JP2010190485A - Electronic apparatus cooling device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To carry out cooling of an electronic apparatus even if an electric power supply stopped state occurs. <P>SOLUTION: The electronic apparatus cooling device is equipped with an electric type air conditioner 110 carrying out air conditioning in a computer room, and a gas engine type air conditioner 1 carrying out air conditioning of an air-conditioning space 3 other than the computer room. The electric type air conditioner 110 is equipped with a first coolant circuit 131A supplying a coolant from a compressor driven by a motor to an indoor heat exchanger 131 of the electric type air conditioner 110, a second coolant circuit 131B supplying a coolant from a compressor driven by a gas engine to the indoor heat exchanger, and switching means 201, 202 for carrying out switching of the first and second coolant circuits. It is equipped with a detecting means 200 for detecting occurrence of an electric power supply stopped state from a commercial power supply to the electric type air conditioner, and in the electric power supply stopped state, switching is carried out from the first coolant circuit to the second coolant circuit by the switching means, and the coolant from the compressor driven by the gas engine is supplied to the indoor heat exchanger. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to an electronic device cooling apparatus.

In a computer room with a cabinet that houses multiple electronic devices such as servers, the computer room is air-conditioned by an air conditioner so that the temperature in the computer room rises and the electronic device does not run out of heat (patented) Reference 1).
JP 2008-51475 A

  However, the above-described technique has a problem that the electronic device cannot be cooled when, for example, a power supply stop state caused by a power failure or the like occurs.

  The present invention has been made in view of the above-described circumstances, and an object thereof is to provide an electronic device cooling apparatus capable of cooling an electronic device even when a power supply stop state occurs.

In order to achieve the above object, the present invention drives an electric air conditioner that air-conditions a computer room by driving a compressor with an electric motor using a commercial power source, and drives a compressor and a generator with a gas engine, Driving the auxiliary machine of the air conditioner with the generated power of the generator, and a gas engine type air conditioner that air-conditions a normal air-conditioned space other than the computer room, the electric air conditioner A first refrigerant circuit that supplies refrigerant from a compressor driven by an electric motor to an indoor heat exchanger of the electric air conditioner; and refrigerant from the compressor driven by the gas engine, A second refrigerant circuit that supplies the heat exchanger; and a switching unit that switches between the first and second refrigerant circuits, and detects the occurrence of a power supply stop state from the commercial power source to the electric air conditioner. Detection means In the power supply stop state, the switching means switches the first refrigerant circuit to the second refrigerant circuit, and the refrigerant from the compressor driven by the gas engine is supplied to the indoor heat exchanger. It is characterized by supplying to.
According to this configuration, even when the power supply stop state occurs, it is possible to cool the electronic device in the computer room.

In addition to the above invention, another invention is characterized in that the first refrigerant circuit and the second refrigerant circuit are arranged in a common indoor heat exchanger.
According to this structure, it can prevent that an installation space becomes large by providing two refrigerant circuits in an indoor heat exchanger.

  ADVANTAGE OF THE INVENTION According to this invention, even when an electric power supply stop state generate | occur | produces, the electronic device cooling device which can cool the electronic device in a computer room can be provided.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.
FIG. 1 is a diagram showing a server rack cooling device (electronic device cooling device) 100 according to an embodiment of the present invention. The server rack cooling apparatus 100 includes an air conditioner (hereinafter referred to as “air conditioner”) 110 as an electric air conditioner that drives a compressor with an electric motor, a compressor and a generator with a gas engine. And an air conditioner 1 as a gas engine type air conditioner for driving the vehicle. The air conditioner 110 air-conditions a server room (computer room) 2 as a conditioned room using a commercial power source as a power source. For example, the air conditioner 1 uses the city gas as a power source to air-condition the office 3 as a conditioned room. The air conditioner 110 includes an outdoor unit 120 installed outside and an indoor unit 130 installed in the server room 2, and these units are connected by a unit pipe 140 to form a refrigeration circuit that performs a refrigeration cycle. Yes. In addition, since the office 3 performs not only cooling operation but also heating operation depending on the season or outside air temperature, the gas engine type air conditioner 1 having high operating efficiency (COP) during heating operation is employed. In the server room 2 where the cooling operation is always performed, the electric air conditioner 110 having high operation efficiency during the cooling operation is employed.

  In the server room 2, server racks 10 each accommodating a plurality of servers (electronic devices) 11 are arranged. In each server rack 10, a plurality of servers 11 are stacked in a vertical direction. Each server 11 is provided with a cooling fan. When the temperature in the server 11 exceeds a predetermined temperature, the fan is driven, and outside air is introduced into the server 11 to perform forced air cooling. Since the server 11 is supplied with power from an unillustrated UPS (Uninterruptable Power Supply), the server 11 and the fan operate even when the power supply from the commercial power supply is stopped. Continue.

  The units 120 and 130 will be described. The outdoor unit 120 includes a compressor 121, a compressor motor 122, an outdoor heat exchanger 123, an expansion valve 124, an outdoor fan 125, an outdoor fan motor 126, a control unit 85, and the like. The indoor unit 130 accommodates an indoor heat exchanger 131, an indoor fan 132, and the like. The compressor 121 driven by the compressor motor 122 compresses and discharges the refrigerant filled in the refrigeration circuit, thereby circulating the refrigerant between the outdoor heat exchanger 123 and the indoor heat exchanger 131. Perform refrigeration cycle operation. By controlling the rotation speed of the compressor motor 122, the refrigerating capacity can be adjusted.

FIG. 1 shows a case where the indoor unit 130 is configured as a built-in type. That is, the indoor unit 130 is installed in the ceiling space, sucks air in the server room 2 from the suction port 141 provided in the ceiling by the negative pressure of the indoor fan 132, passes through the indoor heat exchanger 131, and performs heat exchange. The subsequent conditioned air is blown out into the server room 2 through the duct 144 and a plurality of (two in this example) outlets 142.
In the present embodiment, the case where the air conditioner 110 is configured as a built-in type has been described. It can be widely applied.

  The air conditioner 1 includes an outdoor unit 30 installed outside and an indoor unit 160 installed in an office 3 as a normal air-conditioned space other than the server room 2, and these are connected by a unit pipe 170. A refrigeration circuit for performing a refrigeration cycle is configured.

  The units 30 and 160 will be described. The outdoor unit 30 includes a compressor 32, an outdoor fan motor 34, an outdoor heat exchanger 35, an expansion valve 36, an outdoor fan 37, a four-way valve 38, a gas engine 40, a generator 41, The control unit 80 and the like are accommodated, and the indoor unit 160 accommodates the indoor heat exchanger 161, the indoor fan 162, and the like. Then, the compressor 32 driven by the gas engine 40 compresses and discharges the refrigerant filled in the refrigeration circuit, thereby circulating the refrigerant between the outdoor heat exchanger 35 and the indoor heat exchanger 161 and refrigeration. Perform cycle operation. The refrigerating capacity can be adjusted by controlling the rotation speed of the gas engine 40. Moreover, the gas engine 40 drives the generator 41, and the electric power generated by the generator 41 is supplied to the auxiliary equipment and the like of the air conditioner 1 as described later.

The four-way valve 38 is a switching valve for switching between the cooling operation and the heating operation, and FIG. 1 shows the state of the cooling operation. In this case, the refrigerant discharged from the compressor 32 flows to the outdoor heat exchanger 35 via the four-way valve 38 and then to the indoor heat exchanger 161, and the outdoor heat exchanger 35 is a condenser and indoor heat exchange. The unit 161 functions as an evaporator to enter a cooling operation state, and indoor air is heat-exchanged by the indoor heat exchanger 161 by the indoor fan 162 to cool the room.
When the four-way valve 38 is switched to the heating side, although not shown, the refrigerant discharged from the compressor 32 flows to the indoor heat exchanger 161 via the four-way valve 38 and then to the outdoor heat exchanger 35. The indoor heat exchanger 161 functions as a condenser and the outdoor heat exchanger 35 functions as an evaporator to enter a heating operation state, thereby heating the room.

FIG. 1 shows a case where the indoor unit 160 is configured as a built-in type. That is, the indoor unit 160 is installed in the ceiling space, sucks air in the office 3 from the suction port 151 provided in the ceiling by the negative pressure of the indoor fan 162, passes through the indoor heat exchanger 161, and after heat exchange The conditioned air is blown out into the office 3 through the duct 154 and a plurality of (two in this example) outlets 152.
In the present embodiment, the case where the air conditioner 1 is configured as a built-in type has been described. It can be widely applied.

  The indoor heat exchangers 131 and 161 are configured by, for example, a plate fin tube type heat exchanger including a copper tube and aluminum plate fins. The indoor heat exchanger 131 includes a copper pipe 131A (first refrigerant circuit) through which the refrigerant from the outdoor unit 120 flows, and a copper pipe 131B (second refrigerant circuit) through which the refrigerant from the outdoor unit 30 flows. Yes. An electromagnetic valve 202 controlled by the centralized controller 200 is provided between the four-way valve 38 and the copper pipe 131B. During normal operation, the solenoid valve 202 is closed and the cooling operation is executed by the refrigerant from the outdoor unit 120. On the other hand, when a power supply stop state (for example, a power failure) from the commercial power source occurs, the electromagnetic valve 202 is opened and the cooling operation is performed by the refrigerant from the outdoor unit 30.

  An electromagnetic valve 201 controlled by the centralized controller 200 is provided between the expansion valve 36 and the indoor heat exchanger 161. In the normal operation, the electromagnetic valve 201 is opened, and the refrigerant from the outdoor unit 30 is supplied to the indoor heat exchanger 161 to perform the cooling operation or the heating operation. On the other hand, when the power supply stop state occurs, the solenoid valve 201 is closed, the refrigerant flow into the indoor heat exchanger 161 is stopped, and the refrigerant flow into the indoor heat exchanger 131 is increased. By doing so, the cooling capacity of the server room 2 is increased.

  FIG. 2 is a block diagram illustrating a configuration example of a control system of the server rack cooling apparatus 100. In this figure, a solid thin line indicates a control signal line, a broken line indicates a power supply line, and a solid thick line (a line segment between the gas engine 40 and the generator 41) indicates a drive shaft. The centralized controller (detecting means) 200 is a control circuit for centrally controlling the control units 80 and 85 and the electromagnetic valves 201 and 202. As shown in FIG. 1, the control unit 80 is disposed in the outdoor unit 30, and is based on an output signal indicating the room temperature in the office 3 output from the indoor temperature sensor 29 and a control signal supplied from the centralized controller 200. Thus, the gas engine 40, the indoor fan motor 162A that drives the indoor fan 162, the outdoor fan motor 34, the expansion valve 36, and the four-way valve 38 are controlled. The generator 41 is driven by, for example, a gas engine 40 that operates by city gas or the like, and generates electric power from the centralized controller 200, the control units 80 and 85, the indoor fan motor 162A, the outdoor fan motor 34, the expansion valve 36, and the four-way The valve 38 and the indoor fan motor 132A for driving the indoor fan 132 are supplied. Instead of directly supplying the power generated by the generator 41 to each unit, for example, the frequency and voltage may be adjusted by an inverter or the like and then supplied to each unit.

  The control unit 85 is provided in the outdoor unit 120, and based on a signal indicating the room temperature in the server room 2 output from the indoor temperature sensor 129 and a control signal from the centralized controller 200, the indoor fan motor 132A, the compressor The motor 122, the expansion valve 124, and the outdoor fan motor 126 are controlled. The control unit 85, the indoor fan motor 132A, the compressor motor 122, the expansion valve 124, and the outdoor fan motor 126 are supplied with power from the commercial power supply 300.

  Next, the operation of this embodiment will be described. In the following, first, the operation when the power supply from the commercial power supply 300 is normal (normal operation) will be described, and then the power supply from the commercial power supply 300 is not normal with reference to FIG. In the case of (), the operation will be described.

  When the power supply from the commercial power supply 300 is normal, the centralized controller 200 opens the electromagnetic valve 201 and closes the electromagnetic valve 202. As a result, since the inflow of the refrigerant from the outdoor unit 30 to the indoor heat exchanger 131 is stopped by the electromagnetic valve 202, the indoor heat exchanger 131 operates only with the refrigerant from the outdoor unit 120, and the indoor heat exchanger 161 is It operates only with the refrigerant from the outdoor unit 30. More specifically, since the server room 2 needs to cool the heat discharged from the server 11, the cooling operation is always performed. The control unit 85 controls the compressor motor 122 based on the difference between the signal indicating the room temperature of the server room 2 output from the indoor temperature sensor 129 and the target temperature, so that the server room 2 reaches the target temperature. To control. Note that the appropriate temperature range of the ambient temperature of the server 11 is generally 17 to 26 ° C. If the temperature rises further, the lifetime of the semiconductor and electronic parts constituting the server 11 is shortened and the failure rate is increased. For example, in the case of a semiconductor, if the failure rate at 40 ° C. is 1, it is 10 times at 60 ° C. and 100 times at 80 ° C. In the case of an electrolytic capacitor, if the temperature rises by 10 ° C., the life is halved. Therefore, normally, for example, 20 ° C. belonging to the range of 17 to 26 ° C. described above is set as the target temperature for air conditioning. This not only prevents thermal runaway of the server 11 due to temperature rise, but also reduces the failure rate of the electronic components that make up the server 11 and extends the life.

On the other hand, with respect to the air conditioner 1, a cooling operation or a heating operation is executed according to the season or the outside temperature, and the inside of the office 3 is cooled or heated. For example, in the case of cooling operation, the four-way valve 38 is in the state shown in FIG. 1, and the refrigerant discharged from the compressor 32 flows into the outdoor heat exchanger 35 via the four-way valve 38 and then exchanges indoor heat. The outdoor heat exchanger 35 functions as a condenser, and the indoor heat exchanger 161 functions as an evaporator to enter a cooling operation state.
In the case of heating operation, the four-way valve 38 is switched to the heating side, and the refrigerant discharged from the compressor 32 flows to the indoor heat exchanger 161 via the four-way valve 38 and then to the outdoor heat exchanger 35. The indoor heat exchanger 161 functions as a condenser and the outdoor heat exchanger 35 functions as an evaporator to enter a heating operation state. Since the solenoid valve 202 is closed during normal operation, it is possible to prevent thermal refrigerant (refrigerant discharged from the compressor 32) during heating operation from flowing into the copper pipe 131B of the indoor heat exchanger 131. Therefore, it is possible to prevent the temperature refrigerant from flowing due to the heat refrigerant flowing into the indoor heat exchanger 131 that is in the cooling operation state. In each of the cooling operation and the heating operation, the control unit 80 outputs a signal indicating the room temperature in the office 3 output from the indoor temperature sensor 29 and a target temperature (for example, an operation unit (not shown) is operated by the user). The temperature in the office 3 is maintained at the target temperature by determining the difference between the temperature of the gas engine 40 and the rotational speed of the gas engine 40 based on the difference.

  Next, with reference to FIG. 3, an operation in the case where a power supply stop state from the commercial power supply 300 occurs will be described. When the power supply stop state occurs, the air conditioner 110 stops operating and only the air conditioner 1 is operated. Therefore, in such a case, the air conditioning in the office 3 is stopped, the refrigerant from the outdoor unit 30 is supplied to the indoor heat exchanger 131, and the cooling of the server room 2 is continued. It is possible to prevent a temperature abnormality (for example, thermal runaway) from occurring in the arranged server 11.

  For example, a power failure occurs in the commercial power source 300 due to a lightning strike or the like, or a safety device (shut-off device) disposed between the commercial power source 300 and the air conditioner 110 operates, so that the commercial power source 300 When the supply of power to the air conditioner 110 is stopped, the centralized controller 200 detects this, determines that a power supply stop state has occurred in step S10 (step S10; Yes), and proceeds to step S11. move on. When the power supply is stopped, power is not supplied to the compressor motor 122, the expansion valve 124, and the outdoor fan motor 126, and these stop operating.

  In step S11, the centralized controller 200 acquires information indicating the operation status from the control unit 80, determines whether or not the air conditioner 1 is in the heating operation, and if it is in the heating operation (step S11; Yes). The process proceeds to step S12, and otherwise (step S11; No), the process proceeds to step S13. For example, if the heating operation is being performed, the determination is Yes and the process proceeds to step S12.

  In step S12, the centralized controller 200 instructs the control unit 80 to switch the four-way valve 38. As a result, when the four-way valve 38 is in the heating operation state, it is switched to the cooling operation state shown in FIG.

  In step S <b> 13, the centralized controller 200 keeps the electromagnetic valve 202 open. Thereby, the inflow of the refrigerant from the outdoor unit 30 to the copper pipe 131B of the indoor heat exchanger 131 is started. In step S14, the centralized controller 200 closes the electromagnetic valve 201. Thereby, the inflow of the refrigerant from the outdoor unit 30 to the indoor heat exchanger 161 is stopped. Through these series of operations, the refrigerant from the outdoor unit 30 is supplied to the copper tube 131B of the indoor heat exchanger 131, and the cooling operation is performed. The solenoid valve 201 is closed after the solenoid valve 202 is opened. However, if the solenoid valve 201 is closed first, the refrigerant inflow destination from the outdoor unit 30 disappears. This is to secure the inflow destination of the refrigerant by opening it first.

  In step S <b> 15, the centralized controller 200 refers to the output of the room temperature sensor 129 via the control unit 85 and detects the temperature in the server room 2. As shown in FIG. 2, since the power from the generator 41 is supplied to the control unit 85, the control unit 85 can acquire an output signal from the indoor temperature sensor 129 and supply it to the centralized controller 200. At this time, the output signal from the indoor temperature sensor 29 is ignored.

  In step S16, it is determined whether or not the temperature detected in step S15 is equal to the target temperature (for example, 20 ° C.) of the server room 2. If it is determined that the temperature is equal (step S16; Yes), the process proceeds to step S18. In other cases (step S16; No), the process proceeds to step S17. For example, if it is determined that the temperature is higher than the target temperature, or if it is determined that the temperature is lower, the process proceeds to step S17.

  In step S17, the centralized controller 200 calculates the refrigeration load based on the difference between the temperature in the server room 2 detected in step S15 and the target temperature, and adjusts the output of the gas engine 40 according to the refrigeration load. To do. Thereby, since the output of the gas engine 40 is adjusted so that the room temperature of the server room 2 approaches the target temperature, the server 11 can be prevented from causing a temperature abnormality (for example, thermal runaway).

  In step S18, the centralized controller 200 determines whether or not the power supply stop state has been resolved. If it is determined that the power supply stop state has been resolved (step S18; Yes), the process proceeds to step S19, and otherwise (step S18; No) returns to step S15 and repeats the same processing. For example, when the power failure is resolved and the power supply stop state is resolved, the process proceeds to step S19.

  In step S19, the centralized controller 200 restores the air conditioner 1 to the original operating state (the operating state before the power supply stop state occurs). More specifically, when the air conditioner 1 is in the heating operation before the power supply stop state occurs, the centralized controller 200 controls the control unit 80 to switch the four-way valve 38 and thereby perform the heating operation. Restore to the state.

  In step S20, the centralized controller 200 keeps the electromagnetic valve 201 open. Thereby, inflow of the refrigerant from the outdoor unit 30 to the indoor heat exchanger 161 becomes possible. In step S21, the centralized controller 200 closes the solenoid valve 202. Thereby, the inflow of the refrigerant from the outdoor unit 30 to the copper pipe 131B of the indoor heat exchanger 131 is stopped. Through these series of operations, the indoor heat exchanger 131 is supplied with the refrigerant from the outdoor unit 120 and enters the cooling operation state. Moreover, the refrigerant | coolant from the outdoor unit 30 is supplied to the indoor heat exchanger 161, and it will be in the state of cooling operation or heating operation. The solenoid valve 202 is closed after the solenoid valve 201 is opened. This is for the same reason as described above.

  In step S22, the centralized controller 200 instructs the control units 80 and 85 to resume normal operation. As a result, based on the output signal from the indoor temperature sensor 129, the air conditioner 110 sets the air temperature in the server room 2 to a target temperature (for example, 20 ° C.) as a temperature at which the server 11 does not cause a temperature abnormality. Implement air-conditioning operation. Further, the air conditioner 1 performs the air conditioning operation based on the output signal from the indoor temperature sensor 29 so that the air temperature in the office 3 becomes the target temperature set by the user.

  As described above, according to the embodiment of the present invention, when the power supply stop state occurs and the air conditioner 110 for cooling the server room 2 is stopped, the air conditioning for the office 3 is performed. Since the refrigerant from the outdoor unit 30 of the air conditioner 1 is supplied to the copper pipe 131B included in the indoor heat exchanger 131 of the air conditioner 110, the server room 2 can be used even when the power supply is stopped. It is possible to prevent the server 11 arranged in the server from generating a temperature abnormality such as a thermal runaway.

  Further, since the electric power from the generator 41 is provided to the control unit 85 and the indoor fan motor 132A, the detection signal from the indoor temperature sensor 129 is transmitted via the control unit 85 even in the power supply stop state. While being able to supply to the centralized controller 200, the indoor fan motor 132A can be operated.

  Further, since the electromagnetic valve 202 is inserted between the four-way valve 38 and the copper pipe 131B, the high-temperature refrigerant discharged from the compressor 32 through the four-way valve 38 is copper when the air conditioner 1 is in the heating operation. It is possible to prevent the temperature of the indoor heat exchanger 131 from rising into the pipe 131B.

  It should be noted that the above-described embodiment is merely an aspect of the present invention, and can be arbitrarily modified and applied within the scope of the present invention. For example, in the above embodiment, the solenoid valves 201 and 202 are provided to control the inflow and outflow of the refrigerant. However, the indoor unit 130 and the indoor unit 150 have no solenoid valves 201 and 202. A refrigerant flow control may be performed using an expansion valve (not shown). According to such a configuration, the configuration of the apparatus can be simplified.

  Moreover, in the above embodiment, although it does not mention about the operation capability of the air conditioner 1 and the air conditioner 110, you may make it control based on these operation capability differences, for example. Specifically, when these driving capabilities are substantially the same, the above-described processing allows the air conditioning in the server room 2 to be continued even when the power supply is stopped. In addition, when the operating capacity of the air conditioner 1 is larger than that of the air conditioner 110, an extra driving capacity is generated in addition to the ability to air-condition the server room 2, and therefore the extra capacity is used in the office 3 You may make it air-condition. In addition, when the operating capacity of the air conditioner 1 is smaller than that of the air conditioner 110, it may be assumed that the capacity of air conditioning the server room 2 is insufficient. In such a case, since the temperature cannot be lowered to the target temperature at the normal time, an “allowable temperature” higher than the target temperature may be set, and control may be performed so as not to exceed the allowable temperature. . In other words, in the power supply stop state, it is the temperature at which the server 11 is thermally runaway because it is the most important issue to prevent the server 11 from causing a temperature abnormality (for example, the server 11 is thermally runaway). For example, the gas engine 40 can be controlled so that 35 ° C. is set as the allowable temperature and the temperature is not exceeded. If the driving capacity is still insufficient, for example, when the power from the generator 41 is supplied to other than the block shown in FIG. 2 (for example, supplied to indoor lighting). By stopping the supply of power to the supply destination, it is possible to reduce the load on the gas engine 40 and increase the driving capacity. Alternatively, it is possible to reduce the heat generation amount by forcibly terminating a part of the server 11 so that the heat generation amount matches the driving ability.

  In the above embodiment, the electric power generated by the generator 41 is supplied to the indoor fan motor 162A and the control unit 85. For example, the electric power from the commercial power source 300 is used during normal operation. For example, power supply switching means may be provided so as to supply power from the generator 41 in the power supply stop state.

  In the above embodiment, the conditioned air heat-exchanged in the indoor unit 130 is blown out from the air outlet 142 on the ceiling surface and collected from the air inlet 141 on the ceiling surface. You may make it collect | recover from a surface, or you may make it collect | recover on a floor surface by blowing out from a ceiling surface.

It is a figure showing an air-conditioning system concerning one embodiment of the present invention. It is a block diagram which shows the control system of the air conditioning system shown in FIG. It is an example of the process performed at the time of an electric power supply stop.

1 Air conditioner (gas engine type air conditioner)
2 Server room (computer room)
3 Office 10 Server rack 11 Server (electronic equipment)
30 Outdoor Unit 32 Compressor 34 Fan Motor 35 Outdoor Heat Exchanger 40 Gas Engine 41 Generator 80 Control Unit 85 Control Unit 100 Server Rack Cooling Device (Electronic Equipment Cooling Device)
110 Air conditioner (electric air conditioner)
120 outdoor unit 121 compressor 122 compressor motor 126 fan motor 130 indoor unit 131 indoor heat exchanger 131A copper pipe (first refrigerant circuit)
131B Copper tube (second refrigerant circuit)
160 indoor unit 161 indoor heat exchanger 200 centralized controller (detection means)
201, 202 Solenoid valve (switching means)

Claims (2)

An electric air conditioner that drives a compressor with an electric motor using a commercial power source to air-condition the computer room, a compressor and a generator are driven with a gas engine, and the generated power of the generator A gas engine type air conditioner that drives an auxiliary machine and air-conditions a normal air-conditioned space other than the computer room,
The electric air conditioner includes a first refrigerant circuit that supplies a refrigerant from a compressor driven by the electric motor to an indoor heat exchanger of the electric air conditioner, and the gas engine that is driven by the gas engine. A second refrigerant circuit for supplying refrigerant from the compressor to the indoor heat exchanger, and switching means for switching between the first and second refrigerant circuits,
Detecting means for detecting occurrence of a power supply stop state from the commercial power source to the electric air conditioner;
When the power supply is stopped, the switching means switches from the first refrigerant circuit to the second refrigerant circuit, and supplies the refrigerant from the compressor driven by the gas engine to the indoor heat exchanger. An electronic device cooling device characterized by that. In the electronic device cooling device according to claim 1,
The electronic apparatus cooling device, wherein the first refrigerant circuit and the second refrigerant circuit are arranged in a common indoor heat exchanger.

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