, max. 250 W
zero volt, max. 230 V, 1 A
NTC (
tab. 4)
NTC (
tab. 5)
zero volt
24 V DC
0 - 10 V DC
Ω
°C
60
2488
65
2083
70
1752
75
1481
80
1258
85
1072
90
917
95
788
2.6.6

Actual values, outside temperature sensor

Ω
°C
– 20
97070
– 15
72929
– 10
55330
– 5
42315
0
32650
5
25388
Tab. 5 Actual values, outside temperature sensor
2.7

System integration of the MCM10

2.7.1

Principles of cascade control

When the heating controller signals a heat demand
(
tab. 6, page 62) for system versions 1, 2 and 3,
initially one boiler is started and its output raised to its
maximum rated output. Only then will a further boiler be
started.
If excessive heat is being generated, boilers are regulated
in sequence without delay down to their respective
minimum rated output, and then shut down until heat
demand and generation match. With system version 4 all
boilers are shut down simultaneously.
MCM10 module automatically determines the sequence
in which the boilers are controlled. MCM10 module
safeguards an even distribution of the burner hours run for
all boilers. This takes into account the number of hours run
in heating mode as well as in DHW mode. This increases
the boiler service life. If the power supply to the
MCM10 module fails, the hours run meter in the MCM10
module is reset to zero.
If a boiler is not able to start (DHW heating for a directly
connected DHW cylinder, boiler fault, communication
fault with the MCM10 module), another boiler will be
started automatically to cover the heat demand.
2.7.2
Heating control unit for MCM10 cascade
systems
The MCM10 modules control the boilers in accordance
with the heat demand calculated by the heating controller.
For control in accordance with the heat demand, the
MCM10 modules must therefore be installed in
conjunction with a heating controller (
terminals H, I or J). Subject to the heating controller used,
there are 4 possible system versions (
Only 1 heating controller/building
management system can be connected to
ensure the correct function.
One MCM10 module can control up to 4 boilers. By
connecting up to 4 MCM10 modules , up to 16 boilers
can be linked to form a single cascade (
page 59). In this configuration, one MCM10 module
regulates the cascade as the MCM10 master module.
Ω
°C
10
19900
15
15708
20
12490
25
10000
30
8057
35
6531
fig. 3, page 59,
tab. 6, page 62).
fig. 3,
MCM10
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