JP2004309007A - Air conditioning system and air conditioning setting device - Google Patents

Abstract

An air conditioning system and an air conditioning selection device capable of reducing energy consumption are provided.
An air conditioning system is an air conditioning system for maintaining the temperature of an electronic device in an appropriate temperature range suitable for the operation of the electronic device, and includes a storage unit, an air conditioning device, and a setting device. And a supply device 30. The storage unit 20 stores the electronic device 1. The air conditioner 10 can provide conditioned air in the storage unit 20. The setting device 40 sets any of the adjacent space adjacent to the storage unit 20 and the air conditioner 10 as a supply source. The supply device 30 supplies air into the storage unit 20 from a supply source.
[Selection diagram] Fig. 1

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to an air conditioning system and an air conditioning setting device.
[0002]
[Prior art]
2. Description of the Related Art Conventionally, there has been known an air conditioning system that supplies air having a temperature suitable for operation of an electronic device to the vicinity of the electronic device to maintain the temperature of the electronic device at a temperature suitable for operation of the electronic device. For example, a server computer used in a computer network generates heat during operation. However, if the temperature of the server computer exceeds a predetermined temperature, the server computer may not be able to operate properly. For this reason, in an air conditioning system of a server computer, the temperature of the server computer is maintained at a temperature suitable for operation by providing cool air near the server computer (for example, Patent Document 1).
[0003]
Such an air conditioning system includes a server rack in which a server computer is stored, and an air conditioner that generates cool air. The server rack is connected to the air conditioner and receives supply of cool air from the air conditioner. The air conditioner generates cold air using electricity or gas as a power source. In the air conditioning system configured as described above, the cool air is supplied from the air conditioner into the server rack, whereby the temperature inside the server rack is reduced, and the temperature of the server computer is maintained at a temperature suitable for operation. I have.
[0004]
[Patent Document 1]
JP-A-2002-156136
[0005]
[Problems to be solved by the invention]
By the way, in such an air conditioning system, air used for cooling the server computer is supplied from an air conditioning apparatus. Further, a server computer used for a computer network such as the Internet is constantly operating, and thus, the server computer constantly generates heat. Therefore, in order to keep the temperature of the server computer at a temperature suitable for operation, it is necessary to always operate the air conditioner. For this reason, in the conventional air conditioning system, a large amount of energy is consumed because the air conditioner operates constantly.
[0006]
Therefore, an object of the present invention is to provide an air conditioning system and an air conditioning setting device capable of reducing energy consumption.
[0007]
[Means for Solving the Problems]
The air conditioning system according to claim 1 is an air conditioning system for keeping the temperature of an electronic device in an appropriate temperature range suitable for operation of the electronic device, comprising: a storage unit, an air conditioning device, a setting device, and a supply unit. Device. The storage unit stores an electronic device. The air conditioner can provide conditioned air in the storage unit. The setting device sets one of an adjacent space adjacent to the storage unit and the air conditioner as a supply source. The supply device supplies air into the storage unit from a supply source.
[0008]
In this air conditioning system, the setting device sets one of the adjacent space and the air conditioning device as a supply source. When the adjacent space is set as the supply source, the supply device sucks air from the adjacent space into the storage unit. When the air conditioner is set as the supply source, the supply device supplies conditioned air from the air conditioner into the storage unit. In any case, the air supplied from the supply source into the storage unit keeps the temperature of the electronic device in an appropriate temperature range.
[0009]
Here, the setting device sets the supply source of the air for maintaining the temperature of the electronic device in the appropriate temperature zone to either the adjacent space or the air conditioner. Therefore, when the supply source is set in the adjacent space, there is no need for the air conditioner to supply air to the storage section. That is, in this case, the temperature of the electronic device can be maintained in an appropriate temperature range without the air conditioner supplying air to the storage section. Therefore, the energy consumption of the air conditioner can be reduced. For this reason, in this air conditioning system, the energy consumption of the system can be reduced.
[0010]
An air conditioning system according to a second aspect is the air conditioning system according to the first aspect, wherein the setting device sets the adjacent space as a supply source within a predetermined time. The setting device sets the air conditioner as a supply source outside the predetermined time.
Here, the adjacent space is set as the supply source within a predetermined time. Outside the predetermined time, the air conditioner is set as the supply source. Therefore, the setting device can set the supply source to either the adjacent space or the air conditioner according to the time zone. Therefore, in this air conditioning system, the usefulness of the system is improved.
[0011]
The air conditioning system according to claim 3 is the air conditioning system according to claim 1 or 2, wherein the setting device sets the adjacent space as a supply source when the temperature of the adjacent space is within an appropriate temperature range. I do. In addition, when the air temperature in the adjacent space is outside the appropriate temperature range, the setting device sets the air conditioner as a supply source.
Here, when the air temperature in the adjacent space is within the appropriate temperature range, the adjacent space is set as the supply source. When the air temperature in the adjacent space is outside the appropriate temperature range, the air conditioner is set as the supply source. Therefore, the setting device can set the supply source to either the adjacent space or the air conditioner according to the temperature of the adjacent space. Therefore, in this air conditioning system, the usefulness of the system is improved.
[0012]
An air conditioning system according to a fourth aspect is the air conditioning system according to the first aspect, wherein the air conditioning apparatus harmoniously airs in a room where the storage unit is installed.
Here, the air in the room where the storage unit is installed is conditioned by the air conditioner. Therefore, it is not necessary to separately provide a new air conditioner in order to balance the air in the room where the storage unit is installed. For this reason, the configuration of the equipment for air conditioning in the room can be simplified.
[0013]
The air conditioning system according to a fifth aspect is the air conditioning system according to the fourth aspect, wherein the air conditioner stops indoor air conditioning when the consumed energy exceeds a certain amount. In addition, the air conditioner performs indoor air conditioning when the consumed energy is equal to or less than a certain amount. The setting device sets the air conditioner as a supply source when the energy consumption of the air conditioner exceeds a certain amount.
[0014]
Here, when the energy consumption of the air conditioner exceeds a certain amount, the air conditioner stops indoor air conditioning, and the setting device sets the air conditioner as a supply source. When the energy consumption of the air conditioner is equal to or less than a certain amount, the air conditioner performs indoor air conditioning. Therefore, when the energy consumption of the air conditioner exceeds a certain amount, the air conditioner stops air conditioning in the room and performs only air conditioning in the storage unit. That is, in this air conditioning system, the energy consumption can be kept constant while the temperature of the electronic device is kept in an appropriate temperature range. For this reason, in this air conditioning system, energy consumption can be suppressed.
[0015]
The air conditioning system according to a sixth aspect is the air conditioning system according to the fourth or fifth aspect, wherein the air conditioning apparatus performs air conditioning in a room when there is a occupant in the room. The air conditioner stops air conditioning in the room when there is no occupant in the room. The setting device sets the adjacent space as a supply source when there is an occupant in the room.
[0016]
Here, when there is an occupant in the room, the air conditioner performs air conditioning in the room. When there is no occupant in the room, the air conditioner stops air conditioning in the room, and the setting device sets the air conditioner as a supply source. Therefore, when there is no occupant in the room, the air conditioner stops air conditioning in the room and performs only air conditioning in the storage unit. For this reason, in this air conditioning system, it is possible to reduce energy consumption while maintaining the temperature of the electronic device in an appropriate temperature range.
[0017]
An air conditioning system according to a seventh aspect is the air conditioning system according to any one of the first to sixth aspects, wherein the air conditioning apparatus includes a power storage device that stores electricity.
Here, the air conditioner includes a power storage device that stores electricity for operation. Therefore, this air conditioner can accumulate electricity in the power storage device at night or the like when power consumption is difficult to concentrate, and can operate using the accumulated electricity. For this reason, in this air conditioner, power consumption can be dispersed.
[0018]
An air conditioning system according to an eighth aspect is the air conditioning system according to the seventh aspect, wherein the electronic device is supplied with electricity from a power storage device.
Here, the electricity stored in the power storage device is supplied to the electronic device. Therefore, even when a power failure such as a power failure or a voltage drop occurs, the electronic device can operate based on the electricity stored in the power storage device. Therefore, the electronic device can operate relatively stably.
[0019]
An air conditioning system according to a ninth aspect is the air conditioning system according to the eighth aspect, wherein the setting device sets a supply source to the air conditioning device when a power failure occurs.
Here, when a power failure such as a power failure occurs, the setting device sets the air conditioner as a supply source. Therefore, the temperature of the electronic device is stably maintained in the appropriate temperature range. Therefore, in this air conditioner, the electronic device can operate more stably.
[0020]
An air-conditioning setting device according to a tenth aspect is an air-conditioning setting device for maintaining the temperature of an electronic device in an appropriate temperature range suitable for operation of the electronic device, and includes a determination unit and a setting unit. The electric device is stored in the storage device. The storage device is adjacent to the adjacent space. Air is supplied into the storage device from one of the adjacent space and the air conditioner. The determining unit determines which of the adjacent space and the air conditioner is set as the supply source. The setting unit sets the supply source based on the determination result of the determination unit.
[0021]
In this air conditioning setting device, the determining unit determines which of the adjacent space and the air conditioner is set as the supply source. Then, the setting unit sets the supply source based on the determination result of the determination unit. Air is supplied into the storage device from the supply source set by the setting unit.
Here, the setting unit sets the supply source of air for maintaining the temperature of the electronic device in an appropriate temperature zone to one of the adjacent space and the air conditioner. Therefore, when the supply source is set in the adjacent space, there is no need for the air conditioner to supply air to the storage section. That is, in this case, the temperature of the electronic device can be maintained in an appropriate temperature range without the air conditioner supplying air to the storage section. Therefore, the energy consumption of the air conditioner can be reduced. For this reason, in this air conditioning setting device, it is possible to reduce energy consumption for maintaining the temperature of the electronic device in an appropriate temperature range suitable for the operation of the electronic device.
[0022]
An air conditioning setting device according to an eleventh aspect is the air conditioning setting device according to the tenth aspect, wherein the determining unit sets an adjacent space as a supply source within a predetermined time. In addition, the determination unit sets the air conditioner as a supply source outside the predetermined time.
That is, here, the adjacent space is set as the supply source within the predetermined time. Outside the predetermined time, the air conditioner is set as the supply source. Therefore, in this air-conditioning setting device, the supply source can be set to either the adjacent space or the air conditioner according to the time zone, so that the usability is improved.
[0023]
The air-conditioning setting device according to claim 12 is the air-conditioning setting device according to claim 10 or 11, wherein the determining unit sets the adjacent space as a supply source when the temperature of the adjacent space is within an appropriate temperature range. I do. When the air temperature in the adjacent space is outside the appropriate temperature range, the determination unit sets the air conditioner as a supply source.
Here, when the air temperature in the adjacent space is within the appropriate temperature range, the adjacent space is set as the supply source. When the air temperature in the adjacent space is outside the appropriate temperature range, the air conditioner is set as the supply source. Therefore, in this air-conditioning setting device, the supply source can be set to either the adjacent space or the air conditioner according to the temperature of the adjacent space, so that the usefulness is improved.
[0024]
BEST MODE FOR CARRYING OUT THE INVENTION
<Configuration of server rack air conditioning system>
FIG. 1 shows a schematic configuration of a server rack air conditioning system to which an embodiment of the present invention is applied. This server rack air-conditioning system is an air-conditioning system for maintaining the temperature of the server computer 1 in an appropriate temperature range suitable for the operation of the server computer 1 (for example, 5 degrees Celsius to 35 degrees Celsius). The server rack air conditioning system mainly includes an air conditioner 10, a demand control device 50, and a server rack 20.
[0025]
In addition, here, one air conditioner 10 arranged in the room 2 is premised on the system, but a plurality of air conditioners may be arranged in the room.
(Air conditioner)
The air-conditioning apparatus 10 can provide conditioned air (for example, cool air or warm air) that has been conditioned such as cooling and heating or dehumidification into the server rack 20 and can harmony the air in the room 2. It is an air conditioner.
[0026]
The air conditioner 10 is an electric air conditioner. In addition, the air conditioner 10 has a power storage device 14 that mainly stores electricity supplied from a commercial power supply at night. This power storage device 14 is connected to a commercial power supply via a power supply line. The air conditioner 10 operates using electricity stored in the power storage device 14. The power storage device 14 is connected to the server computer 1 via a power supply line 15 and supplies power to the server computer 1.
[0027]
Further, the air conditioner 10 can change the operation status according to a command from the demand control device 50 or the server rack 20.
Further, the air conditioner 10 is connected to the air duct 16. The air duct 16 is a duct for providing the air conditioned in the air conditioner 10 to the server rack 20. The air duct 16 is configured to connect the air conditioner 10 and the server rack 20.
[0028]
Further, in the event of a commercial power failure such as a power failure or a drop in power supply voltage, the air conditioner 10 stops supplying conditioned air to the space in the room 2 and supplies conditioned air into the air duct 16.
(Demand control device)
The demand control device 50 is provided between the commercial power supply and the air conditioner 10 to suppress the power supplied from the commercial power supply to the power storage device 14 of the air conditioner 10 to a predetermined power value or less. The demand control device 50 monitors the power supplied from the commercial power supply to the power storage device 14 of the air conditioner 10. Then, based on the monitoring result, the demand control device 50 calculates a predicted demand power amount at which the power supplied from the commercial power supply to the power storage device 14 of the air conditioner 10 reaches after the demand time period ends. When the predicted demand power amount exceeds the predetermined power amount at the end of the demand time period, the demand control device 50 transmits the predicted demand power amount to the unit control unit 41 via the air-conditioning apparatus 10. Is transmitted (hereinafter, referred to as demand information) that a prediction exceeding the power amount is performed. Further, in this case, the demand control device 50 transmits a control command to the air conditioner 10. This control command stops the supply of conditioned air from the air conditioner 10 to the space in the room 2 and causes the air conditioner 10 to supply conditioned air into the air duct 16.
[0029]
(Server rack)
The server rack 20 is a metal or resin shelf that houses the server computer 1 therein, and is installed in the room 2. The server rack 20 covers the server computer 1 from above and below and from the side, and forms a closed space around the server computer 1. The server rack 20 has a fan unit 30 and an air conditioning unit 40. The fan unit 30 and the air conditioning unit 40 are connected to the power storage device 14 of the air conditioner 10 via the power supply line 15 and receive power supply from the power storage device 14.
[0030]
The fan unit 30 is provided above the server rack 20 to take air into the server rack 20. The fan unit 30 has a fan (not shown) and a fan motor that rotates the fan. When the fan rotates, air is sucked into the server rack 20 from the air supply destination set by the air conditioning unit 40. Further, the rotation of the fan releases the air in the server rack 20 to the outside of the server rack 20.
[0031]
The air conditioning unit 40 is a unit provided below the server rack 20 for setting a supply source of air taken into the server rack 20 by the fan unit 30. The air conditioning unit 40 has a unit control unit 41 and an electric damper 45.
FIG. 2 shows a configuration diagram of the unit control unit 41 of the air conditioning unit 40.
[0032]
Unit control unit 41 is connected to air conditioner 10 via a power supply line and a signal line. Further, the unit control section 41 is connected to the timer 42, the temperature sensor 43, the motion sensor 44, and the electric damper 45 via signal lines.
The timer 42 is provided inside the air conditioning unit 40, and transmits the current time to the unit control unit 41. The temperature sensor 43 is provided on the outer surface of the server rack 20 and measures the room temperature of the room 2. Further, the temperature sensor 43 transmits the measurement result of the room temperature of the room 2 to the unit control unit 41. The human sensor 44 detects the presence or absence of a room occupant in the room 2 by sensing infrared rays emitted from the room occupants in the room 2. Further, the human sensor 44 transmits an occupant signal indicating the presence or absence of the occupant to the unit control unit 41. The unit control section 41 transmits an open / close signal to the electric damper 45 according to the transmission content transmitted from these connected devices. Further, unit control section 41 can transmit a control command to air-conditioning apparatus 10 according to the transmission content transmitted from these connected devices. This control command is the same command as the control command transmitted from the demand control device 50 to the air conditioner 10.
[0033]
The electric damper 45 opens and closes according to an opening and closing signal transmitted from the unit control unit 41. When the electric damper 45 is in the “open” state, the space in the server rack 20 is connected to the space in the room 2 adjacent to the server rack 20. When the electric damper 45 is in the “closed” state, the space in the server rack 20 is connected to the space in the air duct 16.
[0034]
In the unit control unit 41, for example, one of the “demand mode”, the “timer mode”, the “temperature mode”, and the “occupant mode” is selected by an administrator of the server computer 1, for example. In the “demand mode”, the unit control unit 41 determines the open / closed state of the electric damper 45 according to only the content transmitted from the demand control device 50. In the “timer mode”, the unit control unit 41 determines the open / closed state of the electric damper 45 according to only the content transmitted from the timer 42. In the “temperature mode”, the unit control unit 41 determines the open / closed state of the electric damper 45 based only on the content of the transmission from the temperature sensor 43. In the “occupant mode”, the unit control unit 41 determines the open / closed state of the electric damper 45 only in accordance with the content transmitted from the human sensor. The case where each of the above control modes is selected in the unit control section 41 will be described later in detail.
[0035]
In the event of a commercial power failure such as a power failure or a drop in the power supply voltage, the electric damper 45 is in a “closed” state. That is, the space in the server rack 20 is connected to the space in the air duct 16 by the electric damper 45.
<Air supply status in each control mode>
Hereinafter, a flow of a signal when each of the above control modes is selected in the unit control unit 41 and an operation of each device will be described.
[0036]
(Demand mode)
First, FIG. 3 shows a flow of a signal when the “demand mode” is selected in the unit control unit 41 and an operation of each device.
First, the power supplied from the commercial power supply to the power storage device 14 of the air conditioner 10 is monitored by the demand control device 50 (step S101). Based on the monitoring result, the demand control device 50 calculates a predicted demand power amount at which power supplied from the commercial power supply to the power storage device 14 of the air conditioner 10 after the demand time period ends (step S102). ). Then, the demand control device 50 determines whether or not the predicted power demand exceeds a predetermined power (for example, a contract power with a power company) (step S103).
[0037]
When the predicted demand power amount exceeds the predetermined power amount, the demand information is transmitted from the demand control device 50 to the unit control unit 41 via the air conditioner 10 (step S104). The unit control unit 41 that has received the demand information transmits an open / close signal to the electric damper 45 so that the electric damper 45 is closed (step S105). The open / close signal transmitted from the unit control unit 41 causes the electric damper 45 to be in a “closed” state. That is, the space in the server rack 20 is connected to the space in the air duct 16 by the electric damper 45. Further, the demand control device 50 transmits a control command to the air conditioner 10 (step S106). According to the control command transmitted to the air conditioner 10, the air conditioner 10 stops supplying the conditioned air to the space in the room 2 and supplies the conditioned air into the air duct 16. The conditioned air supplied into the air duct 16 is drawn into the server rack 20 by the fan unit 30. Further, the air in the server rack 20 is discharged out of the server rack 20 by the fan unit 30. The temperature of the server computer 1 is kept in an appropriate temperature range by the conditioned air sucked into the server rack 20 from the air duct 16.
[0038]
If the predicted demand power amount does not exceed the predetermined power amount, the unit control unit 41 transmits an opening / closing signal to the electric damper 45 so that the electric damper 45 is opened (step S107). The open / close signal transmitted from the unit control unit 41 causes the electric damper 45 to be in an “open” state. That is, the space in the server rack 20 is connected to the space in the room 2 by the electric damper 45. In this case, conditioned air is provided from the air conditioner 10 into the room 2. Then, the air in the room 2 is sucked into the server rack 20 by the fan unit 30. Further, the air in the server rack 20 is discharged out of the server rack 20 by the fan unit 30. The conditioned air sucked into the server rack 20 from the space in the room 2 keeps the temperature of the server computer 1 in an appropriate temperature range.
[0039]
(Timer mode)
Next, FIG. 4 shows a flow of a signal when the “timer mode” is selected in the unit control unit 41 and an operation of each device.
First, the current time is transmitted from the timer 42 to the unit control unit 41 (step S201). Based on the current time transmitted from the timer 42, the unit control unit determines whether the current time is within a predetermined time (for example, a time period from 8:00 am to 8:00 pm) specified in advance. It is determined at 41 (step S202).
[0040]
If the current time is within the predetermined time, the unit control unit 41 transmits an open / close signal to the electric damper 45 so that the electric damper 45 is opened (step S203). The open / close signal transmitted from the unit control unit 41 causes the electric damper 45 to be in an “open” state. That is, the space in the server rack 20 is connected to the space in the room 2 by the electric damper 45. In this case, conditioned air is provided from the air conditioner 10 into the room 2. Then, the air in the room 2 is sucked into the server rack 20 by the fan unit 30. Further, the air in the server rack 20 is discharged out of the server rack 20 by the fan unit 30. The conditioned air sucked into the server rack 20 from the space in the room 2 keeps the temperature of the server computer 1 in an appropriate temperature range.
[0041]
If the current time is outside the predetermined time, the unit control section 41 transmits an open / close signal to the electric damper 45 so that the electric damper 45 is closed (step S204). The open / close signal transmitted from the unit control unit 41 causes the electric damper 45 to be in a “closed” state. That is, the space in the server rack 20 is connected to the space in the air duct 16 by the electric damper 45. Further, a control command is transmitted to the air-conditioning apparatus 10 by the unit control section 41 (step S205). According to the control command transmitted to the air conditioner 10, the air conditioner 10 stops supplying the conditioned air to the space in the room 2 and supplies the conditioned air into the air duct 16. The conditioned air supplied into the air duct 16 is drawn into the server rack 20 by the fan unit 30. Further, the air in the server rack 20 is discharged out of the server rack 20 by the fan unit 30. The conditioned air sucked into the server rack 20 from the air duct 16 keeps the temperature of the server computer 1 in an appropriate temperature range.
[0042]
(Temperature mode)
Next, FIG. 5 shows a flow of a signal when the “temperature mode” is selected in the unit control unit 41 and an operation of each device.
First, the room temperature in the room 2 is measured by the temperature sensor 43 and transmitted to the unit controller 41 (Step S301). Based on the room temperature in the room 2 transmitted from the temperature sensor 43, the unit controller 41 determines whether the room temperature in the room 2 is within the appropriate temperature range of the server computer 1 (step S302).
[0043]
If the room temperature in the room 2 is within the appropriate temperature range of the server computer 1, the unit control section 41 transmits an opening / closing signal to the electric damper 45 so that the electric damper 45 is opened (step S303). . The open / close signal transmitted from the unit control unit 41 causes the electric damper 45 to be in an “open” state. That is, the space in the server rack 20 is connected to the space in the room 2 by the electric damper 45. In this case, conditioned air is provided from the air conditioner 10 into the room 2. Then, the air in the room 2 is sucked into the server rack 20 by the fan unit 30. Further, the air in the server rack 20 is discharged out of the server rack 20 by the fan unit 30. The conditioned air sucked into the server rack 20 from the space in the room 2 keeps the temperature of the server computer 1 in an appropriate temperature range.
[0044]
When the room temperature in the room 2 is outside the appropriate temperature range of the server computer 1, the unit control section 41 transmits an opening / closing signal to the electric damper 45 so that the electric damper 45 is closed (step S304). . The open / close signal transmitted from the unit control unit 41 causes the electric damper 45 to be in a “closed” state. That is, the space in the server rack 20 is connected to the space in the air duct 16 by the electric damper 45. Further, a control command is transmitted to the air conditioner 10 by the unit control unit 41 (step S305). According to the control command transmitted to the air conditioner 10, the air conditioner 10 stops supplying the conditioned air to the space in the room 2 and supplies the conditioned air into the air duct 16. The conditioned air supplied into the air duct 16 is drawn into the server rack 20 by the fan unit 30. Further, the air in the server rack 20 is discharged out of the server rack 20 by the fan unit 30. The temperature of the server computer 1 is kept in an appropriate temperature range by the conditioned air sucked into the server rack 20 from the air duct 16.
[0045]
(Occupant mode)
Next, FIG. 6 shows a flow of a signal when the “occupant mode” is selected in the unit control unit 41 and an operation of each device.
First, the presence or absence of a occupant in the room 2 is determined by the human sensor 44, and a determination result is transmitted to the unit control unit 41 (step S401).
[0046]
When there is an occupant in the room 2, the unit control unit 41 transmits an open / close signal to the electric damper 45 so that the electric damper 45 is opened (step S402). The open / close signal transmitted from the unit control unit 41 causes the electric damper 45 to be in an “open” state. That is, the space in the server rack 20 is connected to the space in the room 2 by the electric damper 45. In this case, conditioned air is provided from the air conditioner 10 into the room 2. Then, the air in the room 2 is sucked into the server rack 20 by the fan unit 30. Further, the air in the server rack 20 is discharged out of the server rack 20 by the fan unit 30. The conditioned air sucked into the server rack 20 from the space in the room 2 keeps the temperature of the server computer 1 in an appropriate temperature range.
[0047]
When there is no occupant in the room 2, the unit control section 41 transmits an open / close signal to the electric damper 45 so that the electric damper 45 is closed (step S403). The open / close signal transmitted from the unit control unit 41 causes the electric damper 45 to be in a “closed” state. That is, the space in the server rack 20 is connected to the space in the air duct 16 by the electric damper 45. Further, a control command is transmitted to the air-conditioning apparatus 10 by the unit control section 41 (step S404). According to the control command transmitted to the air conditioner 10, the air conditioner 10 stops supplying the conditioned air to the space in the room 2 and supplies the conditioned air into the air duct 16. The conditioned air supplied into the air duct 16 is drawn into the server rack 20 by the fan unit 30. Further, the air in the server rack 20 is discharged out of the server rack 20 by the fan unit 30. The temperature of the server computer 1 is kept in an appropriate temperature range by the conditioned air sucked into the server rack 20 from the air duct 16.
[0048]
<Features of this system>
(1)
In this server rack air conditioning system, the unit control unit 41 determines which of the space in the room 2 and the air conditioner 10 sucks air into the server rack 20. Then, based on the determination of the unit control unit 41, the electric damper 45 connects the space in the server rack 20 to one of the space in the room 2 and the space in the air duct 16. As a result, air is sucked into the server rack 20 from either the space in the room 2 or the space in the air duct 16.
[0049]
For this reason, when air is sucked into the server rack 20 from the space in the room 2, the temperature of the server computer 1 can be adjusted properly even if the air conditioner 10 does not directly provide conditioned air to the server rack 20. It can be kept in the temperature range. In this case, it is not necessary for the air conditioner 10 to supply conditioned air to the server rack 20, so that the power consumption of the air conditioner 10 can be reduced. Therefore, in this server rack air conditioning system, the power consumption of the system can be reduced.
[0050]
(2)
In this server rack air-conditioning system, when the “timer mode” is selected, the space in the server rack 20 is changed by the electric damper 45 into the room in which the conditioned air is provided by the air conditioner 10 within a predetermined time. 2 is connected to the space inside. Therefore, within a predetermined time, air is sucked into the server rack 20 from the space in the room 2 by the fan unit 30.
[0051]
Outside the predetermined time, the electric damper 45 connects the space in the server rack 20 with the space in the air duct 16 to which the conditioned air is provided by the air conditioner 10. Therefore, outside the predetermined time, air is sucked into the server rack 20 from the space in the air duct 16 by the fan unit 30.
Therefore, the air conditioning unit 40 can supply conditioned air into the server rack 20 from either the space in the room 2 or the space in the air duct 16 according to a predetermined time set in advance.
[0052]
Therefore, in this server rack air conditioning system, the usefulness of the system is improved.
(3)
In this server rack air-conditioning system, when the “temperature mode” is selected, if the room temperature in the room 2 is within the appropriate temperature range of the server computer 1, the electric damper 45 reduces the space in the server rack 20. Connected to the space in room 2. Therefore, when the room temperature in the room 2 is within the appropriate temperature range of the server computer 1, air is sucked into the server rack 20 from the space in the room 2 by the fan unit 30.
[0053]
When the room temperature inside the room 2 is outside the appropriate temperature range of the server computer 1, the space inside the server rack 20 is moved by the electric damper 45 into the air duct 16 where the conditioned air is provided by the air conditioner 10. Connected with space. Therefore, outside the predetermined time, air is sucked into the server rack 20 from the space in the air duct 16 by the fan unit 30.
[0054]
Therefore, the air conditioning unit 40 can supply conditioned air into the server rack 20 from either the space in the room 2 or the space in the air duct 16 according to the room temperature in the room 2. Therefore, in this server rack air conditioning system, the usefulness of the system is improved.
(4)
In this server rack air conditioning system, the air in the room 2 where the server rack 20 is installed is conditioned by the air conditioner 10. That is, the air in both the space in the server rack 20 and the space in the room 2 can be conditioned by one air conditioner 10. Therefore, it is not necessary to separately install a new air conditioner in order to condition the air in the room 2. For this reason, in this server rack air conditioning system, the configuration of equipment for air conditioning can be simplified.
[0055]
(5)
In this server rack air-conditioning system, when the “demand mode” is selected, if the predicted demand power exceeds a predetermined power, the electric damper 45 causes the space in the server rack 20 to be air-conditioned. The device 10 is connected to the space in the air duct 16 where the conditioned air is provided. Therefore, when the predicted power demand exceeds the predetermined power demand, the fan unit 30 draws air from the space in the air duct 16 into the server rack 20.
[0056]
When the predicted demand power amount does not exceed the predetermined power amount, the space in the server rack 20 is changed by the electric damper 45 to the space in the room 2 in which the conditioned air is provided by the air conditioner 10. Connected. Therefore, when the predicted demand power amount does not exceed the predetermined power amount, the fan unit 30 draws air from the space in the room 2 into the server rack 20.
[0057]
Therefore, the air conditioning unit 40 can supply conditioned air to the server rack 20 from either the space in the room 2 or the space in the air duct 16 according to the expected power demand of the air conditioner 10. Therefore, in this server rack air conditioning system, the usefulness of the system is improved.
(6)
In this server rack air-conditioning system, when the “occupant mode” is selected, if there is no occupant in the room 2, the electric damper 45 changes the space in the server rack 20 to the air conditioner 10. Is connected to the space in the air duct 16 where the conditioned air is provided. Therefore, when there is no occupant in the room 2, air is sucked into the server rack 20 from the space in the air duct 16 by the fan unit 30.
[0058]
When there is an occupant in the room 2, the space in the server rack 20 is connected by the electric damper 45 to the space in the room 2 in which the conditioned air is provided by the air conditioner 10. Therefore, when there is an occupant in the room 2, the fan unit 30 draws air from the space in the room 2 into the server rack 20.
[0059]
Therefore, the air-conditioning unit 40 can supply conditioned air into the server rack 20 from either the space in the room 2 or the space in the air duct 16 according to the presence or absence of a occupant in the room 2. Therefore, in this server rack air conditioning system, the usefulness of the system is improved.
(7)
In this server rack air-conditioning system, when the “demand mode” is selected and the predicted power demand exceeds a predetermined power demand, the air conditioner 10 stops the supply of the conditioned air to the space in the room 2. At the same time, conditioned air is provided in the air duct 16. When the predicted demand power amount does not exceed the predetermined power amount, the air conditioner 10 performs air conditioning in the room 2. For this reason, in this server rack air-conditioning system, the temperature of the server computer 1 can be maintained in an appropriate temperature range while the power consumption of the air conditioner 10 is kept at a certain level or less.
[0060]
(8)
In the server rack air-conditioning system, when the “timer mode” is selected, even if the current time is outside the predetermined time, the air-conditioning apparatus 10 stops supplying the conditioned air to the space in the room 2 and also sets the air duct 16 provides conditioned air. The same applies when the "temperature mode" is selected and the room temperature in the room 2 is outside the appropriate temperature range of the server computer 1. Further, the same applies when there is no occupant in the room 2 when the “occupant mode” is selected.
[0061]
As described above, in this server rack air conditioning system, air conditioning in the server rack 20 can be preferentially performed without performing air conditioning in the room 2. For this reason, in this server rack air conditioning system, the power consumption of the air conditioner 10 can be reduced.
(9)
In this server rack air-conditioning system, the air conditioner 10 includes a power storage device 14 that mainly stores electricity supplied from a commercial power supply at night. Therefore, the air conditioner 10 can accumulate electricity in the power storage device 14 at night when power consumption is difficult to concentrate, and can operate using the accumulated electricity. For this reason, in this server rack air-conditioning system, time periods of power consumption can be dispersed.
[0062]
(10)
In this server rack air conditioning system, electricity mainly stored at night in the power storage device 14 of the air conditioner 10 is always supplied to the server computer 1, the fan unit 30, and the air conditioning unit 40. For this reason, in this server rack air-conditioning system, the server computer 1, the fan unit 30, and the air-conditioning unit 40 can operate relatively stably even when a power failure such as a power failure or a drop in power supply voltage occurs.
[0063]
(11)
In this server rack air-conditioning system, when a commercial power supply fails, the air conditioner 10 stops supply of conditioned air to the space in the room 2 and supplies conditioned air into the air duct 16. In this case, the electric damper 45 is in the “closed” state. That is, the space in the server rack 20 is connected to the space in the air duct 16 by the electric damper 45. Therefore, in the server rack air-conditioning system, the temperature of the server computer 1 is maintained in an appropriate temperature range even when the commercial power supply fails, so that the server computer 1 can operate stably.
[0064]
<Other embodiments>
Although the present invention has been described above, the specific configuration is not limited to the above-described embodiment, and can be changed without departing from the spirit of the invention.
(A)
In the above-described embodiment, various control modes are selected, for example, by the administrator of the server computer 1, and the temperature of the server computer 1 is maintained in an appropriate temperature range. Instead, the above-described various control modes may be appropriately combined to perform complex control of the air conditioner 10 and the electric damper 45.
[0065]
(B)
In the above embodiment, the supply source of the air taken into the server rack 20 is set to either the air duct 16 to which the conditioned air is provided by the air conditioner 10 or the space in the room 2. However, in winter, for example, in order to keep the temperature of the server computer 1 in an appropriate temperature range, it is more appropriate to take outdoor air into the server rack than to take indoor air into the server rack. The efficiency of keeping in the area may be high. In this case, instead of the above embodiment, the server rack air conditioning system may be configured to take air into the server rack from either inside the air duct or outside.
[0066]
That is, the system may be configured such that air is sucked into the server rack from either the inside of the air duct or the outside of the server rack.
(C)
In the above embodiment, the unit control unit 41 determines whether or not the air conditioner 10 preferentially supplies conditioned air to the server rack 20. Alternatively, the server rack air-conditioning system may be configured so that the air-conditioning apparatus determines whether to supply conditioned air to the server rack preferentially, for example, according to an instruction from a server computer administrator or the like. .
[0067]
(D)
In addition to the above embodiment, the server rack air-conditioning system may be configured to blow exhaust gas discharged from the server rack near the outdoor heat exchanger of the air conditioner. Since the exhaust gas discharged from the server rack often has a higher temperature than the air near the outdoor heat exchanger, the heating efficiency of the refrigerant in the outdoor heat exchanger is improved when the air conditioner is heated. Therefore, in this server rack air conditioning system, the operation efficiency of the air conditioner is improved.
[0068]
【The invention's effect】
As described above, according to the present invention, the following effects can be obtained.
In the invention according to claim 1, the supply source of the air for keeping the temperature of the electronic device in an appropriate temperature zone is set to either the adjacent space or the air conditioner by the setting device. Therefore, when the supply source is set in the adjacent space, there is no need for the air conditioner to supply air to the storage section. That is, in this case, the temperature of the electronic device can be maintained in an appropriate temperature range without the air conditioner supplying air to the storage section. Therefore, the energy consumption of the air conditioner can be reduced. For this reason, in this air conditioning system, the energy consumption of the system can be reduced.
[0069]
In the invention according to claim 2, the adjacent space is set as the supply source within the predetermined time. Outside the predetermined time, the air conditioner is set as the supply source. Therefore, the setting device can set the supply source to either the adjacent space or the air conditioner according to the time zone. Therefore, in this air conditioning system, the usefulness of the system is improved.
[0070]
In the invention according to claim 3, when the air temperature in the adjacent space is within the appropriate temperature range, the adjacent space is set as the supply source. When the air temperature in the adjacent space is outside the appropriate temperature range, the air conditioner is set as the supply source. Therefore, the setting device can set the supply source to either the adjacent space or the air conditioner according to the temperature of the adjacent space. Therefore, in this air conditioning system, the usefulness of the system is improved.
[0071]
In the invention according to claim 4, the air in the room where the storage unit is installed is conditioned by the air conditioner. Therefore, it is not necessary to separately provide a new air conditioner in order to balance the air in the room where the storage unit is installed. For this reason, the configuration of the equipment for air conditioning in the room can be simplified.
In the invention according to claim 5, when the energy consumption of the air conditioner exceeds a certain amount, the air conditioner stops indoor air conditioning, and the setting device sets the air conditioner as a supply source. When the energy consumption of the air conditioner is equal to or less than a certain amount, the air conditioner performs indoor air conditioning. Therefore, when the energy consumption of the air conditioner exceeds a certain amount, the air conditioner stops air conditioning in the room and performs only air conditioning in the storage unit. That is, in this air conditioning system, the energy consumption can be kept constant while the temperature of the electronic device is kept in an appropriate temperature range. For this reason, in this air conditioning system, energy consumption can be suppressed.
[0072]
In the invention according to claim 6, when there is an occupant in the room, the air conditioner performs air conditioning in the room. When there is no occupant in the room, the air conditioner stops air conditioning in the room, and the setting device sets the air conditioner as a supply source. Therefore, when there is no occupant in the room, the air conditioner stops air conditioning in the room and performs only air conditioning in the storage unit. For this reason, in this air conditioning system, it is possible to reduce energy consumption while maintaining the temperature of the electronic device in an appropriate temperature range.
[0073]
In the invention according to claim 7, the air conditioner includes a power storage device that stores electricity for operation. Therefore, this air conditioner can accumulate electricity in the power storage device at night or the like when power consumption is difficult to concentrate, and can operate using the accumulated electricity. For this reason, in this air conditioner, power consumption can be dispersed.
In the invention according to claim 8, the electricity stored in the power storage device is supplied to the electronic device. Therefore, even when a power failure such as a power failure or a voltage drop occurs, the electronic device can operate based on the electricity stored in the power storage device. Therefore, the electronic device can operate relatively stably.
[0074]
In the invention according to claim 9, in the event of a power failure such as a power failure, the setting device sets the air conditioner as a supply source. Therefore, the temperature of the electronic device is stably maintained in the appropriate temperature range. Therefore, in this air conditioner, the electronic device can operate more stably.
In the invention according to claim 10, the setting unit sets the supply source of the air for keeping the temperature of the electronic device in the appropriate temperature zone to either the adjacent space or the air conditioner. Therefore, when the supply source is set in the adjacent space, there is no need for the air conditioner to supply air to the storage section. That is, in this case, the temperature of the electronic device can be maintained in an appropriate temperature range without the air conditioner providing air to the storage section. Therefore, the energy consumption of the air conditioner can be reduced. For this reason, in this air conditioning system, the energy consumption of the system can be reduced.
[0075]
According to the eleventh aspect, the adjacent space is set as a supply source within a predetermined time. Outside the predetermined time, the air conditioner is set as the supply source. Therefore, in this air conditioning setting device, the supply source can be set to either the adjacent space or the air conditioner according to the time zone.
In the invention according to claim 12, when the air temperature in the adjacent space is within the appropriate temperature range, the adjacent space is set as a supply source. When the air temperature in the adjacent space is outside the appropriate temperature range, the air conditioner is set as the supply source. Therefore, in this air conditioning setting device, the supply source can be set to either the adjacent space or the air conditioner according to the temperature of the adjacent space.
[Brief description of the drawings]
FIG. 1 is a schematic diagram of a server rack air-conditioning system to which an embodiment of the present invention is applied.
FIG. 2 is a schematic configuration diagram of a control unit.
FIG. 3 is a flowchart of signals when “demand mode” is selected and operations of respective devices.
FIG. 4 is a flowchart of signals when “timer mode” is selected and the operation of each device.
FIG. 5 is a flowchart of a signal when “temperature mode” is selected and the operation of each device.
FIG. 6 is a flowchart of signals when the “occupant mode” is selected and the operation of each device.
[Explanation of symbols]
1 server computer (electronic equipment)
2 rooms (rooms)
10 Air conditioner
14 Power storage device
20 server rack (storage unit, storage device)
30 Fan unit (supply device)
40 air conditioning unit (setting device)
41 Unit control unit (judgment unit)
42 electric damper (setting part)

Claims (12)

An air conditioning system for maintaining a temperature of an electronic device (1) in an appropriate temperature range suitable for operation of the electronic device (1),
A storage section (20) for storing the electronic device (1);
An air conditioner (10) capable of providing conditioned air in the storage section (20);
A setting device (40) for setting any of the adjacent space adjacent to the storage section (20) and the air conditioner (10) as a supply source;
A supply device (30) for supplying air from the supply source into the storage section (20). The setting device (40) sets the adjacent space as a supply source during a predetermined time period, and sets the air conditioner (10) as a supply source outside the predetermined time period.
The air conditioning system according to claim 1. The setting device (40) sets the adjacent space as a supply source when the temperature of the adjacent space is within the appropriate temperature range, and sets the air conditioning device when the temperature of the adjacent space is outside the appropriate temperature range. (10) is set as the supplier,
The air conditioning system according to claim 1. The air conditioner (10) condition air in a room (2) in which the storage unit (20) is installed.
The air conditioning system according to any one of claims 1 to 3. The air conditioner (10) stops air conditioning in the room (2) when the consumed energy exceeds a certain amount, and stops the air in the room (2) when the consumed energy is less than a certain amount. Do harmony,
The setting device (40) sets the air conditioner (10) as the supply source when the energy consumption of the air conditioner (10) exceeds a certain amount.
The air conditioning system according to claim 4. The air conditioner (10) performs air conditioning in the room (2) when there is an occupant in the room (2), and performs air conditioning in the room (2) when there is no occupant in the room (2). Stops air conditioning in said chamber (2),
The setting device (40) sets the adjacent space as the supply source when there is an occupant in the room (2).
The air conditioning system according to claim 4. The air conditioner (10) includes a power storage device (14) for storing electricity.
The air conditioning system according to any one of claims 1 to 6. The electronic device (1) receives supply of electricity from the power storage device (14).
The air conditioning system according to claim 7. The setting device (40) sets the supply source to the air conditioner (10) in the event of a power failure.
An air conditioning system according to claim 8. In order to keep the temperature of the electronic device (1) in an appropriate temperature range suitable for the operation of the electronic device (1), an air-conditioning apparatus and an adjacent space adjacent to the storage device (20) in which the electronic device (1) is stored. (10) An air conditioning setting device (40) for supplying air into the storage device (20) from any of the above (10),
A determining unit (41) for determining which of the adjacent space and the air conditioner (10) is set as a supply source;
A setting unit (42) for setting the supply source based on the determination result of the determination unit (41);
An air conditioning setting device (40) comprising: The determination unit (41) determines the adjacent space as a supply source during a predetermined time period, and determines the air conditioner (10) as a supply source outside the predetermined time period.
An air conditioning setting device (40) according to claim 10. The determination unit (41) determines that the adjacent space is a supply source when the temperature of the adjacent space is within the appropriate temperature range, and determines the air conditioning apparatus when the temperature of the adjacent space is outside the appropriate temperature range. Judge (10) as the supplier,
An air conditioning setting device (40) according to claim 10 or 11.

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