Post on 17-Mar-2021
is a registered trademark of Fuji Electric Co., Ltd.
●F–COOL NEO is in continuous operation at Fuji Electric’s data center demonstration laboratory located in our Kawasaki factory,in Japan and it is possible to visit this facility.
●As an optional function, it is possible to start or stop the F-COOL NEO, and set the supply air (SA) temperature and air flow rate by means of a higher-level building management system. ●In order to ensure the reliability required of data center facilities, we recommend operating with N+1 redundancy (for a TIER 2* data center) or N+1 or more redundancy (for a TIER 3 & 4* data center). N+1 redundancy means, after the total necessary cooling capacity is divided by the rated cooling capacity of the type of air conditioner unit (for example, 40 kW) to be used, where N is the total number of units required, N+1 adds an additional unit to the total number to be installed as a safety margin for redundancy. ●Please perform a daily inspection according to the instruction manual that comes with the delivered product. Also in addition to this normal day-to-day inspection, we recommend a contract for periodic maintenance and inspections.
Indirect Outside Air-cooling Unit
Redundant Operation and Maintenance
Demonstration Equipment
Modular–type data center
Server racks
●
®
®
*: Standards for Data Center from ANSI/TIA-942-A-2012.
(Option)
Gate City Ohsaki, East Tower, 11-2, Osaki 1-chome, Shinagawa-ku, Tokyo 141-0032, JapanPhone : +81-3-5435-7111
Internet address : http://www.fujielectric.comInformation in this catalog is subject to change without notice. 2017-6(F2017b/I2014)4EP/FOLS Printed in Japan 09G1-E-0021b
Notes:*1: Coefficient of Performance = Cooling capacity (kW) / Power consumption of air conditioner (kW). The larger the COP, is the better the efficiency.*2: Assuming that COP = 3.5 for a general air conditioner.*3: Alternative values of the actual emission coefficients for each electric utility company in FY2011 as announced by the Ministry of the Environment, Goverment of Japan.
Cooling capacity: 40 kW, Supply air (SA) temperature: 26°C, Supply air (SA) flow rate: 8500 m3/h, Outside air (OA): Monthly mean temperature of Tokyo. Carbon dioxide basic unit*3: 0.55 kg–CO2/kWh
is an air-cooling system that cools in directly without needing to introduce outside air directly into indoor areas.By taking advantage of outside air energy all throughout the year, F-COOL NEO makes possible significantly greater energy-savingoperations compared with the use of general air conditioners.
Possible carbon dioxide reductions and energysavings throughout the year●Coefficient of performance (COP*1) =10 (annual average in Tokyo)
●Possible reduction in electricity charges is about 123 million USD per year
●Possible reduction in carbon dioxide is about 36 tons per year
About 65% savings in energy compared with general air conditioners*2
®
●The indirect outside air cooling circuit that drives the sensible heat exchanger and the refrigeration cooling circuit that is driven by the compressor are integrated in the unit. (Integrated type 40 kW)
Indirect outdoor air cooling operates without introducing outside air directlyso there is no need for concern about the indoor areas being contaminated from the outside such as by dust (PM 2.5), SOx, or NOx.
Indoor unit Outdoor unit Indoor unit Outdoor unit
Item
Model
Rated cooling capacity
Coefficient of performance
Cooling method
External dimensions
Product mass
Power supply
Installationexample
*: ( ) is installed on the side of a control panel.
Unit
kW
m3/h
℃
℃
mm
mm
mm
kg
Integrated type 40 kW
FCA–40 A
40
Rating 8500(variable from 2500 to 12000)
Rating 26 (18 to 35)
±2(At stable operation, in accordance with JIS Z 8402-1)
Annual average COP 10 (Tokyo)
Indirect outside air cooling (brine circulation) +Refrigeration cooling (R410A refrigerant circulation)
1200
2200
2700
1000
3-phase, 3w 200 or 400 V50/60 Hz
Separate type 40 kW Indoor unit
FCA–SI–40A
40
Rating 8500(variable from 2500 to 12000)
Rating 26 (18 to 35)
±2(At stable operation, in accordance with JIS Z 8402-1)
Annual average COP 9 (Tokyo)
Indirect outside air cooling (brine circulation) +Refrigeration cooling (R410A refrigerant circulation)
1200
1200
2300
440
3-phase, 3w 200 or 400 V50/60 Hz
Outdoor unit
FCA–SO–40A
1200
1000
2700
580
Separate type 56 kW Indoor unit
FCA–SI–56A
56
Rating 12000(variable from 2500 to 16800)
Rating 26 (18 to 35)
±2(At stable operation, in accordance with JIS Z 8402-1)
Annual average COP 9 (Tokyo)
Indirect outside air cooling (brine circulation) +Refrigeration cooling (R410A refrigerant circulation)
1200
1600
2700
680
3-phase, 3w 400 V50/60 Hz
Outdoor unit
FCA–SO–56A
1200 (1500)*
1900 (1600)*
2300
740
F-COOL NEO(Outdoor unit)
F-COOL NEO(Indoor unit)
F-COOL NEO(Outdoor unit)
F-COOL NEO(Indoor unit)
W
D
H
Hot area
Cold area Cold area Cold area
Return air (RA) Hot area Return air (RA) Hot area Return air (RA)
Supply air(SA)
Supply air(SA)
Supply air(SA)
Outside air (OA)
Outsideair
(OA) Outsideair
(OA)
Exhaust air(EA)
Exhaust air(EA)
Exhaust air(EA)
Supplyair
Volume setting
Temperature setting
Temperature precision
Specification
Method of Operation (HMI)
Operation start and stop are performed using the included Programmable Operation Display (POD).●Supply air (SA) temperature and flow rate can be set.●Operation and alarm history logs can be viewed.
POD (HMI) display
Operation display
Operation and alarm history display
Internal Structure Diagram
Return air (RA) Return air (RA)Outside air (OA)
Outside air (OA)Inside air fan Outside air fanInside air Outside air
Pump
Sensible heat exchanger
Sensible heat exchanger
Exhaust air (EA)
Exhaust air (EA)
Condenser
Compressor
Evaporator
Expansion valve
Refrigeration cooling circuit (Circulated refrigerant: R410A)
Indirect outside air cooling circuit (Circulated refrigerant: brine)
Supply air (SA)
Supply air (SA)
1 2
Notes:*1: Coefficient of Performance = Cooling capacity (kW) / Power consumption of air conditioner (kW). The larger the COP, is the better the efficiency.*2: Assuming that COP = 3.5 for a general air conditioner.*3: Alternative values of the actual emission coefficients for each electric utility company in FY2011 as announced by the Ministry of the Environment, Goverment of Japan.
Cooling capacity: 40 kW, Supply air (SA) temperature: 26°C, Supply air (SA) flow rate: 8500 m3/h, Outside air (OA): Monthly mean temperature of Tokyo. Carbon dioxide basic unit*3: 0.55 kg–CO2/kWh
is an air-cooling system that cools in directly without needing to introduce outside air directly into indoor areas.By taking advantage of outside air energy all throughout the year, F-COOL NEO makes possible significantly greater energy-savingoperations compared with the use of general air conditioners.
Possible carbon dioxide reductions and energysavings throughout the year●Coefficient of performance (COP*1) =10 (annual average in Tokyo)
●Possible reduction in electricity charges is about 123 million USD per year
●Possible reduction in carbon dioxide is about 36 tons per year
About 65% savings in energy compared with general air conditioners*2
®
●The indirect outside air cooling circuit that drives the sensible heat exchanger and the refrigeration cooling circuit that is driven by the compressor are integrated in the unit. (Integrated type 40 kW)
Indirect outdoor air cooling operates without introducing outside air directlyso there is no need for concern about the indoor areas being contaminated from the outside such as by dust (PM 2.5), SOx, or NOx.
Indoor unit Outdoor unit Indoor unit Outdoor unit
Item
Model
Rated cooling capacity
Coefficient of performance
Cooling method
External dimensions
Product mass
Power supply
Installationexample
*: ( ) is installed on the side of a control panel.
Unit
kW
m3/h
℃
℃
mm
mm
mm
kg
Integrated type 40 kW
FCA–40 A
40
Rating 8500(variable from 2500 to 12000)
Rating 26 (18 to 35)
±2(At stable operation, in accordance with JIS Z 8402-1)
Annual average COP 10 (Tokyo)
Indirect outside air cooling (brine circulation) +Refrigeration cooling (R410A refrigerant circulation)
1200
2200
2700
1000
3-phase, 3w 200 or 400 V50/60 Hz
Separate type 40 kW Indoor unit
FCA–SI–40A
40
Rating 8500(variable from 2500 to 12000)
Rating 26 (18 to 35)
±2(At stable operation, in accordance with JIS Z 8402-1)
Annual average COP 9 (Tokyo)
Indirect outside air cooling (brine circulation) +Refrigeration cooling (R410A refrigerant circulation)
1200
1200
2300
440
3-phase, 3w 200 or 400 V50/60 Hz
Outdoor unit
FCA–SO–40A
1200
1000
2700
580
Separate type 56 kW Indoor unit
FCA–SI–56A
56
Rating 12000(variable from 2500 to 16800)
Rating 26 (18 to 35)
±2(At stable operation, in accordance with JIS Z 8402-1)
Annual average COP 9 (Tokyo)
Indirect outside air cooling (brine circulation) +Refrigeration cooling (R410A refrigerant circulation)
1200
1600
2700
680
3-phase, 3w 400 V50/60 Hz
Outdoor unit
FCA–SO–56A
1200 (1500)*
1900 (1600)*
2300
740
F-COOL NEO(Outdoor unit)
F-COOL NEO(Indoor unit)
F-COOL NEO(Outdoor unit)
F-COOL NEO(Indoor unit)
W
D
H
Hot area
Cold area Cold area Cold area
Return air (RA) Hot area Return air (RA) Hot area Return air (RA)
Supply air(SA)
Supply air(SA)
Supply air(SA)
Outside air (OA)
Outsideair
(OA) Outsideair
(OA)
Exhaust air(EA)
Exhaust air(EA)
Exhaust air(EA)
Supplyair
Volume setting
Temperature setting
Temperature precision
Specification
Method of Operation (HMI)
Operation start and stop are performed using the included Programmable Operation Display (POD).●Supply air (SA) temperature and flow rate can be set.●Operation and alarm history logs can be viewed.
POD (HMI) display
Operation display
Operation and alarm history display
Internal Structure Diagram
Return air (RA) Return air (RA)Outside air (OA)
Outside air (OA)Inside air fan Outside air fanInside air Outside air
Pump
Sensible heat exchanger
Sensible heat exchanger
Exhaust air (EA)
Exhaust air (EA)
Condenser
Compressor
Evaporator
Expansion valve
Refrigeration cooling circuit (Circulated refrigerant: R410A)
Indirect outside air cooling circuit (Circulated refrigerant: brine)
Supply air (SA)
Supply air (SA)
1 2
Indirect outsideair cooling
Refrigerationcooling
Indirect outside air +Refrigeration cooling (hybrid operation)
Rat
ed c
apac
ity
Low ← Outside air temperature → High
Indirect outside air cooling
Refrigeration cooling
Maintains the cooling capacity regardlessof the outside air temperature!
Automatic control in response tochanges in outside air temperature
Jan Feb Mar Apr May Jun Jul Aug Sep Oct Nov Dec–10(14)
0(32)
10(50)
20(68)
30(86)
40(104)
Refrigeration cooling circuit
Indirect outside air cooling circuit
Refrigeration cooling circuit
Indirect outside air cooling circuit
Returnair(RA)
Outsideair (OA)
Pump
Exhaust air (EA)
Compressor Compressor Compressor
Supplyair (SA)
Returnair(RA)
Outsideair (OA)
Pump
Exhaust air (EA)
Supplyair (SA)
Refrigeration cooling circuit
Indirect outside air cooling circuit
Returnair(RA)
Outsideair (OA)
Pump
Exhaust air (EA)
Supplyair (SA)
Aver
age
mon
thly
tem
pera
ture
[°C
] / C
OP
[ – ]
[°F ]
/ CO
P [ –
]
pPUE(partial Power Useage Effectiveness)*
COP CharacteristicsAutomatic Switching of Cooling Mode
Relationship Between Outside Air Temperature and Cooling Mode
Operation Mode in Various Locations
*
25
20
15
10
5
0–10 0 10 20 30 40 50(14) (32) (50) (68) (86) (104) (122)
●Depending on the outside air temperature, the unit automatically switches to one of three cooling modes.
●Depending on the outside air temperature, the unit automatically switches to one of three cooling modes.
●Operation mode in each location when operating at cooling capacity of 40 kW, supply air (SA) temperature of 26°C, and return air (RA) temperature of 40°C. The lower the outside temperature is, the more energy savings are possible using the indirect outside air cooling mode. Note: Performance varies depending on the SA and RA temperature conditions.
●The pPUE of major cities around the world is shown below.(1981 to 2010) (Source: Japan Meteorological Agency website.〔http://www.data.jma.go.jp/gmd/cpd/monitor/climfig/?tm=normal&el=tn〕)
CO
P [ –
]
[°C]
[°C][°F]
Average temperature in Kuala LumpurAverage temperature in TokyoAverage temperature in New YorkKuala Lumpur COP (annual average 6.2)Tokyo COP (annual average 10.2)New York COP (annual average 11.6)
△T = 14 K, supply air: 8500 m3/h△T = 12 K, supply air: 10000 m3/h△T = 10 K, supply air: 12000 m3/h
Other common conditions:Supply air temp. : 26°CCooling capacity: 40 kW
JanuaryMaySeptember
FebruaryJuneOctober
MarchJulyNovember
AprilAugustDecember
Indirect outside air cooling mode Refrigeration cooling modeIndirect outside air +
Refrigeration cooling mode(hybrid operation)
Indirect outsideair cooling
Refrigerationcooling
Refrigerationcooling
Indirect outside air + Refrigeration cooling
(hybrid operation)
Indirect outside air + Refrigeration cooling
(hybrid operation)
●While it is certainly possible in the cool climate of Sapporo, a high COP can also be demonstrated in Tokyo, Kuala Lumpur and New York. (Integrated type 40 kW)
Dry-bulb temperature t [°C]
Abso
lute
hum
idity
× [k
g/kg
(DA)
]
Kuala Lumpur Tokyo New York
Abso
lute
hum
idity
× [k
g/kg
(DA)
]
Abso
lute
hum
idity
× [k
g/kg
(DA)
]
Dry-bulb temperature t [°C] Dry-bulb temperature t [°C]
Note: That in this catalog, rather than the power consumption of the data center as a whole(PUE) , the power consumption of only the air conditioner is determined and displayed as the partial pue (pPUE).
Supply air temp. : 26°CReturn air temp. : 40°CAir flow rate: 8500 m3/hCooling capacity: 40 kW
(℉)Outside air temperature
Note:
is a hybrid cooling only air conditioner system that operates using indirect outside air cooling and refrigeration cooling.In response to changes in outside air temperature, the most energy-saving mode of operation is automatically selected.
®
0 10
20
30
40
50
60
70
80
90
10
0 110
0
5
10
15
20
25
30
10
20
30
40
50
60
70
80 90
0.000
0.005
0.010
0.015
0.020
0.025
0.030
-10 -5 0 5 10 15 20 25 30 35 40 45 50 45 50
0 10
20
30
40
50
60
70
80
90
100 11
0
0
5
10
15
20
25
30
10
20
30
40
50
60
70
80 90
0.000
0.005
0.010
0.015
0.020
0.025
0.030
-10 -5 0 5 10 15 20 25 30 35 40
0 10
20
30
40
50
60
70
80
90
100 11
0
0
5
10
15
20
25
30
10
20
30
40
50
60
70
80 90
0.000
0.005
0.010
0.015
0.020
0.025
0.030
-10 -5 0 5 10 15 20 25 30 35 40 φ[%] φ[%] φ[%]
Hybrid operationmode
Refrigeration cooling mode
Indirect outside aircooling mode
Hybrid operationmode
Refrigeration cooling mode
Indirect outside aircooling mode
Hybrid operationmode
Refrigeration cooling mode
Indirect outside aircooling mode
Moscow1.11
Tokyo1.15
India:Mumbai1.21
New York1.14
Thailand:Bangkok1.22
Malaysia:Kuala Lumpur1.21
30°W90°N
60°N
30°N
30°S
60°S
90°S30°W 0° 30°E 60°E
-20(-4)
-15(5)
-10(14)
-5(23)
0(32)
5(41)
10(50)
15(59)
20(68)
25(77)
30(86)
35(95)
40(104)
90°E 120°E 150°E 180° 150°W 120°W 90°W 60°WCPD/JMA
30°W
0°
90°N
60°N
30°N
30°S
60°S
90°S
0°
0° 30°E 60°E 90°E 120°E 150°E 150°W 120°W 90°W 60°W 30°W180°
43
Indirect outsideair cooling
Refrigerationcooling
Indirect outside air +Refrigeration cooling (hybrid operation)
Rat
ed c
apac
ity
Low ← Outside air temperature → High
Indirect outside air cooling
Refrigeration cooling
Maintains the cooling capacity regardlessof the outside air temperature!
Automatic control in response tochanges in outside air temperature
Jan Feb Mar Apr May Jun Jul Aug Sep Oct Nov Dec–10(14)
0(32)
10(50)
20(68)
30(86)
40(104)
Refrigeration cooling circuit
Indirect outside air cooling circuit
Refrigeration cooling circuit
Indirect outside air cooling circuit
Returnair(RA)
Outsideair (OA)
Pump
Exhaust air (EA)
Compressor Compressor Compressor
Supplyair (SA)
Returnair(RA)
Outsideair (OA)
Pump
Exhaust air (EA)
Supplyair (SA)
Refrigeration cooling circuit
Indirect outside air cooling circuit
Returnair(RA)
Outsideair (OA)
Pump
Exhaust air (EA)
Supplyair (SA)
Aver
age
mon
thly
tem
pera
ture
[°C
] / C
OP
[ – ]
[°F ]
/ CO
P [ –
]
pPUE(partial Power Useage Effectiveness)*
COP CharacteristicsAutomatic Switching of Cooling Mode
Relationship Between Outside Air Temperature and Cooling Mode
Operation Mode in Various Locations
*
25
20
15
10
5
0–10 0 10 20 30 40 50(14) (32) (50) (68) (86) (104) (122)
●Depending on the outside air temperature, the unit automatically switches to one of three cooling modes.
●Depending on the outside air temperature, the unit automatically switches to one of three cooling modes.
●Operation mode in each location when operating at cooling capacity of 40 kW, supply air (SA) temperature of 26°C, and return air (RA) temperature of 40°C. The lower the outside temperature is, the more energy savings are possible using the indirect outside air cooling mode. Note: Performance varies depending on the SA and RA temperature conditions.
●The pPUE of major cities around the world is shown below.(1981 to 2010) (Source: Japan Meteorological Agency website.〔http://www.data.jma.go.jp/gmd/cpd/monitor/climfig/?tm=normal&el=tn〕)
CO
P [ –
]
[°C]
[°C][°F]
Average temperature in Kuala LumpurAverage temperature in TokyoAverage temperature in New YorkKuala Lumpur COP (annual average 6.2)Tokyo COP (annual average 10.2)New York COP (annual average 11.6)
△T = 14 K, supply air: 8500 m3/h△T = 12 K, supply air: 10000 m3/h△T = 10 K, supply air: 12000 m3/h
Other common conditions:Supply air temp. : 26°CCooling capacity: 40 kW
JanuaryMaySeptember
FebruaryJuneOctober
MarchJulyNovember
AprilAugustDecember
Indirect outside air cooling mode Refrigeration cooling modeIndirect outside air +
Refrigeration cooling mode(hybrid operation)
Indirect outsideair cooling
Refrigerationcooling
Refrigerationcooling
Indirect outside air + Refrigeration cooling
(hybrid operation)
Indirect outside air + Refrigeration cooling
(hybrid operation)
●While it is certainly possible in the cool climate of Sapporo, a high COP can also be demonstrated in Tokyo, Kuala Lumpur and New York. (Integrated type 40 kW)
Dry-bulb temperature t [°C]
Abso
lute
hum
idity
× [k
g/kg
(DA)
]
Kuala Lumpur Tokyo New York
Abso
lute
hum
idity
× [k
g/kg
(DA)
]
Abso
lute
hum
idity
× [k
g/kg
(DA)
]
Dry-bulb temperature t [°C] Dry-bulb temperature t [°C]
Note: That in this catalog, rather than the power consumption of the data center as a whole(PUE) , the power consumption of only the air conditioner is determined and displayed as the partial pue (pPUE).
Supply air temp. : 26°CReturn air temp. : 40°CAir flow rate: 8500 m3/hCooling capacity: 40 kW
(℉)Outside air temperature
Note:
is a hybrid cooling only air conditioner system that operates using indirect outside air cooling and refrigeration cooling.In response to changes in outside air temperature, the most energy-saving mode of operation is automatically selected.
®
0 10
20
30
40
50
60
70
80
90
10
0 110
0
5
10
15
20
25
30
10
20
30
40
50
60
70
80 90
0.000
0.005
0.010
0.015
0.020
0.025
0.030
-10 -5 0 5 10 15 20 25 30 35 40 45 50 45 50
0 10
20
30
40
50
60
70
80
90
100 11
0
0
5
10
15
20
25
30
10
20
30
40
50
60
70
80 90
0.000
0.005
0.010
0.015
0.020
0.025
0.030
-10 -5 0 5 10 15 20 25 30 35 40
0 10
20
30
40
50
60
70
80
90
100 11
0
0
5
10
15
20
25
30
10
20
30
40
50
60
70
80 90
0.000
0.005
0.010
0.015
0.020
0.025
0.030
-10 -5 0 5 10 15 20 25 30 35 40 φ[%] φ[%] φ[%]
Hybrid operationmode
Refrigeration cooling mode
Indirect outside aircooling mode
Hybrid operationmode
Refrigeration cooling mode
Indirect outside aircooling mode
Hybrid operationmode
Refrigeration cooling mode
Indirect outside aircooling mode
Moscow1.11
Tokyo1.15
India:Mumbai1.21
New York1.14
Thailand:Bangkok1.22
Malaysia:Kuala Lumpur1.21
30°W90°N
60°N
30°N
30°S
60°S
90°S30°W 0° 30°E 60°E
-20(-4)
-15(5)
-10(14)
-5(23)
0(32)
5(41)
10(50)
15(59)
20(68)
25(77)
30(86)
35(95)
40(104)
90°E 120°E 150°E 180° 150°W 120°W 90°W 60°WCPD/JMA
30°W
0°
90°N
60°N
30°N
30°S
60°S
90°S
0°
0° 30°E 60°E 90°E 120°E 150°E 150°W 120°W 90°W 60°W 30°W180°
43
Examples of Applications
●In such fields that require air conditioned cooling with clean air throughout the entire year, from data centers to precision machining, and foods to pharmaceuticals, F–COOL NEO is the perfect air conditioning system.
Building-Type Data Center
Modular-Type Data Center Container-Type Data Center
●Among the air-conditioning systems that use outside air, an outside air indirect air-conditioning system (F-COOL NEO) is the best.
Comparison with an Air-Conditioning System Using Outside Air
●The process of mixing outside air and exhaust air that is required by a direct outside air air-conditioning system is not required, and the control of humidity is easy (because there are no abrupt changes in humidity). In addition, since the mixing chamber used for the mixing process is also unnecessary, the duct layout can be simplified. ●Since the dust removal filters and the summer-winter switchover of operations that are required by outside air direct air-conditioning system are not required, energy-saving operations are possible all throughout the year.
COP
Use of outside air energy
Risk of water supply outage, water freezing
Maintenance
Space
Workability
Implementation in stages
Symbol legend: ◎ = Best, ○ = Good, △ = Fair, � = Not good
Direct Outside Air System
Refrigerator
Outside air filter (Dust, salt damage)
Humidifier(for indoor humidifier control)
With the , the heat source equipment needed for generalair-conditioning systems is no longer required.Even when compared to outside air direct air-conditioning systems the F‒COOL NEO is a simple system that makes energy-saving operations possible.
®
®
Integrated type Separate type
○
○
×
△
△
△
△
○
△
○
○
○
○
○
◎
◎
◎
○
○
◎
○
◎
◎
◎
○
○
○
◎
Indoor unit Outdoor unit
(Utilize outside air)
Server room Server room
Comparison of Air-Conditioning Systems
Air-cooled packaged unit(PU) system
Centrifugal chiller +Air handling unit system
Indirect outside air air-conditioning system (F-COOL NEO)
Direct outside air-cooling unit®
Exhaust air Exhaust air
Outside air Outside air
Server Server
Indirect outside cooling unit Refrigerator
Indirect outside air-cooling unit
6
Integrated Type Separate Type
Examples of installation for a building-type data center and the flow of air
®
®
® ®
Server room
5
Examples of Applications
●In such fields that require air conditioned cooling with clean air throughout the entire year, from data centers to precision machining, and foods to pharmaceuticals, F–COOL NEO is the perfect air conditioning system.
Building-Type Data Center
Modular-Type Data Center Container-Type Data Center
●Among the air-conditioning systems that use outside air, an outside air indirect air-conditioning system (F-COOL NEO) is the best.
Comparison with an Air-Conditioning System Using Outside Air
●The process of mixing outside air and exhaust air that is required by a direct outside air air-conditioning system is not required, and the control of humidity is easy (because there are no abrupt changes in humidity). In addition, since the mixing chamber used for the mixing process is also unnecessary, the duct layout can be simplified. ●Since the dust removal filters and the summer-winter switchover of operations that are required by outside air direct air-conditioning system are not required, energy-saving operations are possible all throughout the year.
COP
Use of outside air energy
Risk of water supply outage, water freezing
Maintenance
Space
Workability
Implementation in stages
Symbol legend: ◎ = Best, ○ = Good, △ = Fair, � = Not good
Direct Outside Air System
Refrigerator
Outside air filter (Dust, salt damage)
Humidifier(for indoor humidifier control)
With the , the heat source equipment needed for generalair-conditioning systems is no longer required.Even when compared to outside air direct air-conditioning systems the F‒COOL NEO is a simple system that makes energy-saving operations possible.
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Integrated type Separate type
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Indoor unit Outdoor unit
(Utilize outside air)
Server room Server room
Comparison of Air-Conditioning Systems
Air-cooled packaged unit(PU) system
Centrifugal chiller +Air handling unit system
Indirect outside air air-conditioning system (F-COOL NEO)
Direct outside air-cooling unit®
Exhaust air Exhaust air
Outside air Outside air
Server Server
Indirect outside cooling unit Refrigerator
Indirect outside air-cooling unit
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Integrated Type Separate Type
Examples of installation for a building-type data center and the flow of air
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Server room
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is a registered trademark of Fuji Electric Co., Ltd.
●F–COOL NEO is in continuous operation at Fuji Electric’s data center demonstration laboratory located in our Kawasaki factory,in Japan and it is possible to visit this facility.
●As an optional function, it is possible to start or stop the F-COOL NEO, and set the supply air (SA) temperature and air flow rate by means of a higher-level building management system. ●In order to ensure the reliability required of data center facilities, we recommend operating with N+1 redundancy (for a TIER 2* data center) or N+1 or more redundancy (for a TIER 3 & 4* data center). N+1 redundancy means, after the total necessary cooling capacity is divided by the rated cooling capacity of the type of air conditioner unit (for example, 40 kW) to be used, where N is the total number of units required, N+1 adds an additional unit to the total number to be installed as a safety margin for redundancy. ●Please perform a daily inspection according to the instruction manual that comes with the delivered product. Also in addition to this normal day-to-day inspection, we recommend a contract for periodic maintenance and inspections.
Indirect Outside Air-cooling Unit
Redundant Operation and Maintenance
Demonstration Equipment
Modular–type data center
Server racks
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*: Standards for Data Center from ANSI/TIA-942-A-2012.
(Option)
Gate City Ohsaki, East Tower, 11-2, Osaki 1-chome, Shinagawa-ku, Tokyo 141-0032, JapanPhone : +81-3-5435-7111
Internet address : http://www.fujielectric.comInformation in this catalog is subject to change without notice. 2017-6(F2017b/I2014)4EP/FOLS Printed in Japan 09G1-E-0021b