JP2017083988A - Air conditioning system, controller, and control method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an air conditioning system, a controller, and a control method capable of reducing power consumption by a data center air conditioning system.SOLUTION: The air conditioning system controls to stop an indirect vaporization cooling system 106 constituting an air conditioning system 101 based on the temperature and the humidity of the outside air to shut-off the supply of outside air to the indirect vaporization cooling system, and supplies the outside air directly to the inside of a data center by using a channel for supplying the outside air into the inside of the data center without using the indirect vaporization cooling system.SELECTED DRAWING: Figure 1

Description

  The present invention relates to an air conditioning system, a control device, and a control method.

  In order to reduce the power consumption of the data center and reduce electricity bills, an outside air cooling method that does not use an air conditioner has attracted attention. The outside air cooling method is an air conditioning method that enables energy-saving operation of the data center because it does not require the power of the compressor. Among the outside air cooling methods, a direct outside air cooling method in which the outside air is directly taken into the data center is expected to obtain a high energy saving effect because the outside air can be directly used.

  A direct outside air cooling type data center usually cannot use outside air as it is for cooling Information Technology (IT) equipment, so in many cases the air conditioner unit is the front room of the server room where IT equipment is installed. Located in the air conditioner room.

  A cooling system is known in which outside air is not introduced into the heating element storage chamber, the air in the heating element storage chamber is supplied to an indirect vaporization cooling device for cooling, and the cooled air is supplied into the heating element storage chamber. (For example, refer to Patent Document 1). In addition, a cooling system using indirect evaporative cooling means is known (for example, see Patent Document 2).

JP 2012-113682 A JP2013-155931A

  A conventional air conditioning system includes a plurality of types of air conditioners for temperature control and humidity control, and controls the plurality of air conditioners based on temperature and humidity information of outside air. However, in the conventional air conditioning system, even when some or all of the air conditioners are not used, the outside air is allowed to pass through the stopped air conditioners, and the power consumption of the blower fan increases due to the air resistance of the air conditioners. There's a problem.

  An object of the present invention is to reduce power consumption of an air conditioning system.

  An air conditioning system according to an embodiment is an air conditioning system that adjusts the temperature and humidity of a room, and includes an indirect evaporative cooling device, a first air path, a second air path, and a control device.

  The indirect vaporization cooling device cools the input cooling target air and outputs the cooled cooling target air.

The first air path supplies outside air to the indirect evaporative cooling device.
The second air path supplies the outside air to the room without passing through the indirect evaporative cooling device.

  The control device, based on the temperature of the outside air and the humidity of the outside air, stops the indirect evaporative cooling device and shuts off the supply of the outside air from the first air path to the indirect evaporative cooling device, The outside air is supplied to the room using the second air path.

  According to the air conditioning system of the embodiment, power consumption can be reduced.

It is a lineblock diagram of an air-conditioning system concerning an embodiment. It is a block diagram of the control apparatus which concerns on embodiment. It is a figure which shows the operation mode of the air conditioning system corresponding to the temperature and humidity of external air. It is a flowchart of the control processing of the air conditioning system which concerns on embodiment. It is a detailed flowchart of a setting process. It is a figure which shows the flow of the air at the time of outside air mode. It is a figure which shows the flow of the air at the time of a circulation mode. It is a figure which shows the flow of the air at the time of humidification mode. It is a figure which shows the flow of the air at the time of external air cooling mode. It is a figure which shows the flow of the air at the time of the circulation cooling mode. It is a block diagram of information processing apparatus (computer).

Hereinafter, embodiments will be described with reference to the drawings.
FIG. 1 is a configuration diagram of an air conditioning system according to an embodiment.

  The air conditioning system 101 adjusts the temperature and humidity of the server room 102. In the server room 102, a server rack 103 on which IT equipment that generates heat such as a server is mounted is installed. In FIG. 1, the air flow in the server room 102 is indicated by arrows.

  The air conditioning system 101 includes an outside air inlet 104, an exhaust port 105, an indirect evaporative cooling device 106, fans 111 to 116, a valve (damper) 117-i (i = 1 to 3), a three-way valve 118-i, a control device 119, A temperature sensor 120-i, a humidity sensor 121-j (j = 1, 2), a connecting part 122-i, and a duct 123-k (k = 1 to 11) are provided.

  The outside air inlet 104 is adjacent to the outdoors and takes in outside air (OA).

  The exhaust port 105 exhausts air to the outdoors. The exhausted air is referred to as exhaust (EA).

  The indirect evaporative cooling device 106 has a configuration of a kind of air-to-air heat exchanger, and a number of wet channels and dry channels partitioned by a partition are stacked.

  The wet channel wall surface is wet-treated, and when a liquid (for example, water) is dropped on the wall surface, the wet channel is wetted inside. The liquid is vaporized by heat passing from the air and the dry channel passing through the wet channel, and the wall surface of the wet channel is cooled by the vaporization phenomenon. Humidified and cooled air is discharged from the exhaust port of the wet channel.

  Due to the cooling of the wet channel, a temperature difference is generated between the dry channel and the wet channel, and the sensible heat of the dry channel moves to the wet channel through the partition wall, so that the air passing through the dry channel is also cooled. Thereby, the cooled air is discharged from the exhaust port of the dry channel.

  A fan 111 is attached to the air inlet of the dry channel, and a fan 112 is attached to the air inlet of the wet channel, and air is sent to the dry channel and the wet channel, respectively.

  The indirect evaporative cooling device 106 has a large air resistance when air is allowed to pass therethrough due to the shape of the partition walls of the wet channel and the dry channel, a filter mounted on the indirect evaporative cooling device 106, and the like.

The fans 111 to 116 send out air.
The valve 117-i passes or blocks air by opening and closing.

The three-way valve 118-i allows air to pass in a specific direction by opening and closing the valve.
The control device 119 controls the indirect evaporative cooling device 106, the valve fans 111 to 116, 117-i, and the three-way valve 118-i based on the measured temperature and humidity. Fans 111 to 116, valve 117-i, and three-way valve 118-i operate according to control signals received from control device 119.

The temperature sensor 120-i measures the temperature and notifies the control device 119 of the measured temperature.
The humidity sensor 121-j measures the humidity and notifies the control device 119 of the measured humidity.

  The connection part 122-i connects the plurality of ducts 123-k. Air can pass between the connected ducts 123-k. The connection part 122-i is a pipe joint, for example.

  The duct 123-k forms a flow of air through the air. The duct 123-k is an example of an air path.

  A duct 123-1 is connected to the outside air inlet 104, and a temperature sensor 120-1, a humidity sensor 121-1, and a fan 115 are attached to the duct 123-1. The duct 123-1 branches in three directions, and each of the branched ducts 123-1 is connected to the connection part 122-2, the intake port of the wet channel of the indirect evaporative cooling device 106, and the connection part 122-1. The fan 115 is attached so as to suck in outside air, and the sucked outside air is sent to the connection portion 122-2, the intake port of the wet channel of the indirect evaporative cooling device 106, and the connection portion 122-1. The temperature sensor 120-1 measures the temperature of the outside air, and the humidity sensor 121-1 measures the humidity of the outside air, and notifies the control device 119 of it. Here, the temperature of outside air is OA temperature, and the humidity of outside air is OA humidity. Each of the ducts 123-1 branched into three is provided with a valve 117-i, which passes or blocks outside air by opening and closing.

  The connection part 122-1 is connected to the air inlet of the dry channel of the indirect evaporative cooling device 106. Moreover, the connection part 122-1 is connected with the three-way valve 118-3 through the duct 123-8. Moreover, the connection part 122-1 is connected with the duct 123-1 in which the valve 117-3 is installed among the ducts 123-1 branched into three.

  The exhaust port of the dry channel of the indirect vaporization cooling apparatus 106 is connected to the connection part 122-2 via the duct 123-2. The outlet of the wet channel of the indirect evaporative cooling device 106 is connected to the three-way valve 118-1 via the duct 123-3.

  The connecting part 122-2 is connected to the exhaust port of the dry channel of the indirect evaporative cooling device 106 via the duct 123-2, the three-way valve 118-1 via the duct 123-4, and the server room 102 via the duct 123-5. The three-way valve 118-3 is connected via an intake port and a duct 123-6.

  The three-way valve 118-1 is connected to the exhaust port of the wet channel of the indirect evaporative cooling device 106 via the duct 123-3, the connecting part 122-2 via the duct 123-4, and the connecting part 122- via the duct 12-7. 3 and 3 respectively.

  A fan 113 is installed at the inlet of the server room 102, and the fan 113 supplies air into the server room 102. The air supplied into the server room 102 is sucked into the server rack 103 from the intake side of the server rack 103, cools the internal IT equipment, and is exhausted from the exhaust side of the server rack 103. Let the air supplied to the server room 102 be a supply air (SA). A temperature sensor 120-2 and a humidity sensor 121-2 are installed on the intake side of the server rack 103. The temperature sensor 121-2 and the humidity sensor 121-2 measure the temperature and humidity of the air supplied to the server room 102, respectively. Here, let the temperature of the air supplied to the server room 102 be the SA temperature, and let the humidity of the air supplied to the server room 102 be the SA humidity. The temperature sensor 121-2 and the humidity sensor 121-2 notify the control device 119 of the measured temperature and humidity, respectively.

  A fan 114 is installed at the exhaust port of the server room 102, and the fan 114 exhausts air in the server room 102. The exhaust port of the server room 102 is connected to the three-way valve 118-2. A temperature sensor 120-3 is installed on the exhaust side of the server rack 103, for example, in the server room 102 and near the exhaust port of the server room 102. The temperature sensor 121-2 measures the temperature of the air exhausted from the server room 102 and notifies the control device 119 of it. Let the temperature of the air exhausted from the server room 102 be a Return Air (RA) temperature.

  The three-way valve 118-2 is connected to the connection part 122-3 via the three-way valve 118-3 and the duct 123-10 via the exhaust port of the server room 102 and the duct 123-9.

  The three-way valve 118-3 is connected to the three-way valve 118-2 via the duct 123-9, the connecting part 122-2 via the duct 123-6, and the connecting part 122-1 via the duct 123-8.

  The connecting portion 122-3 is connected to the exhaust port 105 through the duct 123-11, the three-way valve 118-1 through the duct 123-7, and the three-way valve 118-2 through the duct 123-10.

  A duct 123-11 is connected to the exhaust port 105, and a fan 116 is attached to the duct 123-11. A fan 116 is attached so as to exhaust air from the connecting portion 122-3 from the exhaust port 105.

FIG. 2 is a configuration diagram of the control device according to the embodiment.
The control device 119 includes a processing unit 151 and a storage unit 161.

  The processing unit 151 includes a threshold acquisition unit 152, a calculation unit 153, a comparison unit 154, a setting unit 155, and an output unit 156.

The threshold acquisition unit 152 reads and acquires threshold information 162 from the storage unit 161.
The calculation unit 153 acquires temperature and humidity from the temperature sensor 120-i and the humidity sensor 121-j, respectively. The calculation unit 153 calculates the dew point of the outside air and the air (SA) supplied to the server room 102.

  The comparison unit 154 compares the upper and lower limits of the temperature and humidity included in the threshold information 162 with the temperature and humidity of the air supplied to the server room 102.

  The setting unit 155 determines in which operation mode to operate based on the temperature and humidity of the outside air, the threshold information 162, the calculated dew point, and the temperature of the air exhausted from the server room 102. The setting unit 155 sets the operation of the indirect vaporization cooling device 106, the fans 111 to 116, the valve 117-i, and the three-way valve 118-i according to the determined operation mode.

  The output unit 156 outputs a control signal to the indirect vaporization cooling device 106, the fans 111 to 116, the valve 117-i, and the three-way valve 118-i so that the state set by the setting unit 155 is obtained. The setting unit 155 and the output unit 156 are examples of a control unit.

  The storage unit 161 is a storage device that stores data and programs used in the processing unit 151. The storage unit 161 stores threshold information 162. The threshold information 162 includes an upper limit value (upper limit threshold value) and a lower limit value (lower limit threshold value) of the temperature of air supplied to the server room 102 (SA temperature), and the humidity of the air supplied to the server room 102 (SA humidity). ) Upper limit value (upper limit threshold) and lower limit value (lower limit threshold).

FIG. 3 is a diagram illustrating an operation mode of the air conditioning system corresponding to the temperature and humidity of the outside air.
The horizontal axis of the graph of FIG. 3 is the outside air temperature (dry bulb temperature), and the vertical axis is the outside air humidity (absolute humidity).

  The air conditioning system 101 has five operation modes (mode (1) to mode (5)), and the setting unit 155 has the temperature and humidity of the outside air, threshold information 162, the calculated dew point temperature, and the server room 102. The operation mode is determined based on the temperature of the air exhausted from the air.

  In the embodiment, modes (1) to (5) are referred to as an outside air mode, a circulation mode, a humidification mode, an outside air cooling mode, and a circulation cooling mode, respectively.

  For example, when the temperature and humidity of the outside air correspond to the area A of the graph, the air conditioning system 101 operates in the outside air mode. When the temperature and humidity of the outside air correspond to the graph areas B and E, the air conditioning system 101 operates in the circulation mode. When the temperature and humidity of the outside air correspond to the regions C and D of the graph, the air conditioning system 101 operates in the humidification mode. When the temperature and humidity of the outside air correspond to the graph regions F, G, and H, the air conditioning system 101 operates in the outside air cooling mode. When the temperature and humidity of the outside air correspond to the graph areas J and I, the air conditioning system 101 operates in the circulation cooling mode.

  Details of the outside air mode, the circulation mode, the humidification mode, the outside air cooling mode, and the circulation cooling mode will be described later.

FIG. 4 is a flowchart of the control processing of the air conditioning system according to the embodiment.
In step S501, the calculation unit 153 acquires the temperature and humidity measured from the temperature sensor 120-i and the humidity sensor 121-j. As described above, the temperatures measured by the temperature sensors 120-1 to 120-3 are referred to as OA temperature, SA temperature, and RA temperature, respectively. In addition, the humidity measured by the humidity sensors 121-1 and 121-2 is assumed to be OA humidity and SA humidity, respectively.

  In step S <b> 502, the threshold acquisition unit 152 acquires threshold information 162 from the storage unit 161.

  In step S503, the calculation unit 153 calculates the dew point of the outside air (OA) and the air (SA) supplied to the server room 102. Hereinafter, the calculated dew point of outside air is referred to as OA dew point, and the dew point of air supplied to the server room 102 is referred to as SA dew point.

  In step S504, the comparison unit 154 compares the SA temperature with the upper limit value and the lower limit value of the SA temperature included in the threshold information 162. Further, the comparison unit 154 compares the SA humidity with the upper limit value and the lower limit value of the SA humidity included in the threshold information 162.

  In step S505, when the SA temperature is not less than the lower limit value of the SA temperature included in the threshold information 162 and not more than the upper limit value, and the SA humidity is not less than the lower limit value of the SA humidity and not more than the upper limit value included in the threshold information 162, the control is performed. The process proceeds to S506. That is, the acquired SA temperature is included in the range of the lower limit value and the upper limit value of the SA temperature included in the threshold information 162, and the acquired SA humidity is the lower limit value and the upper limit value of the SA humidity included in the threshold information 162. If it is included in the range, control proceeds to step S506. If the SA temperature is not less than the lower limit value and not more than the upper limit value of the SA temperature included in the threshold information 162, or if the SA humidity is not less than the lower limit value and not more than the upper limit value of the SA humidity included in the threshold information 162, the control proceeds to step S507. . That is, the acquired SA temperature is not included in the range of the lower limit value and upper limit value of the SA temperature included in the threshold information 162, or the acquired SA humidity is lower limit value and upper limit value of the SA humidity included in the threshold information 162. If it is not included in the range, the control proceeds to step S507.

  In step S506, setting unit 155 and output unit 156 maintain the current operation mode, and the process ends. The control process according to the embodiment is executed periodically, for example.

  In step S507, the setting unit 155 and the output unit 156 perform setting processing. Details of the setting process will be described later.

FIG. 5 is a detailed flowchart of the setting process.
FIG. 5 corresponds to step S507 in FIG.

  In step S511, the setting unit 155 sets the fans 113 and 114 to operation, and the output unit 156 outputs a control signal for operating the fans 113 and 114 to the fans 113 and 114. The fans 113 and 114 that have received the control signal operate to supply air to the server room 102 and exhaust air from the server room 102.

  In step S512, the setting unit 155 compares the OA dew point with the upper limit value of the SA temperature included in the threshold information 162. If the OA dew point is larger than the upper limit value of the SA temperature, the control proceeds to step S522. If the OA dew point is equal to or lower than the upper limit value of the SA temperature, the control proceeds to step S513.

  In step S513, the setting unit 155 compares the OA temperature with the upper limit value of the SA temperature included in the threshold information 162. If the OA temperature is higher than the upper limit value of the SA temperature, the control proceeds to step S520. If the OA temperature is equal to or lower than the upper limit value of the SA temperature, the control proceeds to step S514.

  In step S514, the setting unit 155 compares the OA humidity and the lower limit value of the SA humidity included in the threshold information 162. If the OA humidity is less than the lower limit value of the SA humidity, the control proceeds to step S519, and if the OA humidity is greater than or equal to the lower limit value of the SA humidity, the control proceeds to step S515.

  In step S515, the setting unit 155 compares the OA humidity with the upper limit value of the SA humidity included in the threshold information 162. If the OA humidity is higher than the upper limit value of the SA humidity, the control proceeds to step S518. If the OA humidity is equal to or lower than the upper limit value of the SA humidity, the control proceeds to step S516.

  In step S516, the setting unit 155 compares the OA temperature with the lower limit value of the SA temperature included in the threshold information 162. If the OA temperature is less than the lower limit value of the SA temperature, the control proceeds to step S518. If the OA temperature is equal to or higher than the lower limit value of the SA temperature, the control proceeds to step S517.

In step S517, the setting unit 155 sets the air conditioning system 101 to the outside air mode. Specifically, the setting unit 155 sets the indirect vaporization cooling device 106, the fans 111, 112, 115, 116, the valve 117-i, and the three-way valve 118-i as follows.
Indirect evaporative cooling device 106: Stop • Fans 111, 112: Stop • Fans 115, 116: Operation • Valve 117-1: Operation in the opening direction • Valves 117-2, 117-3: Operation in the closing direction • Three-way valve 118 -2: Operation to the exhaust side (that is, the valve is switched so that the exhaust of the server room 102 flows to the connecting portion 122-3)

  The output unit 156 sends control signals for operating the indirect evaporative cooling device 106, the fans 111, 112, 115, 116, the valve 117-i, and the three-way valve 118-i as described above to the indirect evaporative cooling device 106, the fan. 111, 112, 115, 116, valve 117-i, and three-way valve 118-i.

FIG. 6 is a diagram illustrating an air flow in the outside air mode.
In the outside air mode, the indirect evaporative cooling device 106 and the fans 111 and 112 are stopped. In addition, since the valve 117-1 is open and the valves 117-2 and 117-3 are closed, the outside air passes through the path in which the valve 117-1 is installed in the duct 123-1 branched into three. Then, it is supplied to the server room 102. That is, the outside air is supplied to the server room 102 through a path that does not pass through the indirect evaporative cooling device 106. Further, since the valves 117-2 and 117-3 are closed, the outside air to the indirect evaporative cooling device 106 is blocked. Thereby, the power consumption of the indirect vaporization cooling device 106 and the fans 111 and 112 can be reduced, and the air resistance by the indirect vaporization cooling device 106 is eliminated, so that the power consumption of the fans 113 and 115 can be suppressed.

Returning to FIG.
In step S518, the air conditioning system 101 is set to the circulation mode. Specifically, the setting unit 155 sets the indirect vaporization cooling device 106, the fans 111, 112, 115, 116, the valve 117-i, and the three-way valve 118-i as follows.
Indirect evaporative cooling device 106: Stop • Fans 111, 112, 115, 116: Stop • Valves 117-1, 117-2, 117-3: Operate in the closing direction • Three-way valve 118-2: Operate toward the air supply side ( That is, the valve is switched so that the exhaust from the server room 102 flows to the three-way valve 118-3)
Three-way valve 118-3: Operates downstream of the indirect vaporizer 106 (that is, switches the valve so that air from the three-way valve 118-2 flows to the connecting portion 122-2)

  The output unit 156 sends control signals for operating the indirect evaporative cooling device 106, the fans 111, 112, 115, 116, the valve 117-i, and the three-way valve 118-i as described above to the indirect evaporative cooling device 106, the fan. 111, 112, 115, 116, valve 117-i, and three-way valve 118-i.

FIG. 7 is a diagram illustrating the air flow in the circulation mode.
In the circulation mode, the exhaust from the server room 102 is circulated to supply air to the server room 102. Thereby, the temperature of the server room 102 can be raised and the humidity can be lowered.

Returning to FIG.
In step S519, the air conditioning system 101 is set to the humidification mode. Specifically, the setting unit 155 sets the indirect vaporization cooling device 106, the fans 111, 112, 115, 116, the valve 117-i, and the three-way valve 118-i as follows.
Indirect evaporative cooling device 106: operation fan 111: stop fan 112, 115, 116: operation valve 117-1, 117-2: operation in the opening direction valve 117-3: operation in the closing direction three-way valve 118 -1: Operation toward the supply side (that is, the valve is switched so that the exhaust gas of the indirect evaporative cooling device 106 flows to the connecting portion 122-2)
Three-way valve 118-2: Operates toward the exhaust side (that is, switches the valve so that the exhaust from the server room 102 flows to the connecting portion 122-3)

  The output unit 156 sends control signals for operating the indirect evaporative cooling device 106, the fans 111, 112, 115, 116, the valve 117-i, and the three-way valve 118-i as described above to the indirect evaporative cooling device 106, the fan. 111, 112, 115, 116, valve 117-i, and three-way valve 118-i.

FIG. 8 is a diagram illustrating an air flow in the humidification mode.
In the humidification mode, the exhaust from the wet channel of the indirect evaporative cooling device 106 is supplied to the server room 102. Thereby, the humidity of the server room 102 can be raised.

Returning to FIG.
In step S520, the setting unit 155 compares the OA temperature and the RA temperature. If the OA temperature is higher than the RA temperature, the control proceeds to step S522. If the OA temperature is equal to or lower than the RA temperature, the control proceeds to step S521.

In step S521, the air conditioning system 101 is set to the outside air cooling mode. Specifically, the setting unit 155 sets the indirect vaporization cooling device 106, the fans 111, 112, 115, 116, the valve 117-i, and the three-way valve 118-i as follows.
-Indirect evaporative cooling device 106: Operation-Fans 111, 112, 115, 116: Operation-Valves 117-2, 117-3: Operation in the opening direction-Valve 117-1: Operation in the closing direction-Three-way valve 118-1: Operation to the exhaust side (that is, the valve is switched so that the exhaust of the wet channel of the indirect evaporative cooling device 106 flows to the connecting portion 122-3)
Three-way valve 118-2: Operates toward the exhaust side (that is, switches the valve so that the exhaust from the server room 102 flows to the connecting portion 122-3)

  The output unit 156 sends control signals for operating the indirect evaporative cooling device 106, the fans 111, 112, 115, 116, the valve 117-i, and the three-way valve 118-i as described above to the indirect evaporative cooling device 106, the fan. 111, 112, 115, 116, valve 117-i, and three-way valve 118-i.

FIG. 9 is a diagram illustrating an air flow in the outside air cooling mode.
In the outside air cooling mode, since the temperature of the outside air is lower than the temperature of the exhaust in the server room 102, the outside air is cooled by the indirect evaporative cooling device 106 and supplied to the server room 102.

In step S522, the air conditioning system 101 is set to the circulation cooling mode. Specifically, the setting unit 155 sets the indirect vaporization cooling device 106, the fans 111, 112, 115, 116, the valve 117-i, and the three-way valve 118-i as follows.
-Indirect evaporative cooling device 106: Operation-Fans 111, 112, 115, 116: Operation-Valve 117-2: Operation in the opening direction-Valves 117-1, 117-3: Operation in the closing direction-Three-way valve 118-1: Operation to the exhaust side (that is, the valve is switched so that the exhaust of the wet channel of the indirect evaporative cooling device 106 flows to the connecting portion 122-3)
Three-way valve 118-2: Operates to the exhaust side (that is, switches the valve so that the exhaust from the server room 102 flows to the three-way valve 118-3)
Three-way valve 118-3: Operates upstream of the indirect vaporizer 106 (that is, switches the valve so that air from the three-way valve 118-2 flows to the connecting portion 122-1)

  The output unit 156 sends control signals for operating the indirect evaporative cooling device 106, the fans 111, 112, 115, 116, the valve 117-i, and the three-way valve 118-i as described above to the indirect evaporative cooling device 106, the fan. 111, 112, 115, 116, valve 117-i, and three-way valve 118-i.

FIG. 10 is a diagram illustrating an air flow in the circulation cooling mode.
In the circulation cooling mode, since the temperature of the outside air is higher than the temperature of the exhaust in the server room 102, the exhaust in the server room 102 is cooled by the indirect evaporative cooling device 106 and supplied to the server room 102.

  According to the air conditioning system according to the embodiment, when the indirect evaporative cooling device 106 is not used, the air is supplied to the server room 102 using a path that does not pass through the indirect evaporative cooling device 106. The air resistance of the fan 113 and 115 can be reduced.

  According to the air conditioning system according to the embodiment, the temperature of the server room 102 can be raised by using the exhaust of the server room 102 for supplying air to the server room 102 without using a heater. Therefore, the air conditioning system according to the embodiment can increase not only the cooling and humidification by the indirect vaporization cooling device 106 but also the temperature of the server room 102 by return air, so it can be used for all seasons without providing a heater. it can.

FIG. 11 is a configuration diagram of an information processing apparatus (computer).
The control device 119 of the embodiment can be realized by an information processing device 1 as shown in FIG. 11, for example.

  The information processing apparatus 1 includes a CPU 2, a memory 3, an input unit 4, an output unit 5, a storage unit 6, a recording medium drive unit 7, and a network connection unit 8, which are connected to each other by a bus 9.

  The CPU 2 is a central processing unit that controls the entire information processing apparatus 1. The CPU 2 corresponds to the processing unit 151.

  The memory 3 is a Read Only Memory (ROM) or Random Access Memory (RAM) that temporarily stores a program or data stored in the storage unit 6 (or the portable recording medium 10) during program execution. It is memory. The CPU 2 executes the various processes described above by executing programs using the memory 3.

  In this case, the program code itself read from the portable recording medium 10 or the like realizes the functions of the embodiment.

  The input unit 4 is, for example, a keyboard, a mouse, a touch panel, a camera, or a sensor, and is used for inputting an instruction or information from a user or an operator, acquiring data used in the information processing apparatus 1, or the like.

  The output unit 5 is, for example, a display or a printer. The output unit 5 is a device that outputs an inquiry to a user or an operator and a processing result, or operates under the control of the CPU 2.

  The storage unit 6 is, for example, a magnetic disk device, an optical disk device, a tape device, or the like. The information processing apparatus 1 stores the above-described program and data in the storage unit 6 and reads them into the memory 3 and uses them as necessary. The memory 3 and the storage unit 6 correspond to the storage unit 161.

  The recording medium driving unit 7 drives the portable recording medium 10 and accesses the recorded contents. As the portable recording medium, any computer-readable recording medium such as a memory card, a flexible disk, a compact disk read only memory (CD-ROM), an optical disk, a magneto-optical disk, or the like is used. The user stores the above-described program and data in the portable recording medium 10 and reads them into the memory 3 and uses them as necessary.

  The network connection unit 8 is connected to an arbitrary communication network such as a local area network (LAN) or a wide area network (WAN), and performs data conversion accompanying communication. The network connection unit 8 transmits data to a device connected via a communication network or receives data from a device connected via a communication network.

Regarding the above embodiment, the following additional notes are disclosed.
(Appendix 1)
An air conditioning system that adjusts room temperature and humidity,
An indirect evaporative cooling device that cools the input cooling target air and outputs the cooled cooling target air;
A first air path for supplying outside air to the indirect evaporative cooling device;
A second air path for supplying the outside air to the room without passing through the indirect evaporative cooling device;
Based on the temperature of the outside air and the humidity of the outside air, the indirect evaporative cooling device is stopped to cut off the supply of the outside air from the first air path to the indirect evaporative cooling device, and the second air A controller for supplying the outside air to the room using a route;
Air conditioning system equipped with.
(Appendix 2)
The control device supplies the outside air to the room using the second air path when the temperature of the outside air is within a first range and the humidity of the outside air is within a second range. The air conditioning system according to appendix 1, characterized by:
(Appendix 3)
When the temperature of the outside air is lower than the lower limit value of the first range or the humidity of the outside air is higher than the upper limit value of the second range, the control device supplies the exhaust of the room to the room. The air conditioning system according to Supplementary Note 1 or 2, which is characterized.
(Appendix 4)
The indirect evaporative cooling device includes a wet channel to which humidification target air is input and a dry channel to which the cooling target air is input, and the cooling target air in the dry channel due to a liquid vaporization phenomenon in the wet channel. The air to be cooled passes through the dry channel from the exhaust outlet of the dry channel, and the air to be cooled is output from the exhaust outlet of the wet channel to be humidified through the wet channel. Output
When the humidity of the outside air is lower than the lower limit value of the second range, the control device inputs the outside air as the humidification target air to the wet channel, and the humidification target is humidified through the wet channel. The air conditioning system according to any one of supplementary notes 1 to 3, wherein air is supplied to the room.
(Appendix 5)
When the temperature of the outside air is higher than the upper limit value of the first range and the temperature of the outside air is higher than the temperature of the exhaust of the room, the control device supplies the exhaust of the room as the cooling target air to the dry channel. The air conditioning system according to appendix 4, wherein the air to be cooled that is input and cooled through the dry channel is supplied to the room.
(Appendix 6)
A control device for an air conditioning system that has an indirect evaporative cooling device that cools input cooling target air and outputs the cooled cooling target air, and adjusts the temperature and humidity of the room,
The air conditioning system
A first air path for supplying outside air to the indirect evaporative cooling device;
A second air path for supplying the outside air to the room without passing through the indirect evaporative cooling device;
Have
The controller is
An acquisition unit for acquiring the temperature of the outside air and the humidity of the outside air;
Based on the temperature of the outside air and the humidity of the outside air, the indirect evaporative cooling device is stopped to cut off the supply of the outside air from the first air path to the indirect evaporative cooling device, and the second air And a control unit that supplies the outside air to the room using a route.
(Appendix 7)
The control unit supplies the outside air to the room using the second air path when the temperature of the outside air is within a first range and the humidity of the outside air is within a second range. The control device according to appendix 6, characterized by:
(Appendix 8)
When the temperature of the outside air is lower than the lower limit value of the first range or the humidity of the outside air is higher than the upper limit value of the second range, the control device supplies the exhaust of the room to the room. 8. The control device according to appendix 6 or 7, which is characterized.
(Appendix 9)
The indirect evaporative cooling device includes a wet channel to which humidification target air is input and a dry channel to which the cooling target air is input, and the cooling target air in the dry channel due to a liquid vaporization phenomenon in the wet channel. The air to be cooled passes through the dry channel from the exhaust outlet of the dry channel, and the air to be cooled is output from the exhaust outlet of the wet channel to be humidified through the wet channel. Output
When the humidity of the outside air is lower than the lower limit value of the second range, the control unit inputs the outside air as the humidification target air to the wet channel, and the humidification target is humidified through the wet channel. The control device according to any one of appendices 6 to 8, wherein air is supplied to the room.
(Appendix 10)
When the temperature of the outside air is higher than the upper limit value of the first range and the temperature of the outside air is higher than the temperature of the exhaust of the room, the control unit supplies the exhaust of the room as the cooling target air to the dry channel. 15. The control device according to appendix 14, wherein the air to be cooled that is input and cooled through the dry channel is supplied to the room.
(Appendix 11)
An indirect evaporative cooling device that cools an input air to be cooled and outputs the cooled air to be cooled, and a control device, and a control method for an air conditioning system that adjusts the temperature and humidity of a room,
The air conditioning system
A first air path for supplying outside air to the indirect evaporative cooling device;
A second air path for supplying the outside air to the room without passing through the indirect evaporative cooling device;
Have
The controller is
Based on the temperature of the outside air and the humidity of the outside air, the indirect evaporative cooling device is stopped to cut off the supply of the outside air from the first air path to the indirect evaporative cooling device, and the second air A control method comprising supplying the outside air to the room using a route.
(Appendix 12)
The control device supplies the outside air to the room using the second air path when the temperature of the outside air is within a first range and the humidity of the outside air is within a second range. The control method according to appendix 11, characterized by:
(Appendix 13)
When the temperature of the outside air is lower than the lower limit value of the first range or the humidity of the outside air is higher than the upper limit value of the second range, the control device supplies the exhaust of the room to the room. 13. The control method according to appendix 11 or 12, which is a feature.
(Appendix 14)
The indirect evaporative cooling device includes a wet channel to which humidification target air is input and a dry channel to which the cooling target air is input, and the cooling target air in the dry channel due to a liquid vaporization phenomenon in the wet channel. The air to be cooled passes through the dry channel from the exhaust outlet of the dry channel, and the air to be cooled is output from the exhaust outlet of the wet channel to be humidified through the wet channel. Output
When the humidity of the outside air is lower than the lower limit value of the second range, the control device inputs the outside air as the humidification target air to the wet channel, and the humidification target is humidified through the wet channel. 14. The control method according to any one of appendices 11 to 13, wherein air is supplied to the room.
(Appendix 15)
When the temperature of the outside air is higher than the upper limit value of the first range and the temperature of the outside air is higher than the temperature of the exhaust of the room, the control device supplies the exhaust of the room as the cooling target air to the dry channel. 15. The control method according to claim 14, wherein the cooling target air that is input and cooled through the dry channel is supplied to the room.

DESCRIPTION OF SYMBOLS 101 Air conditioning system 104 Outside air intake port 105 Exhaust port 106 Indirect vaporization cooling device 111-116 Fan 117-i valve 118-i Three-way valve 119 Control device 120-i Temperature sensor 121-j Humidity sensor 122-i Connection part 123-k Duct 151 Processing Unit 152 Threshold Value Acquisition Unit 153 Calculation Unit 154 Comparison Unit 155 Setting Unit 156 Output Unit 161 Storage Unit 162 Threshold Information

Claims (7)

An air conditioning system that adjusts room temperature and humidity,
An indirect evaporative cooling device that cools the input cooling target air and outputs the cooled cooling target air;
A first air path for supplying outside air to the indirect evaporative cooling device;
A second air path for supplying the outside air to the room without passing through the indirect evaporative cooling device;
Based on the temperature of the outside air and the humidity of the outside air, the indirect evaporative cooling device is stopped to cut off the supply of the outside air from the first air path to the indirect evaporative cooling device, and the second air A controller for supplying the outside air to the room using a route;
Air conditioning system equipped with.   The control device supplies the outside air to the room using the second air path when the temperature of the outside air is within a first range and the humidity of the outside air is within a second range. The air conditioning system according to claim 1.   The control device supplies the exhaust of the room to the room when the temperature of the outside air is lower than the lower limit value of the first range or the humidity of the outside air is higher than the upper limit value of the second range. The air conditioning system according to claim 1 or 2. The indirect evaporative cooling device includes a wet channel to which humidification target air is input and a dry channel to which the cooling target air is input, and the cooling target air in the dry channel due to a liquid vaporization phenomenon in the wet channel. The air to be cooled passes through the dry channel from the exhaust outlet of the dry channel, and the air to be cooled is output from the exhaust outlet of the wet channel to be humidified through the wet channel. Output
When the humidity of the outside air is lower than the lower limit value of the second range, the control device inputs the outside air as the humidification target air to the wet channel, and the humidification target is humidified through the wet channel. The air conditioning system according to any one of claims 1 to 3, wherein air is supplied to the room.   When the temperature of the outside air is higher than the upper limit value of the first range and the temperature of the outside air is higher than the temperature of the exhaust of the room, the control device supplies the exhaust of the room as the cooling target air to the dry channel. The air conditioning system according to claim 4, wherein the air to be cooled that is input and cooled through the dry channel is supplied to the room. A control device for an air conditioning system that has an indirect evaporative cooling device that cools input cooling target air and outputs the cooled cooling target air, and adjusts the temperature and humidity of the room,
The air conditioning system
A first air path for supplying outside air to the indirect evaporative cooling device;
A second air path for supplying the outside air to the room without passing through the indirect evaporative cooling device;
Have
The controller is
An acquisition unit for acquiring the temperature of the outside air and the humidity of the outside air;
Based on the temperature of the outside air and the humidity of the outside air, the indirect evaporative cooling device is stopped to cut off the supply of the outside air from the first air path to the indirect evaporative cooling device, and the second air A controller for supplying the outside air to the room using a route;
A control device comprising: An indirect evaporative cooling device that cools an input air to be cooled and outputs the cooled air to be cooled, and a control device, and a control method for an air conditioning system that adjusts the temperature and humidity of a room,
The air conditioning system
A first air path for supplying outside air to the indirect evaporative cooling device;
A second air path for supplying the outside air to the room without passing through the indirect evaporative cooling device;
Have
The controller is
Based on the temperature of the outside air and the humidity of the outside air, the indirect evaporative cooling device is stopped to cut off the supply of the outside air from the first air path to the indirect evaporative cooling device, and the second air A control method comprising supplying the outside air to the room using a route.