JP2014238783A - Air conditioner control system, air conditioner control method and air conditioner air quantity optimization program - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a technique capable of reducing the power consumption of an air conditioner as much as possible while avoiding the occurrence of new sneak of heat.SOLUTION: An air conditioner air quantity optimization system 200 has an air quantity reduction rate calculation part 203 for acquiring an air quantity reduction rate of cool air blown out by the air conditioner and the temperature of air entering a rack when the air conditioner is operated at the air quantity reduction rate, determining the existence/absence of the occurrence of new sneak of heat on the basis of the acquired air quantity reduction rate and the temperature of the entering air, and determining an air quantity reduction rate before the occurrence of new sneak of heat as the air quantity reduction rate for operating the air conditioner.

Description

  The present invention relates to an air conditioner control system, an air conditioner control method, and an air conditioner air volume optimization program.

  The power consumption of data centers and the like tends to increase year by year. In addition to IT (Information Technology) devices such as server devices, storage devices, and network devices that constitute a data center, there is a demand for power saving of air conditioners that cool these devices.

  The air conditioner in the server room is operated under the condition that the inlet temperature to each rack is kept at a predetermined temperature. The configuration of the air conditioner in the server room is designed according to the rated power consumption of the IT equipment, and all the air conditioners are operated with the maximum air flow. However, since not all IT devices are always installed as designed, in such a case, there is room for air conditioning, and power consumption can be reduced. That is, the power consumption of the air conditioner can be reduced by controlling the number of operating air conditioners and the amount of blown air according to the installation status of the IT equipment.

  In the current server room, IT equipment is mounted in a rack, and a rack row in which a plurality of racks are arranged in a row is formed. In the server room, a plurality of rack rows are formed, and it is common that the inlets or the outlets of the IT equipment constituting the rack rows are opposed to each other across the passage. (Hereinafter, the passage on the inlet side of IT equipment is called cold aisle and the passage on the exhaust side is called hot aisle). By arranging the rack row in this way, the cold air blown out by the air conditioner under the floor is blown out to the cold aisle via the grating installed on the cold aisle floor, and the cold air is supplied to the inlet of the IT device. The Then, hot air is exhausted from the exhaust port of the IT device to the hot aisle, and an air flow is formed in which the air conditioner collects the hot air from the hot aisle. By creating such an air flow, it is possible to efficiently cool the IT equipment.

  However, if the supply air volume of the air conditioner is insufficient, the exhaust of the IT equipment to the hot aisle will flow into the cold aisle more than a predetermined amount, and new heat wraparound will occur, which causes the temperature of the cold air supplied to the inlet It rises and IT equipment cannot be cooled efficiently. For this reason, it is necessary to make air volume blown out from an air conditioner over a certain level.

  In general air conditioners, the fan and chiller occupy most of the power consumption. By reducing the air volume of the air conditioner and reducing the power consumption of the fan, energy saving of the air conditioner can be realized. On the other hand, when the air volume of the air conditioner is insufficient and new heat wraparound occurs, the efficiency of heat recovery of the air conditioner decreases, and the power consumption of the chiller increases. Therefore, by setting the air volume of the air conditioner appropriately, it is required to reduce the fan power consumption of the air conditioner while avoiding the occurrence of new heat wraparound.

  In JP 2011-59739 A (Patent Document 1), the temperature of the air taken in by the IT equipment is acquired from a temperature sensor installed on the intake side of the IT equipment housed in the rack device. And a temperature prediction apparatus estimates the temperature change of air from the acquired temperature. Thereafter, the temperature prediction device calculates a temperature gradient from the estimated temperature change, and notifies the alarm as a temperature abnormality when the calculated temperature gradient exceeds a predetermined threshold. In addition, the temperature prediction device identifies the time required to reach a temperature equal to or higher than a predetermined threshold based on the estimated temperature change, and if the specified time exceeds the predetermined time, an alarm is notified as a temperature abnormality. To do.

  In Japanese Patent Application Laid-Open No. 2008-82597 (Patent Document 2), a temperature state acquisition unit that acquires the temperature state of the device, a temperature adjustment device that adjusts the temperature of the device room under the set temperature adjustment conditions, and the acquired temperature Based on the state, the temperature state in the equipment room is simulated under a plurality of temperature adjustment conditions, the optimum temperature adjustment condition is determined according to the result, and the temperature adjustment device is operated under the determined optimum temperature adjustment condition. .

  Japanese Patent Application Publication No. 2007-505285 (Patent Document 3) provides a system for determining a recirculation index value of an air flow in a data center. The system comprises a controller having a metering module configured to determine an index value of air recirculation within one or more locations of the data center.

JP 2011-59739 A JP 2008-82597 A Special table 2007-505285

  In Patent Document 1, a time-series temperature change is predicted, but the correlation with the air volume is not taken into consideration.

  In Patent Document 2, three-dimensional thermal fluid simulation is used. However, this requires a large number of man-hours for model creation, and there is a problem that introduction cost and maintenance management cost increase. Moreover, if the simulation of all the streets is implemented, the number of adjustment conditions increases as the number of air conditioners, the settable number of temperatures and the set number of airflows increase.

  Patent Document 3 derives an index for air recirculation, but does not mention the correlation between the air volume due to the occurrence of heat sneaking and the inlet temperature to the rack. The air volume is only increased or decreased by the actuator according to the index value obtained from the temperature. For this reason, it is necessary to effectively set the air volume of the air conditioner from the correlation between the air volume and the inlet temperature to the rack using only the measurement information without using the three-dimensional thermal fluid simulation.

  An object of the present invention is to reduce the power consumption of an air conditioner while avoiding new heat wraparound in an air conditioner control system including a plurality of IT devices and air conditioners that cool these IT devices. It is providing the technique which can be reduced automatically.

  Of the inventions disclosed in the present application, the outline of typical ones will be briefly described as follows.

  One embodiment of the present invention is an air conditioner control system having a server room and an air conditioner air volume optimization system connected to the server room via a network, wherein the server room includes a rack, IT equipment accommodated in a rack, and an air conditioner that blows out cool air for cooling the IT equipment. The air conditioner air volume optimization system obtains the air volume reduction rate of the cold air blown out by the air conditioner and the inlet temperature to the rack when the air conditioner is operated at the air volume reduction rate, Based on the acquired air volume reduction rate and the inlet temperature, it is determined whether or not a new heat sneak occurs, and the air volume reduction rate before the new heat sneaking occurs is used to operate the air conditioner. An air volume reduction rate calculation unit that determines the air volume reduction rate is provided.

  In another embodiment, there is provided an air conditioner control method in an air conditioner control system having a server room and an air conditioner air volume optimization system connected to the server room via a network, wherein the air conditioner air volume is The air volume reduction rate calculation unit of the optimization system has an acquisition step of acquiring the air volume reduction rate of the cool air blown out by the air conditioner and the inlet temperature to the rack when the air conditioner is operated at the air volume reduction rate. . Further, the air volume reduction rate calculation unit determines whether or not a new heat sneak occurs based on the acquired air volume reduction rate and the intake air temperature, and the air volume reduction just before the new heat sneak occurs. An air volume reduction rate determining step for determining a rate as the air volume reduction rate for operating the air conditioner;

  In another embodiment, an air conditioner air volume optimization program for causing a computer of an air conditioner control system to have a server room and an air conditioner air volume optimization system connected to the server room via a network. When the air volume reduction rate calculation unit of the air conditioner air volume optimization system operates the air conditioner with the air volume reduction rate of the cool air blown out by the air conditioner and the air volume reduction rate, the inlet air temperature to the rack And causing the computer to execute an acquisition step of acquiring. Further, the air volume reduction rate calculation unit determines whether or not a new heat sneak occurs based on the acquired air volume reduction rate and the intake air temperature, and the air volume reduction just before the new heat sneak occurs. Causing the computer to execute an air volume reduction rate determining step of determining a rate as the air volume reduction rate for operating the air conditioner.

  Among the inventions disclosed in the present application, effects obtained by typical ones will be briefly described as follows.

  According to an embodiment of the present invention, an air conditioner control system including a plurality of IT devices and an air conditioner that cools the IT devices avoids the occurrence of new heat wraparound, It becomes possible to reduce power consumption as much as possible.

It is a figure which shows the outline | summary of the structural example of the air conditioner control system in Embodiment 1 of this invention. It is a figure which shows the outline | summary of the structural example of a server room in the air conditioner control system in Embodiment 1 of this invention. It is a figure explaining the airflow generated in a server room in the air-conditioner control system in Embodiment 1 of this invention. It is a figure which shows the outline | summary of the structural example of the table which a server room structure information storage part memorize | stores in the air conditioner control system in Embodiment 1 of this invention. It is a figure which shows the outline | summary of the whole process in the air conditioner control system in Embodiment 1 of this invention. It is a figure which shows the outline | summary of the air volume reduction rate determination process in the air conditioner control system in Embodiment 1 of this invention. In the air conditioner control system in Embodiment 1 of this invention, it is a figure which shows the example of correlation with an air volume reduction rate and the temperature entered into a rack. It is a figure which shows the outline | summary of the structural example of a server room in the air conditioner control system in Embodiment 1 of this invention. It is a figure which shows the outline | summary of the structural example of a server room in the air conditioner control system in Embodiment 1 of this invention. It is a figure which shows the outline | summary of the structural example of a server room in the air conditioner control system in Embodiment 1 of this invention. It is a figure which shows the outline | summary of the structural example of a server room in the air conditioner control system in Embodiment 1 of this invention. It is a figure which shows the outline | summary of the structural example of a server room in the air conditioner control system in Embodiment 1 of this invention. It is a figure which shows the outline | summary of the structural example of a server room in the air conditioner control system in Embodiment 1 of this invention. It is a figure which shows the outline | summary of the structural example of the air conditioner control system in Embodiment 2 of this invention. It is a figure which shows the outline | summary of the structural example of the table which a correlation information storage part memorize | stores in the air conditioner control system in Embodiment 2 of this invention. It is a figure which shows the example of the air volume reduction rate determination process in the air conditioner control system in Embodiment 2 of this invention.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. Note that components having the same function are denoted by the same reference symbols throughout the drawings for describing the embodiment, and the repetitive description thereof will be omitted.

[Embodiment 1]
The first embodiment will be described with reference to FIGS.

  The air conditioner control system according to Embodiment 1 of the present invention gradually increases the air volume reduction rate of the cool air blown from the air conditioner, and increases the air volume reduction rate every time the air volume reduction rate is increased. Get the inlet temperature to the rack. Based on the correlation between the obtained air volume reduction rate and the intake air temperature, the air consumption reduction power consumption can be avoided while identifying the range of air volume reduction rates at which new heat sneaking occurs, while avoiding new heat sneaking. The air volume reduction rate that can reduce the air pressure as much as possible is determined.

<System configuration>
FIG. 1 is a diagram showing an outline of a configuration example of an air conditioner control system according to Embodiment 1 of the present invention. In FIG. 1, the air conditioner control system has a server room 100 and an air conditioner air volume optimization system 200 connected to the server room 100 via a network.

  The air conditioner air volume optimization system 200 is installed with predetermined hardware and software. For example, the air conditioner air volume optimization system 200 includes a processor, a memory, and the like, and causes the computer of the air conditioner air volume optimization system 200 to function as an air conditioner control system by executing a program on the memory by the processor.

  The air conditioner air volume optimization system 200 includes a server room configuration information update unit 201, an air conditioner air volume adjustment unit 202, an air volume reduction rate calculation unit 203, a server room configuration information storage unit 204, and a server room configuration information acquisition unit 205. And an intake air temperature acquisition unit 206 and an air conditioner control unit 207.

  The server room configuration information acquisition unit 205 acquires server room configuration information including the positions and number of racks, IT devices, and gratings from the server room 100 by receiving input from an operator from a management screen (not shown). Here, the server room configuration information acquisition unit 205 acquires power consumption for each rack instead of receiving an input from the management screen regarding the installation status of the IT device in the rack, and determines whether the IT device is installed (this determination). May be determined as not installed when the power consumption is zero). Further, the server room configuration information acquisition unit 205 transmits server room configuration information indicating the number of installed IT devices acquired for each rack row to the server room configuration information update unit 201.

  The server room configuration information update unit 201 stores the installed number of IT devices collected for each rack row received from the server room configuration information acquisition unit 205 in a server room configuration information storage unit 204 (described later, FIG. 4). Furthermore, the server room configuration information update unit 201 is installed or removed from one of the racks, IT devices, and gratings in the server room 100 (for gratings, the outlet is blocked after removal). It is determined that the airflow in the server room has changed. Further, the server room configuration information update unit 201 determines that the airflow in the server room 100 has changed when the operation of the IT device in the server room 100 is stopped or activated.

  When it is determined that the air flow in the server room 100 has changed, the air conditioner air volume adjustment unit 202 sets the air conditioner air volume to a predetermined value, for example, the maximum air volume. Thereafter, the air conditioner air volume adjustment unit 202 sets the air conditioner air volume to a value that is gradually reduced. Each time the air conditioner air volume adjusting unit 202 sets the air conditioner air volume, the air conditioner air volume adjusting unit 202 transmits the set air conditioner air volume to the air conditioner control unit 207, and the air conditioner control unit 207 receives the received air conditioner. The air conditioner is controlled so that the air volume is the same. After the air conditioner control unit 207 controls the air conditioner, the intake air temperature acquisition unit 206 acquires the intake air temperature and transmits the acquired intake air temperature to the air volume reduction rate calculation unit 203. Thereafter, the air volume reduction rate calculating unit 203 tries to calculate the air conditioner air volume, and the air conditioner air volume adjusting unit 202 receives the result. The air conditioner air volume adjusting unit 202 reduces the air conditioner air volume until the air volume reduction rate calculating unit 203 calculates the air conditioner air volume.

  The intake air temperature acquisition unit 206 acquires an intake air temperature, which is a temperature measured by a temperature sensor provided at an inlet of the rack, a temperature sensor built in an IT device, or the like from the server room 100. Further, the intake air temperature acquisition unit 206 acquires an air volume reduction rate from the air conditioner (this air volume reduction rate indicates an air volume reduction rate when the maximum air volume that can be blown by the air conditioner is 100%). Then, the intake air temperature acquisition unit 206 transmits the acquired intake air temperature to the air volume reduction rate calculation unit 203. The air volume reduction rate calculation unit 203 holds the received air volume reduction rate and the inlet temperature to any rack in the server room 100 in association with each other.

  Further, when the intake air temperature acquisition unit 206 acquires the intake air temperature of the rack in the server room 100, for example, the intake air temperature at a plurality of locations such as the upper, middle, and lower stages of the rack is acquired to reduce the air volume. The rate calculating unit 203 may hold the correspondence between the received air volume reduction rate and the inlet temperatures at a plurality of locations in each rack. Further, when the intake air temperature acquisition unit 206 acquires the intake air temperature of the rack in the server room 100, the intake air temperature acquisition unit 206 acquires the intake air temperature at a plurality of locations such as the upper, middle, and lower stages of the rack, and the maximum The air volume reduction rate calculation unit 203 regards the value, median value, average value, and the like as the intake air temperature of the rack, and holds the correspondence between the received air volume reduction rates and the intake air temperatures at a plurality of locations in each rack. It may be.

  The air volume reduction rate calculation unit 203 determines an optimal air volume reduction rate for reducing the air volume while avoiding the occurrence of new heat wraparound. Further, the air volume reduction rate calculation unit 203 transmits to the air conditioner air volume adjustment unit 202 whether or not the air volume reduction rate has been determined, and when the air volume reduction rate can be determined, the determined air volume reduction rate is further transmitted to the air conditioner air volume. Transmit to the adjustment unit 202.

  The air conditioner air volume adjusting unit 202 sets the air conditioner air volume based on the setting value received from the air volume reduction rate calculating unit 203. Thereafter, the air conditioner air volume adjusting unit 202 transmits the set air conditioner air volume to the air conditioner control unit 207, and the air conditioner control unit 207 controls the air conditioner so as to be the received air conditioner air volume.

<Server room configuration>
FIG. 2 is a diagram showing an outline of a configuration example of the server room 100 in the air conditioner control system according to Embodiment 1 of the present invention.

  In FIG. 2, the server room 100 is designed so that eight rack rows 220 to 227 including ten racks 110 are installed, and an IT device 130 is accommodated in each rack 110. In the server room 100, four air conditioners 120, 121, 122, 123 and 80 gratings 150 are installed.

  Each rack 110 is installed in the server room 100 with the air inlet and the air outlet facing each other, a cold aisle is formed as a passage facing the air inlet of each rack 110, and a hot aisle is formed as a passage facing the air outlet. Is formed. As described above, by forming the hot aisle and the cold aisle, the cooled air is efficiently supplied to the rack 110.

  The air conditioners 120, 121, 122, and 123 operate according to the installation status of the IT device 130. More specifically, the air conditioners 120, 121, 122, 123 facing the hot aisle are responsible for cooling the IT equipment 130 accommodated in the racks 110 of the rack rows 220 to 227 facing the hot aisle. In the example of FIG. 2, the air conditioner 120 is responsible for cooling the IT equipment 130 accommodated in the racks 110 constituting the rack rows 220 and 222, and the air conditioner 121 is accommodated in the racks 110 constituting the rack rows 221 and 223. The air conditioner 122 is responsible for cooling the IT equipment 130 housed in the rack 110 constituting the rack rows 224 and 226, and the air conditioner 123 is the rack constituting the rack rows 225 and 227. Responsible for cooling the IT device 130 accommodated in the network 110.

  The air conditioners 120, 121, 122, 123 blow out cool air for cooling the IT device 130 toward the ventilation space provided under the floor of the server room 100. The cold air blown out by the air conditioners 120, 121, 122, 123 is blown out from each grating 150 after passing through the ventilation space under the floor and supplied to the cold aisle. And the inlet of each rack 110 attracts the cold air supplied to the cold aisle, and discharges the hot air from the exhaust outlet to the hot aisle.

<Air flow explanation>
FIG. 3 is a diagram illustrating airflow generated in server room 100 in the air conditioner control system according to Embodiment 1 of the present invention. A plurality of IT devices 130 are accommodated in the rack 110. In addition, a temperature measuring unit 111 (for example, a temperature sensor) is provided at the inlet 170 of the rack 110.

  In FIG. 3, the air conditioner 120 blows out cool air 160 toward the ventilation space 140 provided under the floor. The cold air 160 blown out by the air conditioner 120 passes through the underfloor ventilation space 140 and is then blown out from each grating 150 and supplied to the cold aisle. Thereafter, the cold air is sucked into the rack 110 from the air inlet 170 of the rack 110. The IT device 130 is cooled by the cool air 160 sucked into the rack 110, and the cool air 160 becomes hot air 180 by cooling the IT device 130. Thereafter, the hot air 180 is exhausted from the exhaust port 190 to the hot aisle, and the exhausted hot air 180 forms a heat recovery airflow 181 that is recovered by the air conditioner 120.

  Here, when the air volume of the cool air 160 blown out from the air conditioner 120 is insufficient, a new heat sneak 182 is generated in which the hot air exhausted into the hot aisle flows into the cold aisle over a predetermined value. When this new heat sneak 182 occurs, the temperature of the air supplied to the inlet port 170 rises and the IT device 130 cannot be efficiently cooled.

<Server room configuration information storage unit>
FIG. 4 is a diagram showing an outline of a configuration example of a table stored in the server room configuration information storage unit 204 in the air conditioner control system according to Embodiment 1 of the present invention. 4, the table stored in the server room configuration information storage unit 204 stores server room configuration information corresponding to each [server room configuration ID], and the server room configuration information includes [rack row number] [rack It has data items such as “number of installed units” [number of installed IT devices]. [Server room configuration ID] indicates a symbol for identifying server room configuration information. [Rack Row Number] indicates a number for identifying the rack rows 220 to 227. [Number of racks installed] indicates the number of racks 110 constituting the corresponding rack row 220 to 227. [Number of installed IT devices] indicates the number of IT devices accommodated in the racks 110 constituting the corresponding rack rows 220 to 227.

  Further, the server room configuration information storage unit 204 includes [air conditioner in charge of cooling the rack] [rack position] [installation location of IT equipment in the rack] [model number of installed IT equipment] [grating position ] May have data items such as [position of air conditioner].

<Overall processing>
FIG. 5 is a diagram showing an overview of overall processing in the air conditioner control system according to Embodiment 1 of the present invention.

  First, in S501, the server room configuration information update unit 201 acquires a change in the configuration of a rack, an IT device, a grating, and the like in the server room 100, and determines whether the air flow in the server room 100 has changed. . In S501, when the server room configuration information update unit 201 determines that the airflow in the server room 100 does not change (S501-No), the process proceeds to S501. On the other hand, when the server room configuration information update unit 201 determines that the airflow in the server room 100 has changed (S501—Yes), the process proceeds to S502.

  In S501, the server room configuration information update unit 201 has installed or removed any of the rack 110, the IT device 130, and the grating 150 in the server room 100 (for the grating 150, the outlet after the removal is performed). It is determined that the airflow in the server room 100 has changed. Furthermore, the server room configuration information update unit 201 may determine that the airflow in the server room 100 has changed when the operation of the IT device 130 in the server room 100 is stopped or activated.

  Specifically, in S501, the server room configuration information update unit 201 starts from the state in which the IT device 130 is not accommodated in any rack 110 of the server room 100 as shown in FIG. It is determined that the airflow in the server room 100 has changed when the IT equipment 130 is accommodated in all the racks 110 constituting the rack rows 220 and 222.

  In S501, the server room configuration information updating unit 201 stores the IT device 130 in some of the racks 110 constituting the rack rows 220 and 222 as shown in FIG. 11 from the state shown in FIG. It is determined that the air flow in the server room 100 has changed when the state is changed.

  Further, in S501, the server room configuration information update unit 201 changes the air flow in the server room 100 from the state shown in FIG. 9 described above when the grating 150 is newly installed as shown in FIG. It is determined that

  Further, in S501, the server room configuration information update unit 201 determines that the server room configuration information update unit 201 performs server installation when the rack row 224 in which the IT device 130 is not accommodated is newly installed as illustrated in FIG. 10 from the state illustrated in FIG. It is determined that the air flow in the room 100 has changed. In this way, by installing the rack row 224 across the cold aisle of the rack row 222 shown in FIG. 10, the rack row 224 becomes an obstacle wall, and the cold air blown out from the grating 150 on the cold aisle side is diffused. Can be reduced. Therefore, the air conditioners 120, 121, 122, and 123 can be operated at a higher air reduction rate by performing the processing from S502 onward after the rack row 224 is installed from the state shown in FIG.

  Further, in S501, the server room configuration information update unit 201 starts from the state in which the IT device 130 is accommodated in the rack 110 configuring the rack rows 220, 221, 222, and 224 as shown in FIG. As shown, when the IT device 130 accommodated in the rack 110 constituting the rack row 224 is removed, it is determined that the air flow in the server room 100 has changed.

  Further, the server room configuration information updating unit 201 determines that the air flow in the server room 100 has changed when the IT devices 130 are accommodated in some racks 110 constituting the rack rows 220 to 227 with a predetermined interval. You may judge. Further, the server room configuration information update unit 201 may determine that the airflow in the server room 100 has changed when the IT device 130 is moved between the rack rows 220 to 227.

  Next, in S502, the air conditioner air volume adjustment unit 202 determines the number of IT devices 130 that each air conditioner 120, 121, 122, 123 is responsible for cooling for each air conditioner 120, 121, 122, 123 in the server room. Obtained from the configuration information storage unit 204.

  Next, in S503, the air conditioner air volume adjustment unit 202 is an air conditioner 120, 121, 122, 123 in which the number of IT devices 130 in charge of cooling is small and the air volume is not adjusted. 122, 123 are selected as the air conditioners 120, 121, 122, 123 for adjusting the air volume. Note that the air conditioner air volume adjustment unit 202 excludes the air conditioners 120, 121, 122, and 123 whose number of IT devices 130 in charge of cooling is 0 from the selection targets. In S503, the air conditioner air volume adjusting unit 202 replaces the selection of the air conditioners 120, 121, 122, and 123 with a small number of IT devices 130 in charge of cooling, and each IT device 130 in charge of cooling. May select the air conditioners 120, 121, 122, 123 with a small sum of hot air discharged to the hot aisle. Further, in S503, the air conditioner air volume adjustment unit 202 cools the air conditioners 120, 121, 122, and 123 that target the IT equipment 130 housed in the rack 110 that constitutes the rack rows 220 to 227 facing the hot aisle. Alternatively, only the air conditioners 120, 121, 122, 123 located on both sides of these air conditioners 120, 121, 122, 123 may be selected.

  Next, in S504, an air volume reduction rate determination process (described later, FIG. 6) is performed, and the air volume reduction rates of the air conditioners 120, 121, 122, 123 selected in S503 are determined, and based on this air volume reduction rate. The air volume of cool air blown out by the air conditioners 120, 121, 122, 123 selected in S 503 is set by the air conditioner air volume adjusting unit 202. Thereafter, the air conditioner air volume adjusting unit 202 transmits the set air conditioner air volume to the air conditioner control unit 207, and the air conditioner control unit 207 receives the air conditioner 120, 121, 122, 123 so as to obtain the received air conditioner air volume. To control.

  Next, in S505, the air conditioner control unit 207 selects all the air conditioners 120, 121, 122, and 123 in S503, and determines whether or not the air volume of each of the air conditioners 120, 121, 122, and 123 is adjusted. judge. When the air conditioner control unit 207 determines that the air volume of any of the air conditioners 120, 121, 122, and 123 that needs to be adjusted is not adjusted (No in S505), the process proceeds to S503. On the other hand, when it is determined that the air conditioner control unit 207 has adjusted all the air volumes of the air conditioners 120, 121, 122, and 123 that require adjustment of the air volume (S505-Yes), the entire process is terminated.

  Here, the process for selecting the air conditioner in S503 and the process for determining the air volume reduction amount and adjusting the air volume will be specifically described below with reference to FIGS.

  In FIG. 12, the number of IT devices 130 to be cooled that are accommodated in the rack 110 that constitutes the rack rows 220 and 222 that the air conditioner 120 takes charge of is 20, and the rack rows 221 and 223 that the air conditioner 121 takes charge of. The number of IT devices 130 to be cooled that are accommodated in the rack 110 that constitutes the rack 110 is 10 and the cooling target that is accommodated in the rack 110 that constitutes the rack rows 224 to 227 that the air conditioners 122 and 123 are in charge of. The number of IT devices 130 is zero.

  In S503, the air conditioners 122 and 123 in which the IT device 130 is not accommodated in the rack 110 configuring the rack rows 224 to 227 in charge are excluded from the air volume adjustment targets. Then, the air conditioner air volume adjustment unit 202 first selects the air conditioner 121 in which the number of IT devices 130 to be cooled is 10, and then after the air volume of the air conditioner 121 is adjusted, the IT device to be cooled The air conditioner 120 whose number of 130 is 20 is selected, and then the whole process is finished after the air volume of the air conditioner 120 is adjusted.

  In FIG. 13, the number of IT devices 130 to be cooled accommodated in the racks 110 constituting the rack rows 220 and 222 that the air conditioner 120 is in charge of is 20, and the rack rows 221 and 223 that the air conditioner 121 is in charge of. The number of IT devices 130 to be cooled that are accommodated in the rack 110 that constitutes the rack is 10, and the IT devices that are to be cooled that are accommodated in the rack 110 that constitutes the rack rows 224 and 226 that the air conditioner 122 is responsible for. The number of 130 is three, and the number of IT devices 130 to be cooled that are accommodated in the rack 110 that constitutes the rack rows 225 and 227 handled by the air conditioner 123 is zero.

  In S503, the air conditioners 123 in which the IT devices to be cooled are not accommodated in the racks 110 constituting the rack rows 225 and 227 in charge are excluded from the selection targets for the air volume setting. The air conditioner air volume adjustment unit 202 first selects the air conditioner 122 in which the number of IT devices 130 to be cooled is three, and after the air volume of the air conditioner 122 has been adjusted, the IT device to be cooled. After selecting the air conditioner 121 whose number of 130 is 10, and after adjusting the air volume of the air conditioner 121, select the air conditioner 120 whose number of IT devices 130 to be cooled is 20, and then After the air volume of the air conditioner 120 is adjusted, the entire process is terminated.

<Air volume reduction rate determination process>
FIG. 6 is a diagram showing an outline of the air volume reduction rate determination process in the air conditioner control system according to Embodiment 1 of the present invention.

  First, in step S601, the air conditioner control unit 207 controls the air volume of the cool air blown out from the selected air conditioners 120, 121, 122, and 123 to be the maximum air volume.

  Next, in S602, the air volume reduction rate calculation unit 203 sets 1 to i that is a measurement point number.

Next, in S603, the air volume reduction rate calculation unit 203 calculates Q ₁ that is the air volume reduction rate (this air volume reduction rate is 0%) and T ₁ that is the inlet temperature measured by the temperature measurement unit 111. get. The air volume reduction rate calculation unit 203 holds i (the value of i is 1), Q _1, and T ₁ in association with each other.

  Next, in S604, the air conditioner air volume adjusting unit 202 sets the air conditioner air volume set by increasing the air volume reduction rate at a predetermined rate (for example, 10%, but the reduction rate to be increased is not always the same). Is transmitted to the air conditioner control unit 207. The air conditioner control unit 207 controls the air conditioners 120, 121, 122, and 123 so that the received air conditioner air volume is obtained.

  Next, in S605, the air volume reduction rate calculation unit 203 increments i.

Next, in S606, the air volume reduction rate calculation unit 203 acquires Q _i that is the air volume reduction rate that has been increased to S604 and T _i that is the inlet temperature measured by the temperature measurement unit 111. The air volume reduction rate calculation unit 203 holds i, Q _i, and T _i in association with each other. When the intake air temperature acquired in S606 is equal to or higher than a predetermined value, the air conditioner air volume adjustment unit 202 adjusts the air volume reduction rate to be low until the intake air temperature becomes less than the predetermined value, and the air conditioner The air volume reduction rate may be determined as the maximum value in a range where the inlet temperature is less than a predetermined value.

  Next, in S607, the air volume reduction rate calculation unit 203 determines whether the value of i is 3 or more. When the air volume reduction rate calculation unit 203 determines that the value of i is less than 3 (S607—No), the process proceeds to S604. On the other hand, when the air volume reduction rate calculation unit 203 determines that the value of i is 3 or more (S607—Yes), the process proceeds to S608.

Next, in S608, the air volume reduction rate calculation unit 203 determines the slope A _{i− of the} straight line connecting the coordinates (Q _i−2 , T _i−2 ) and the coordinates (Q _i−1 , T _i−1 ). ₁ is calculated. Further, the air volume reduction rate calculation unit 203 calculates a slope A _{i of} a straight line connecting the coordinates (Q _i−1 , T _i−1 ) and the coordinates (Q _i , T _i ). In step S608, the air volume reduction rate calculation unit 203 may calculate the slope that is a negative value as zero.

Next, in S609, the air volume reduction rate calculator 203 by comparing the _{A i} and _{A i-1,} determines whether _{A i} is greater than _{A i-1.} When the air volume reduction rate calculation unit 203 determines that A _i is smaller than A _i−1 (S609—No), the process proceeds to S604. On the other hand, when the air volume reduction rate calculation unit 203 determines that A _i is greater than A _i-1 (S609-Yes), the air volume reduction rate calculation unit 203 determines the air volume reduction rate Q at the measurement point i-1. _It is determined that a new heat sneak occurs between _i-1 and Q _i that is the air volume reduction rate of the measurement point i. Then, in S610, the air volume reduction rate calculation unit 203 operates the air conditioners 120, 121, 122, and 123 selected in S503 with Q _i-1 that is the air volume reduction rate just before a new heat sneak occurs. The air volume reduction rate to be determined is determined, and the air volume reduction rate determination process is terminated. Thereafter, the air volume reduction rate calculation unit 203 transmits Q _i-1 that is the air volume reduction rate determined in S609 to the air conditioner air volume adjustment unit 202. The air conditioner air volume adjustment unit 202 sets the air conditioner air volume based on the received air volume reduction rate Q _i−1 , and transmits the set air conditioner air volume to the air conditioner controller 207. The air conditioner control unit 207 controls the corresponding air conditioners 120, 121, 122, and 123 so as to obtain the received air conditioner air volume, and the air volume of the cool air blown out by the air conditioners 120, 121, 122, and 123 is adjusted.

Here, the processing of S608 and S609 will be specifically described with reference to FIG. FIG. 7 is a diagram illustrating an example of the correlation between the air volume reduction rate and the temperature entered in the rack 110 in the air conditioner control system according to Embodiment 1 of the present invention. In FIG. 7, the vertical axis represents the inlet air temperature (° C.), and the horizontal axis represents the air volume reduction rate (%). First, in step S <b> 608, the air volume reduction rate calculation unit 203 calculates an inclination 520 and an inclination 521. Here, the inclination 520 (this inclination corresponds to A _i-1 ) corresponds to the inclination of a straight line connecting the measurement points 511 and 512 plotted for each predetermined air volume reduction rate (for example, 10%). . Further, the inclination 521 (this inclination corresponds to A _i ) corresponds to the inclination of a straight line connecting the measurement points 512 and 513. In step S <b> 609, the air volume reduction rate calculation unit 203 determines whether the slope 521 is larger than the slope 520 by comparing the slope 520 and the slope 521. If the air volume reduction rate calculation unit 203 determines that the slope 521 is larger than the slope 520 (S609-Yes), the process proceeds to S610. Then, in S610, the air volume reduction rate calculation unit 203 sets Q _i-1 that is the air volume reduction rate before the new heat sneaking occurs as the air volume reduction rate for operating the air conditioners 120, 121, 122, and 123. decide.

It is also possible to consider temperature measurement errors when measuring temperature. Therefore, at S608, the air volume reduction rate calculation section 203, in consideration of the measurement error _{T error} of temperature, is the minimum possible value of slope _{A i A i_min (A i_min =} (T i -T error - (T _{i-1 + T error))} / (Q i -Q i-1)) and the gradient is a maximum value _{of a i-1} is can take _{a i-1_max (a i-} 1_max = (T i-1 + T error - ( _{T i-1 -T error))} / (Q i-1 -Q i-2)) and calculates, in S609, by comparing the _{a i_min} and _{a i-1_max, a i_min} is _{a i When} it is determined that it is greater than _{−1_max,} it may be determined that a new heat sneak occurs between the air volume reduction rate Q _i−1 and the air volume reduction rate Q _i .

  In S603 and S606, the air volume reduction rate calculation unit 203 may acquire the intake air temperature after a predetermined time (for example, 10 minutes) has elapsed in order to acquire the steady-state intake air temperature. Good. In this case, instead of determining whether or not a predetermined time has elapsed, the intake air temperature is acquired at regular intervals, and whether the time change becomes a predetermined value or less (for example, the fluctuation is 0.2 ° C. or less in 5 minutes). By determining whether or not, it may be determined whether or not the change in the intake air temperature has been eliminated.

  In S603 and S606, the air volume reduction rate calculation unit 203 acquires the intake air temperature for each rack 110, and in S608, the air volume reduction rate calculation unit 203 calculates the inclination for each rack 110, and the process proceeds to S609. Then, the air volume reduction rate calculation unit 203 determines the occurrence of new heat sneaking for each rack 110, and if there is any rack 110 in which even one new heat sneaking occurs, the air volume reduction rate calculation unit 203 in S610. The air volume reduction rate that is optimal for reducing the air volume while avoiding the occurrence of new heat sneaking in the rack 110 may be determined.

  Here, S502 and S503 correspond to an air conditioner selection step, S603 and S606 correspond to an acquisition step, and S608 to S610 correspond to an air volume reduction rate determination step.

<Effect of Embodiment 1>
As described above, according to the first embodiment, by determining the air volume reduction rate before a new heat sneak occurs as the air volume reduction rate for operating the air conditioners 120, 121, 122, 123, It is possible to reduce the power consumption of the air conditioners 120, 121, 122, and 123 as much as possible while avoiding the occurrence of new heat wraparound.

  Further, by increasing the air volume reduction rate by a predetermined rate, the air volume of the cool air blown out by the air conditioners 120, 121, 122, 123 is adjusted so as to gradually decrease from the maximum air volume, thereby automatically reducing each air volume. Rate and inlet temperature can be collected.

  Further, it can be determined that a new heat wrap occurs between the air volume reduction rate before the intake air temperature becomes high and the air volume reduction rate where the intake air temperature becomes high.

  In addition, by adjusting the air volume in order from the air conditioners 120, 121, 122, 123 that are responsible for cooling the IT equipment with a small sum of hot air discharged to the hot aisle, the air conditioners 120 that have the capacity to suck in hot air It becomes possible to reduce that 121, 122, 123 draws air from other than hot aisle, and to reduce the air volume reduction rate as much as possible.

  In addition, after determining that the airflow in the server room 100 has changed, the air volume reduction rate can be determined again.

[Embodiment 2]
The second embodiment is different from the first embodiment in that the air volume reduction rate stored in the correlation information storage unit 1208 and the inlet temperature to the rack are acquired in advance, and the correlation between the acquired air volume reduction rate and the inlet air temperature is obtained. Based on the above, the air volume blown out by the air conditioner is adjusted. Hereinafter, the differences between the second embodiment and the first embodiment will be mainly described with reference to FIGS.

<System configuration>
FIG. 14 is a diagram illustrating an outline of a configuration example of an air conditioner control system according to the second embodiment of the present invention. 14, the air conditioner control system includes a server room 1100 and an air conditioner air volume optimization system 1200 connected to the server room 1100 via a network.

  The air conditioner air volume optimization system 1200 includes a server room configuration information update unit 1201, an air conditioner air volume adjustment unit 1202, an air volume reduction rate calculation unit 1203, a server room configuration information storage unit 1204, and a server room configuration information acquisition unit 1205. And an intake air temperature acquisition unit 1206, an air conditioner control unit 1207, and a correlation information storage unit 1208.

  The air volume reduction rate calculation unit 1203 correlates the server room configuration information, the acquired air volume reduction rate, and the inlet temperature to the rack in advance by using the server room monitoring function during operation before the air volume adjustment. The information is stored in the information storage unit 1208 (corresponding to a storage step). The air volume reduction rate calculation unit 1203 increases the air volume reduction rate by a predetermined rate by the air conditioner air volume adjustment unit 1202 as the air conditioner air volume adjustment unit 1202 sets the air conditioner air volume to a value that is gradually reduced. Each time, the air volume reduction rate and the acquired intake air temperature are associated with each other and stored in the correlation information storage unit 1208. Note that the air volume reduction rate calculation unit 1203 acquires the intake air temperature to all the racks 110 in the server room 1100, and associates the acquired air volume reduction rate with the intake air temperature to each rack to correlate information storage unit. You may make it memorize | store in 1208. FIG.

  Further, the air volume reduction rate calculation unit 1203 is based on the air volume reduction rate acquired from the correlation information storage unit 1208 and the inlet air temperature to the rack, and is optimal for reducing the air volume while avoiding the occurrence of new heat sneaking. Determine the reduction rate.

<Correlation information storage unit>
FIG. 15 is a diagram showing an outline of a configuration example of a table stored in the correlation information storage unit 1208 in the air conditioner control system according to Embodiment 2 of the present invention. In FIG. 15, the table stored in the correlation information storage unit 1208 has data items such as [server room configuration ID] [measurement point number], [air volume reduction rate (%)], and [intake air temperature (° C.)]. .

  [Server room configuration ID] indicates a symbol for identifying server room configuration information.

  [Measurement point number] indicates a number for identifying a measurement point. For example, the measurement points are plotted every 10% in order from the air volume reduction rate from 0%.

  [Air volume reduction rate] indicates an air volume reduction rate when the maximum air volume that can be blown out by the air conditioners 120, 121, 122, and 123 is 100%.

  [Intake air temperature] indicates an intake air temperature to the rack 110.

<Air volume reduction rate determination process>
FIG. 16 is a diagram illustrating an example in which air volume reduction rate determination processing is performed using data stored in a correlation information storage unit with matching server room configuration information in the air conditioner control system according to Embodiment 2 of the present invention. .

  First, in S1601, upon receiving input of server room configuration information from a server room configuration information input screen (not shown), the air volume reduction rate calculation unit 1203 uses the server room configuration information received as a key as a server room configuration information storage unit. By searching 1204, the corresponding server room configuration ID (that is, the server room configuration information that matches the key) is acquired. Thereafter, the air volume reduction rate calculation unit 1203 sets 2 to i which is a measurement point number.

  Next, in S1602, the air volume reduction rate calculation unit 1203 increments i that is a measurement point number.

Next, in S1603, the air volume reduction rate calculation unit 1203 searches the correlation information storage unit 1208 using the measurement point number i-2 and the server room configuration ID acquired in S1601 as keys, and the corresponding air volume. Q _i-2 that is the reduction rate and T _i-2 that is the inlet temperature are acquired. Further, the air volume reduction rate calculation unit 1203 searches the correlation information storage unit 1208 using the measurement point number i-1 as a key, and acquires the corresponding Q _i-1 and T _i-1 . Further, the air volume reduction rate calculation unit 1203 searches the correlation information storage unit 1208 using the measurement point number i and the server room configuration ID acquired in S1601 as keys, and acquires the corresponding Q _i and T _i. To do.

In step S < _b > 1604, the air volume reduction rate calculation unit 1203 determines the slope A _{i− of the} straight line connecting the coordinates (Q _i−2 , T _{i− 2} ) and the coordinates (Q _i−1 , T _i−1 ). ₁ is calculated. Further, the air volume reduction rate calculation unit 1203 calculates a slope A _{i of} a straight line connecting the coordinates (Q _i−1 , T _i−1 ) and the coordinates (Q _i , T _i ).

Next, in S1605, the wind reduction rate calculation section 1203, by comparing the _{A i} and _{A i-1,} determines whether _{A i} is greater than _{A i-1.} When the air volume reduction rate calculation unit 1203 determines that A _i is larger than A _i−1 (S1605—Yes), the air volume reduction rate calculation unit 1203 is Q _i− which is the air volume reduction rate of the measurement point i−1. _It is determined that a new heat sneak occurs between ₁ and Q _i that is the air volume reduction rate of the measurement point i. In step S <b> 1606, the air volume reduction rate calculation unit 1203 determines an optimal air volume reduction rate to reduce the air volume while avoiding the occurrence of new heat wrapping as Q _i−1 , and performs air volume reduction rate determination processing. finish. On the other hand, if the air volume reduction rate calculation unit 1203 determines that A _i is smaller than A _i−1 (S1605—No), the process proceeds to S1602.

  In step S1603, the air volume reduction rate calculation unit 1203 acquires the inlet temperature for each rack 110 from the correlation information storage unit 1208. In step S1604, the air volume reduction rate calculation unit 1203 calculates an inclination for each rack 110. In step S1605, the air volume reduction rate calculation unit 1203 determines whether a new heat sneak occurs for each rack 110. If there is any rack 110 in which even one new heat sneak occurs, the air volume reduction is performed in step S1606. The rate calculation unit 1203 may determine an optimum air volume reduction rate for reducing the air volume while avoiding the occurrence of new heat sneaking in the rack 110.

  Here, S1603 corresponds to an acquisition step, and S1604 to S1606 correspond to an air volume reduction rate determination step.

<Effect of Embodiment 2>
As described above, according to the second embodiment, the air volume reduction rate and the intake air temperature are associated with each other and stored in the correlation information storage unit 1208, thereby reducing the air volume as an effect different from the first embodiment. The air volume of the air conditioners 120, 121, 122, and 123 can be adjusted for the server room 1100 having the same configuration without separately acquiring the rate and the intake air temperature.

  As mentioned above, although the invention made | formed by this invention was concretely demonstrated based on embodiment, this invention is not limited to the said embodiment, It can change variously in the range which does not deviate from the summary. Needless to say.

100, 1100 Server room 110 Rack 111 Temperature measuring unit 120, 121, 122, 123 Air conditioner 130 IT equipment 140 Ventilation space 150 Grating 160 Cold air 170 Inlet port 180 Hot air 181 Heat recovery air flow 182 New heat sneak 190 Exhaust port 200, 1200 Air conditioner air volume optimization system 201, 1201 Server room configuration information update unit 202, 1202 Air conditioner air volume adjustment unit 203, 1203 Air volume reduction rate calculation unit 204, 1204 Server room configuration information storage unit 205, 1205 Server room configuration information acquisition unit 206, 1206 Inlet air temperature acquisition unit 207, 1207 Air conditioner control unit 220, 221, 222, 223, 224, 225, 226, 227 Rack row 511, 512 Measurement point 520, 521 Inclination 1208 Correlation information storage unit

Claims (13)

An air conditioner control system having a server room and an air conditioner air volume optimization system connected to the server room via a network,
The server room includes a rack, an IT device accommodated in the rack, and an air conditioner that blows out cold air that cools the IT device.
The air conditioner air volume optimization system acquires and acquires the air volume reduction rate of the cold air blown out by the air conditioner and the inlet air temperature to the rack when the air conditioner is operated at the air volume reduction rate. Based on the air volume reduction rate and the intake air temperature, it is determined whether or not a new heat sneak has occurred, and the air volume reduction rate before operating the air conditioner is determined based on the air volume reduction rate before the new heat sneak occurs. An air conditioner control system having an air volume reduction rate calculation unit determined as a rate. In the air conditioner control system according to claim 1,
The air conditioner air volume optimization system adjusts the air volume of the cool air blown out by the air conditioner so as to gradually decrease from a predetermined air volume by gradually increasing the air volume reduction rate. Further comprising
The air volume reduction rate calculation unit is an air conditioner control system that acquires the air volume reduction rate and the intake air temperature each time the air conditioner air volume adjustment unit adjusts the air volume. In the air conditioner control system according to claim 1,
A correlation information storage unit that stores the air volume reduction rate and the intake air temperature for each predetermined rate in association with each other;
The air volume reduction rate calculation unit is an air conditioner control system that acquires the air volume reduction rate and the intake air temperature from the correlation information storage unit. In the air-conditioner control system according to any one of claims 1 to 3,
The air volume reduction rate calculating unit determines that the new heat sneak occurs between the air volume reduction rate just before the intake air temperature becomes high and the air volume reduction rate where the intake air temperature becomes high. Control system. In the air conditioner control system according to claim 2,
The air conditioner is in charge of cooling the IT equipment housed in the rack constituting the rack row facing the hot aisle,
The air conditioner air volume adjustment unit determines an air volume reduction rate by the air volume reduction rate calculation unit in order from the air conditioner in charge of cooling the IT equipment with a small sum of hot air discharged to the hot aisle. Control system. In the air-conditioner control system according to any one of claims 1 to 5,
The air conditioner air volume optimization system further includes a server room configuration information update unit that determines that the airflow in the server room has changed when either the rack or the IT device is installed or removed,
The said air volume reduction rate calculation part is an air conditioner control system which determines the said air volume reduction rate, after the said server room structure information update part determines with the air flow in the said server room having changed. An air conditioner control method in an air conditioner control system having a server room and an air conditioner air volume optimization system connected to the server room via a network,
The air volume reduction rate calculation unit of the air conditioner air volume optimization system acquires the air volume reduction rate of the cool air blown out by the air conditioner and the inlet temperature to the rack when the air conditioner is operated at the air volume reduction rate. An acquisition step;
The air volume reduction rate calculation unit determines whether or not a new heat sneak occurs based on the acquired air volume reduction rate and the intake air temperature, and determines the air volume reduction rate just before the new heat sneak occurs. An air volume reduction rate determining step for determining the air volume reduction rate for operating the air conditioner;
An air conditioner control method comprising: In the air-conditioner control method according to claim 7,
In the obtaining step, the air volume adjustment unit of the air conditioner air volume optimization system increases the air volume reduction rate, thereby gradually decreasing the air volume of the cold air blown out by the air conditioner from a predetermined air volume. The air conditioner control method is performed every time adjustment is performed. In the air-conditioner control method according to claim 7,
The air volume reduction rate calculation unit further includes a storage step of storing the air volume reduction rate and the inlet temperature to the rack in association with each other in a correlation information storage unit,
The acquisition step is an air conditioner control method of acquiring the intake air temperature and the air volume reduction rate from the correlation information storage unit. In the air-conditioner control method as described in any one of Claims 7-9,
The air volume reduction rate determination step determines that the new heat sneak occurs between the air volume reduction rate before the intake air temperature increases and the air volume reduction rate at which the intake air temperature increases. Control method. In the air-conditioner control method according to claim 8,
The air conditioning apparatus further includes an air conditioner selection step in which the air conditioner air volume adjustment unit determines the air volume reduction rate in order from the air conditioner that is in charge of cooling the IT equipment in which the sum of the air volumes of hot air discharged to the hot aisle is small. Machine control method. In the air-conditioner control method as described in any one of Claims 7-11,
The air volume reduction rate determining step is an air conditioner control method performed after the server room configuration information update unit of the air conditioner air volume optimization system determines that the air flow in the server room has changed. An air conditioner air volume optimization program for causing a computer of an air conditioner control system having a server room and an air conditioner air volume optimization system connected to the server room via a network,
The air volume reduction rate calculation unit of the air conditioner air volume optimization system acquires the air volume reduction rate of the cool air blown out by the air conditioner and the inlet temperature to the rack when the air conditioner is operated at the air volume reduction rate. An acquisition step;
The air volume reduction rate calculation unit determines whether or not a new heat sneak occurs based on the acquired air volume reduction rate and the intake air temperature, and determines the air volume reduction rate just before the new heat sneak occurs. An air volume reduction rate determining step for determining the air volume reduction rate for operating the air conditioner;
An air conditioner air volume optimization program that causes the computer to execute.

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