McQuay MCM Service Manual
McQuay MCM Service Manual
McQuay MCM Service Manual
Nomenclatur
latur e
ture
X : Not applicable
Electrical
A : 220 - 240V/1Ph/50Hz
F : 380 - 415V/3Ph/50Hz
U : 220 - 240V/1Ph/50Hz/60Hz
M WM 025 G W - A X AB
Piping
H : 4 pipes system
Model Type
W : Chilled water fan coil
Series
G : G series
Capacity
025 : 18,000 Btu/h (Cooling)
Model Name
WM : Wall mounted split type
CK : Ceiling cassette split type
CM : Ceiling exposed split type
CC : Ceiling concealed split type
DB : Ducted split type
Brand
M : McQuay
1
Product Line-Up
Marking
Control
Nomenclature
Model Name
NETWARE 3 (Cool/Heat)
G7 Heatpump Handset
G7 Cooling Handset
Cool/Heat
CE mark
AXCC x x x x x x
AXCD x x x x x x
020DW AXCE x x x x x x
AXCF x x x x x x
AXCG x x x x
AXCC x x x x x x
AXCD x x x x x x
025DW AXCE x x x x x x
AXCF x x x x x x
AXCG x x x x
AXCC x x x x x x
AXCD x x x x x x
030DW AXCE x x x x x x
AXCF x x x x x x
AXCG x x x x
AXCC x x x x x x
AXCD x x x x x x
040DW AXCE x x x x x x
MCM AXCF x x x x x x
AXCG x x x x
AXCC x x x x x x
AXCD x x x x x x
050DW AXCE x x x x x x
AXCF x x x x x x
AXCG x x x x
UXBD x x x x x x
007CBW
UXBE x x x x x x
UXBD x x x x x x
010CBW
UXBE x x x x x x
UXBD x x x x x x
015CBW
UXBE x x x x x x
AXAA x x x x x x
015EW
AXAB x x x x x x
AXAA x x x x x x
020EW
AXAB x x x x x x
AXAA x x x x x x
025EW
AXAB x x x x x x
3
Application Inf
pplication or
Infor ma
orma tion
mation
General Installation Guide
System Configuration
The standard controller board (W2) comes with a VALVE jumper and a HEAT jumper. The system can be
configured as the jumper selection listed below:
HEAT Jumper VALVE Jumper
Heatpump Mode & Valve Application ¥ ¥
Heatpump Mode & Valveless Application ¥ X
Cooling Mode & Valve Application X ¥
Cooling Mode & Valveless Application X X
CAUTION !
CAUTION
Disconnect the power supply to the unit before attempting to connect the wiring
10
Model : MWM 020 / 025GW (IONIZER)
11
MCK-AWH 4 pipes system controller board setting
A) Model selection
The standard controller board (W2.0) comes with a default setting for model selection. Please select the model
accordingly by using jumper.
12
B) Valve, Heat and Fan priority selection
C) Others
i) Unoccupied Mode
If the dry contact is closed, the Unoccupied mode is activated and vice versa. When Timer On is active, system
goes back to Occupied mode.
The dry contact connection points can be connected parallel with other fan coil unit (FCU) boards. If the dry
contact is closed, Unoccupied mode will be activated on all fan coil units that are connected parallel as shown in
figure below.
13
ii) Anti Freeze Mode
Anti Freeze operation has the highest priority among all unit operation. Anti Freeze operation will be activated
only if dry contact is closed and vice versa.
The dry contact connection points can be connected in parallel with other fan coil unit (FCU) boards. If the dry
contact is closed, Window open mode will be activated on all the fan coil units which are connected in parallel as
shown in figure below.
The dry contact connection points can be connected in parallel with other fan coil unit (FCU) boards. If the dry
contact is closed, Load shedding mode will be activated on all the fan coil units which are connected in parallel
as shown in figure below.
Global Unoccupied, Global Window Open and Global Load Shedding operation could also be activated via the
network communication bus line by master controller with or without the above connection.
NOTE :
i) Auto Fan Mode is only applicable in Model 3 only. ( Cooling only with Boiler)
iii) Wired handset (Netware and SLM) has an indoor room sensor. Avoid locating the wired handset at isolated
places where room temperature reading will be inaccurate.
14
Water Piping Connection
The indoor unit is equipped with water outlet and inlet bare connection. There is an air-vent for air purging that is
fitted at the outlet water header.
3 ways solenoid valve is required for cycling off or bypass the chilled water.
Black steel pipe, polyethrene pipe, PVC pipe and copper tube recommended in field installation.
All types of piping and connection must be insulated by polyurethane (ARMAFLEX type or equivalent) to avoid
condensation.
Some main fitting components are needed in the system to enhance the capacity and ease of service, such as
gate valve, balancing valve, 2 ways or 3 ways solenoid valve, filter, strainer etc.
15
Preliminary Site Survey
Electrical supply and installation is to conform to LOCAL AUTHORITY's (e.g. National Electricity Board) CODES
and REGULATIONS.
Voltage supply fluctuation must not exceed ± 10% of rated voltage. Electricity supply lines must be independent
of welding transformers which can cause supply fluctuation.
Mounting
For ceiling mounted models, locate a position where piping and ducting work can be kept to a minimum.
Ensure that overhead supports are strong enough to hold the unit's weight. Position hanger rods and check for
alignment with the unit. Check that hangers are secure and that the base of fan coil unit is level in two horizontal
positions.
Piping
Drain and water piping must be accurately connected.
Piping Support
All water mains must be adequately supported to carry the necessary weight involved, provisions must be
made by the installing contractor to allow for adequate free movement of all vertical and horizontal risers and
run outs. Due to the fact that cold water will be circulated through the water mains, a sizeable movement of the
water mains can be expected due to contraction. If for example, the piping is rigidly supported with no provision
for movement, it is very possible that the tubing of fitting may be broken causing water leakage in the condi-
tioned spaces throughout the building.
Coil Venting
Each standard basic unit coil is equipped with a manually operated air vent which is installed at the end of a
small copper line leading into the highest point of the coil. By means of this valve, air may be vented manually,
from the coil to keep it operating at full capacity. When water is first introduced into a coil, air is sometimes
trapped in the coil tubing. This trapped air will reduce cooling capacity and create "Bubbling" or "Clanking"
noise within the units. To release air trapped in the coil, press the air vent head to allow air to flow out of the air
vent opening. Release when a steady stream of water appear.
Electrical Connection
As wiring regulations differ from country to country, please refer to your LOCAL ELECTRICAL CODES for field
wiring regulations and ensure that they are complied with. Besides, take note of the following general precau-
tion:
1) Ensure that the rated voltage of the unit corresponds to the name plate before commencing wiring work.
2) Provide a power outlet to be used exclusively for each unit and a power supply disconnect and a circuit-
breaker for over-current protection should be provided in the exclusive line.
3) The unit must be EARTH to prevent possible hazards due to insulation failure.
16
General Operation Guide
Start-Up
The following procedure must be completed before any attempts is made to put the entire system Into opera-
tion:
Air Filters
The function of the air filters is to remove foreign matter such as dirt, soot, pollen and certain other impurities
from the air passing through it. A clogged or dirty filter not only fails to do the job for which it is designed, but
restricts the flow of air over the coil.
The importance of cleaning the filter before it becomes clogged must be greatly stressed. The frequency with
which a filter should be cleaned will depend upon the amount of dust and foreign material that enters a unit, and
this depends upon location and situation.
The washable viledon or saranet filter may be cleaned by tapping the filter on a solid surface to dislodge heavy
particles. Wash under stream of warm water, with detergent if necessary. Dry it thoroughly before replacing.
Fan Motor
The fan motor is pre-lubricated and sealed at the factory. Therefore, no lubricating maintenance is required.
Coils
Clean coil unit by brushing between fins with a nylon brush. Brushing should be followed by cleaning with a
vacuum cleaner. The coil may also be cleaned by using a high pressure air hose and nozzle if a compressed air
source is available. It should be pointed out that if suitable air filter is used and taken care of properly, the coils
need no cleaning.
Drain Pipe
The drain pipe should be checked before operation of unit is begun. If it is clogged, steps should be taken to
clean the debris so that condensate will flow out easily.
Replacement Of Parts
Replacement of parts are available through your local dealers. When ordering parts, you must supply
1) Model name of the unit.
2) Serial number of the unit.
3) Part name and number.
17
Controller
18
Sound Data
Data
Sound Pressure Level
1/1 Octave Sound pressure level (dB, ref 20PPa) Overall Noise
Model Speed
125Hz 250Hz 500Hz 1kHz 2kHz 4kHz 8kHz A (dBA) Criteria
High 26 34 38 42 38 35 23 45 41
MCM007CBW Medium 23 29 36 39 34 31 18 42 38
Low 19 26 33 34 31 23 12 37 33
High 27 35 39 43 39 36 24 46 42
MCM010CBW Medium 24 30 37 40 35 32 19 43 39
Low 20 27 34 35 32 24 13 38 34
High 28 36 40 44 40 37 25 47 43
MCM015CBW Medium 25 31 38 41 36 33 20 44 40
Low 21 28 35 36 33 25 13 39 35
Microphone position : 1m in front and 0.8m below the vertical centre line of the unit.
26
Water Flow Vs Pressure Drop
44
Correction Factors
Notes : Adjusted capacity, W (@ Nominal air flow) = base heating capacity (@ nominal 60°C EWT, 21.1°C EAT) x Heating Capacity
Correction Factor
49
General Data - MCM-DW
1) ALL SPECIFICATIONS ARE SUBJECTED TO CHANGE BY THE MANUFACTURER WITHOUT PRIOR NOTICE.
2) ALL UNITS ARE BEING TESTED AND COMPLY TO ISO 5151 & ISO13253.
3) NOMINAL COOLING AND HEATING CAPACITY ARE BASED ON THE CONDITIONS BELOW :
a) COOLING - ENTERING AIR TEMP. : 27°C (80.6°F) DB / 19°C (66.2°F) WB, ENTERING WATER TEMP. : 7°C (44.6°F), LEAVING WATER TEMP. : 12°C (53.6°F)
b) HEATING - ENTERING AIR TEMP.: 20°C (68°F) DB, ENTERING WATER TEMP. : 50°C (122°F), WATER FLOW RATE BASED ON COOLING CYCLE.
4) SOUND PRESSURE LEVEL ARE ACCORDING TO JIS C 9612 STANDARD. MCM020/025DW : POSITION OF THE MEASUREMENT POINT IS 1m IN FRONT
AND 0.8m BELOW THE VERTICAL CENTRE LINE OF THE UNIT. MCM030/040/050DW : POSITION OF THE MEASUREMENT POINT IS 1m IN FRONT
AND 1m BELOW THE VERTICAL CENTRE LINE OF THE UNIT (JIS B 8615)
61
General Data - MCM-DW
1) ALL SPECIFICATIONS ARE SUBJECTED TO CHANGE BY THE MANUFACTURER WITHOUT PRIOR NOTICE.
2) ALL UNITS ARE BEING TESTED AND COMPLY TO ISO 5151 & ISO13253.
3) NOMINAL COOLING AND HEATING CAPACITY ARE BASED ON THE CONDITIONS BELOW :
a) COOLING - ENTERING AIR TEMP. : 27°C (80.6°F) DB / 19°C (66.2°F) WB, ENTERING WATER TEMP. : 7°C (44.6°F), LEAVING WATER TEMP. : 12°C (53.6°F)
b) HEATING - ENTERING AIR TEMP.: 20°C (68°F) DB, ENTERING WATER TEMP. : 50°C (122°F), WATER FLOW RATE BASED ON COOLING CYCLE.
4) SOUND PRESSURE LEVEL ARE ACCORDING TO JIS C 9612 STANDARD. MCM020/025DW : POSITION OF THE MEASUREMENT POINT IS 1m IN FRONT
AND 0.8m BELOW THE VERTICAL CENTRE LINE OF THE UNIT. MCM030/040/050DW : POSITION OF THE MEASUREMENT POINT IS 1m IN FRONT
AND 1m BELOW THE VERTICAL CENTRE LINE OF THE UNIT (JIS B 8615)
62
General Data - MCM-DW
1) ALL SPECIFICATIONS ARE SUBJECTED TO CHANGE BY THE MANUFACTURER WITHOUT PRIOR NOTICE.
2) ALL UNITS ARE BEING TESTED AND COMPLY TO ISO 5151 & ISO13253.
3) NOMINAL COOLING AND HEATING CAPACITY ARE BASED ON THE CONDITIONS BELOW :
a) COOLING - ENTERING AIR TEMP. : 27°C (80.6°F) DB / 19°C (66.2°F) WB, ENTERING WATER TEMP. : 7°C (44.6°F), LEAVING WATER TEMP. : 12°C (53.6°F)
b) HEATING - ENTERING AIR TEMP.: 20°C (68°F) DB, ENTERING WATER TEMP. : 50°C (122°F), WATER FLOW RATE BASED ON COOLING CYCLE.
4) SOUND PRESSURE LEVEL ARE ACCORDING TO JIS C 9612 STANDARD. MCM020/025DW : POSITION OF THE MEASUREMENT POINT IS 1m IN FRONT
AND 0.8m BELOW THE VERTICAL CENTRE LINE OF THE UNIT. MCM030/040/050DW : POSITION OF THE MEASUREMENT POINT IS 1m IN FRONT
AND 1m BELOW THE VERTICAL CENTRE LINE OF THE UNIT (JIS B 8615)
63
General Data - MCM-CBW
1) ALL SPECIFICATIONS ARE SUBJECTED TO CHANGE BY THE MANUFACTURER WITHOUT PRIOR NOTICE.
2) ALL UNITS ARE BEING TESTED AND COMPLY TO ISO 5151 & ISO13253.
3) NOMINAL COOLING AND HEATING CAPACITY ARE BASED ON THE CONDITIONS BELOW :
a) COOLING - ENTERING AIR TEMP. : 27°C (80.6°F) DB / 19°C (66.2°F) WB, ENTERING WATER TEMP. : 7°C (44.6°F), LEAVING WATER TEMP. : 12°C (53.6°F)
b) HEATING - ENTERING AIR TEMP.: 20°C (68°F) DB, ENTERING WATER TEMP. : 50°C (122°F), WATER FLOW RATE BASED ON COOLING CYCLE.
4) SOUND PRESSURE LEVEL ARE TESTED AT 1m IN FRONT AND 0.8m BELOW THE VERTICAL CENTRE LINE OF THE UNIT.
64
General Data - MCM-CBW
1) ALL SPECIFICATIONS ARE SUBJECTED TO CHANGE BY THE MANUFACTURER WITHOUT PRIOR NOTICE.
2) ALL UNITS ARE BEING TESTED AND COMPLY TO ISO 5151 & ISO13253.
3) NOMINAL COOLING AND HEATING CAPACITY ARE BASED ON THE CONDITIONS BELOW :
a) COOLING - ENTERING AIR TEMP. : 27°C (80.6°F) DB / 19°C (66.2°F) WB, ENTERING WATER TEMP. : 7°C (44.6°F), LEAVING WATER TEMP. : 12°C (53.6°F)
b) HEATING - ENTERING AIR TEMP.: 20°C (68°F) DB, ENTERING WATER TEMP. : 50°C (122°F), WATER FLOW RATE BASED ON COOLING CYCLE.
4) SOUND PRESSURE LEVEL ARE TESTED AT 1m IN FRONT AND 0.8m BELOW THE VERTICAL CENTRE LINE OF THE UNIT.
65
General Data - MCM-EW
1) ALL SPECIFICATIONS ARE SUBJECTED TO CHANGE BY THE MANUFACTURER WITHOUT PRIOR NOTICE.
2) ALL UNITS ARE BEING TESTED AND COMPLY TO ISO 5151 & ISO13253.
3) NOMINAL COOLING AND HEATING CAPACITY ARE BASED ON THE CONDITIONS BELOW :
a) COOLING - ENTERING AIR TEMP. : 27°C (80.6°F) DB / 19°C (66.2°F) WB, ENTERING WATER TEMP. : 7°C (44.6°F), LEAVING WATER TEMP. : 12°C (53.6°F)
b) HEATING - ENTERING AIR TEMP.: 20°C (68°F) DB, ENTERING WATER TEMP. : 50°C (122°F), WATER FLOW RATE BASED ON COOLING CYCLE.
4) SOUND PRESSURE LEVEL ARE TESTED AT 1m IN FRONT AND 0.8m BELOW THE VERTICAL CENTRE LINE OF THE UNIT.
66
General Data - MCM-EW
1) ALL SPECIFICATIONS ARE SUBJECTED TO CHANGE BY THE MANUFACTURER WITHOUT PRIOR NOTICE.
2) ALL UNITS ARE BEING TESTED AND COMPLY TO ISO 5151 & ISO13253.
3) NOMINAL COOLING AND HEATING CAPACITY ARE BASED ON THE CONDITIONS BELOW :
a) COOLING - ENTERING AIR TEMP. : 27°C (80.6°F) DB / 19°C (66.2°F) WB, ENTERING WATER TEMP. : 7°C (44.6°F), LEAVING WATER TEMP. : 12°C (53.6°F)
b) HEATING - ENTERING AIR TEMP.: 20°C (68°F) DB, ENTERING WATER TEMP. : 50°C (122°F), WATER FLOW RATE BASED ON COOLING CYCLE.
4) SOUND PRESSURE LEVEL ARE TESTED AT 1m IN FRONT AND 0.8m BELOW THE VERTICAL CENTRE LINE OF THE UNIT.
67
Components Data - MCM-DW
1) ALL SPECIFICATIONS ARE SUBJECTED TO CHANGE BY THE MANUFACTURER WITHOUT PRIOR NOTICE.
82
Components Data - MCM-DW
1) ALL SPECIFICATIONS ARE SUBJECTED TO CHANGE BY THE MANUFACTURER WITHOUT PRIOR NOTICE.
83
Components Data - MCM-CBW
1) ALL SPECIFICATIONS ARE SUBJECTED TO CHANGE BY THE MANUFACTURER WITHOUT PRIOR NOTICE.
84
Components Data - MCM-EW
1) ALL SPECIFICATIONS ARE SUBJECTED TO CHANGE BY THE MANUFACTURER WITHOUT PRIOR NOTICE.
85
Perfor
erfor mance Da
ormance ta
Data
Unit Selection Procedure
The cooling and heating capacities of the fan coil units can be determined by the Cooling Capacity Perfor-
mance Chart and Heating Capacity Performance Chart in the following pages based on nominal air flow at
standard water temperature. The total and sensible capacities must be adjusted as variables come in. A sample
of selection procedure is given as below:
Step 1
Determine type of fan coil units to be used, i.e. ceiling cassette (MCK-AW Series); ceiling exposed (MCM-DW
Series); etc.
Step 2
Select a tentative unit size based on cooling capacities at nominal air flow. Design entering air temperatures
and required water flows from cooling capacities chart (Page 93 - 136) or the nominal capacities ratings (Page
50 - 74) from standard specification.
Step 3
Determine the nominal unit cooling capacities for the unit selected. If the cooling capacities chart must be used,
the following information must be known :-
MCK050AW (ISO)
90
Step 4
If air flow value is different from the nominal value(high speed), then refer to specification from Page 50 to 74 for
the air flow required (medium or low speed). Determine the total and sensible correction factor from Air Flow
Capacity Correction Factor (Page 49).
Step 5
If the unit is to operate at an altitude above sea level, multiply the capacity correction factors by an Altitude
Correction Factors. Refer to Page 49.
Step 6
Calculate the actual cooling capacity by multiply the nominal capacity (from Step 3) with Air Flow Capacity
Correction Factor from Step 4 and the Altitude Correction Factor from Step 5.
Actual Capacity, W = Nominal capacity (Step 3) x Air Flow Capacity Correction Factor (Step 4)
x Altitude Correction Factor (Step 5)
Step 7
Water flow rate can be determined by:
Step 8
Heating Capacities at nominal air flow (Page 137 to 141 - Heating Performance Chart) are based on standard
condition of 60°C EWT and 21°C EAT. The actual heating capacity can be obtained by using the Heating
Capacity Correction Factor (Page 49) and Altitude Correction Factor as per Step 5.
Step 9
Water Pressure Drop Tables are on Page 43 to 48.
EXAMPLE
Select a ceiling cassette type fan coil unit at the following design specification:
SOLUTION
Step 1
Based on the type of fan coil required and the design conditions, tentatively select MCK050AW. From the
cooling capacity performance chart (Page 114), at 26.7°C DB / 19°C WB air temperature, 7°C entering water
temperature and with 5°C water temperature rise, the cooling capacity for this unit is 11.7 kW total capacity and
8.5 kW sensible capacity.
91
Step 2
From page 49, the air flow correction factor table, at high speed, the air volume is 1040 CFM and medium speed
is 950 CFM, hence high speed is selected. And the correction factor is hence 1.0.
If lower air flow required, then use the medium and low fan speed. The correction factor can be determined by
getting the ratio of air flow (i.e. medium or low speed / high speed).
Step 3
As the unit is operating at 600m above sea level, the Altitude correction factor is 0.98 total and 0.93 sensible.
Step 4
Multiply the cooling capacities obtained from step 1 (as per specification and design condition) by correction
factors from (2) and (3)
Step 5
Water flow rate = Litres/M = 11470 W = 32.8
70 x 5
Step 6
From Heating Capacity Performance Chart (Page 138), determine the heating capacity at the nominal air
volume by using the flow rate calculated in step 5. The heating capacity is at 20.6 kW.
MCK-AW
MCK050AW
21.00
MCK040AW
Heating Capacity (kW)
19.00
MCK030AW
17.00
MCK025AW
MCK020AW
15.00
13.00
12.00 14.00 16.00 18.00 20.00 22.00 24.00 26.00 28.00 30.00 32.00 34.00 36.00 38.00 40.00
Water Flowrate - L/min
Step 7
From Heating Capacity Correction Factor Tables at 70°C water entering temperature and 26.7°C entering air
temperature, the correction factor is 1.1261,
Step 8
Water Pressure Drop can be estimated from water Pressure Drop Table (Page 43 to 48) using interpolate
method:
At flow rate of 32.8 Litres/Min, the nominal pressure drop is 39.14 kPa
Pressure drop correction factor = 1.2947 - 0.0021 x (EWT°C x 1.8 + 32) = 0.9629
Hence the actual pressure drop = nominal pressure drop x correction factor = 37.69 kPa.
92
MCM020DW
99
MCM025DW
100
MCM030DW
101
MCM040DW
102
MCM050DW
103
MCM007CBW
104
MCM010CBW
105
MCM015CBW
106
MCM015EW
107
MCM020EW
108
MCM025EW
109
Heating Capacity Performance Chart
26.0
MCM050DW
24.0
22.0 MCM040DW
Heating Capacity (kW)
20.0
18.0
16.0
MCM030DW
14.0
MCM025DW
12.0
MCM020DW
10.0
8.0 12.0 16.0 20.0 24.0 28.0 32.0 36.0 40.0 44.0 48.0
Water Flowrate (L/min)
137
MCM-EW
21.00
MCK050AW
MCK040AW
Heating Capacity (kW)
19.00
MCK030AW
17.00
MCK025AW
15.00 MCK020AW
13.00
12.00 14.00 16.00 18.00 20.00 22.00 24.00 26.00 28.00 30.00 32.00 34.00 36.00 38.00 40.00
Water Flow rate - L/m in
138
Indoor Unit
Model : MCM 020 / 025 DW
Dimension in mm
Indoor Unit
Model : MCM 030 / 040 / 050 DW
MODEL A B C D E F G H I J K L M N O P Q
MCM030DW 1174 75 1082 68 93 156 1214 57 670 216 319 879 517 100 47 100 53
MCM040DW 1674 75 1582 68 93 156 1714 57 670 216 319 1379 517 95 40 100 45
MCM050DW 1674 75 1582 68 93 156 1714 57 670 216 319 1379 517 95 40 100 45
Dimension in mm
144
Indoor Unit
Model : MCM 007 / 010 / 015 CBW
MODEL A (GRILL) B C D E F G H I J K L M N O
MCM 007CBW 700 40 36 853 780 680 352 292 235 140 830 250 50 100 120
MCM 010CBW 700 40 36 853 780 680 352 292 235 140 830 250 50 100 120
MCM 015CBW 1050 40 36 1203 1130 680 352 292 235 140 1180 250 50 100 120
Dimension in mm
Indoor Unit
Model : MCM 015 / 020 / 025 EW
Dimension in mm
145
MCM-DW
1) ALL SPECIFICATIONS ARE SUBJECTED TO CHANGE BY THE MANUFACTURER WITHOUT PRIOR NOTICE.
2) ALL UNITS ARE BEING TESTED AND COMPLY TO ISO 5151.
MCM-CBW
1) ALL SPECIFICATIONS ARE SUBJECTED TO CHANGE BY THE MANUFACTURER WITHOUT PRIOR NOTICE.
2) ALL UNITS ARE BEING TESTED AND COMPLY TO ISO 5151.
162
MCM-EW
1) ALL SPECIFICATIONS ARE SUBJECTED TO CHANGE BY THE MANUFACTURER WITHOUT PRIOR NOTICE.
2) ALL UNITS ARE BEING TESTED AND COMPLY TO ISO 5151.
MCC-CW
1) ALL SPECIFICATIONS ARE SUBJECTED TO CHANGE BY THE MANUFACTURER WITHOUT PRIOR NOTICE.
2) ALL UNITS ARE BEING TESTED AND COMPLY TO ISO 5151.
163
Model : MCM 020 / 025 / 030 / 040 / 050DW
169
Model : MCM 010 CBW
170
Model : MCM 020 / 025 DW
179
Model : MCM 030 DW
1) ALL SPECIFICATIONS ARE SUBJECT TO CHANGE BY THE MANUFACTURER WITHOUT PRIOR NOTICE
180
Model : MCM 040 / 050 DW
1) ALL SPECIFICATIONS ARE SUBJECT TO CHANGE BY THE MANUFACTURER WITHOUT PRIOR NOTICE
181
Model : MCM 015 / 020 / 025 EW
182