JP7381299B2 - air conditioning system - Google Patents

Description

The present disclosure relates to an air conditioning system including a plurality of air conditioners.

For example, in the air conditioning system described in Patent Document 1, each air conditioner is controlled by associating one of the plurality of temperature sensors with one of the plurality of air conditioners.

Japanese Patent Application Publication No. 2011-64375

In the air conditioning system described in Patent Document 1, for example, when one of the air conditioners stops operating due to thermo-off or manual operation or failure, or the air conditioning capacity decreases, the necessary air conditioning capacity is not generated in the air conditioner. If there is no monitoring, the air conditioning area that the air conditioner is in charge of is effectively unmonitored. Note that the air-conditioned area refers to a space where the air temperature, etc. is monitored and adjusted by the air conditioner.

In view of the above points, the present disclosure discloses an example of an air conditioning system that can prevent any air conditioning area from becoming virtually unmonitored.

For example, it is desirable that an air conditioning system applied to a server room in which a plurality of information and communication technology devices () are installed include at least one of the following configuration requirements.
That is, a plurality of temperature sensors (S1 to S5) are installed at multiple locations in the server room (SR) to detect the air temperature of the server room (SR) at each location, and an air conditioner is installed in the server room (SR). A plurality of air conditioners (51 to 54) that supply wind, and the air conditioning capacity can be controlled using the temperature detected by at least one temperature sensor (S1 to S5) among the plurality of temperature sensors (S1 to S5). One of the detected temperatures (Td) detected by each of the plurality of air conditioners (51 to 54) and the plurality of temperature sensors (S1 to S5) is detected by any one of the plurality of air conditioners (51 to 54). A sensor usage determination unit (7) that can be used as a first function for determining the presence or absence of an abnormal air conditioner, and a state in which the detected temperature used by the abnormal air conditioner can also be used by the normal air conditioner. and a sensor usage determination unit (7) that can perform a second function.

Note that an abnormal air conditioner is one or more air conditioners that do not have the necessary air conditioning capacity among the plurality of air conditioners (51 to 54), and a normal air conditioner is one or more air conditioners that are not generating the necessary air conditioning capacity among the plurality of air conditioners (51 to 54). ) is one or more air conditioners other than the abnormal air conditioner.

As a result, in the relevant air conditioning system, if the necessary air conditioning capacity is not generated in the abnormal air conditioner, the air conditioning area handled by the abnormal air conditioner can be monitored and adjusted by the normal air conditioner. It can be a state.

Therefore, even if one of the air conditioners stops operating due to thermo-off or manual operation or failure, or the air conditioning capacity decreases, and the necessary air conditioning capacity is not generated in the air conditioner, This can prevent the air conditioning area that the air conditioner is in charge of from becoming virtually unmonitored.

Incidentally, the above-mentioned symbols in parentheses are an example showing the correspondence with the specific configurations described in the embodiments described later, and the present disclosure is not limited to the specific structures etc. shown in the above-mentioned parentheses. It's not something you can do.

FIG. 1 is a diagram showing an air conditioning system according to a first embodiment. FIG. 1 is a diagram showing an air conditioning system according to a first embodiment. FIG. 3 is a diagram showing association processing according to the first embodiment. FIG. 3 is a diagram illustrating a usage air conditioner determination process according to the first embodiment. It is a figure showing an air conditioning system concerning a 2nd embodiment.

The following "Embodiments of the Invention" represents an example of an embodiment that falls within the technical scope of the present disclosure. In other words, the matters specifying the invention described in the claims are not limited to the specific configurations and structures shown in the embodiments below.

At least one member or portion is provided with at least a reference numeral, unless otherwise specified such as "one". That is, if there is no indication such as "one", two or more members may be provided. The air conditioning system shown in the present disclosure includes at least components such as the referenced and described members or parts.

(First embodiment)
<1. Overview of air conditioning system>
In this embodiment, an example of the air conditioning system according to the present disclosure is applied to an air conditioning system applied to a server room. Inside the server room SR, a plurality of air conditioners 51 to 54 (see FIG. 1) and a plurality of racks 3A to 3D (see FIG. 2) are installed.

Each of the air conditioners 51 to 54 supplies conditioned air (in this embodiment, cold air) into the server room SR. Note that each of the plurality of air conditioners 51 to 54 supplies cold air into the server room SR from under the floor of the server room SR, as shown in FIG.

Each of the plurality of racks 3A to 3D is a shelf on which at least one information communication technology device (not shown) is mounted. That is, a plurality of information and communication technology devices (hereinafter referred to as ICT devices) are installed in the server room SR. Each ICT device has at least an information processing unit (for example, a CPU, a GPU, etc.) that executes information processing.

Each ICT device generates heat when performing information processing. Therefore, each of the air conditioners 51 to 54 supplies cold air into the server room SR in order to maintain the temperature of the ICT equipment (information processing unit) within a predetermined temperature range.

The plurality of racks 3A to 3D are arranged in a row to form a rack row. In this embodiment, as shown in FIG. 1, at least one (in this embodiment, a plurality of) rack rows R1 to R5 are configured in the server room SR.

Cold air is supplied to a space on one side of each of the rack rows R1 to R5 (hereinafter referred to as cold aisle Ci). The air whose temperature has increased by cooling each ICT device is discharged to the space on the other side of each rack row R1 to R5 (hereinafter referred to as hot aisle Hi).

Each cold aisle Ci and each hot aisle Hi are separated by a partition member (not shown). Therefore, the cold air supplied to each cold aisle Ci flows through any of the racks 3A to 3D and flows into any of the hot aisles Hi.

The air in each hot aisle Hi is sucked into one of the air conditioners 51 to 54 and cooled. In this embodiment, the air in each hot aisle Hi is sucked into one of the air conditioners 51 to 54 via the ceiling space of the server room SR.

<2. Air conditioning system details>
<2.1 Configuration and operation of each air conditioner>
<Configuration of each air conditioner>
As shown in FIG. 2, each air conditioner 51 to 54 includes at least a cooler 5A, a blower 5B, a control section 5C, and the like. The cooler 5A is a heat exchanger for cooling air. The blower 5B sucks air from inside the server room SR and supplies the air that has passed through the cooler 5A to the server room SR.

<Operation of each air conditioner>
The control unit 5C controls at least one of the cooling capacity generated by the cooler 5A and the amount of air blown by the blower 5B (hereinafter referred to as air conditioning capacity). The control unit 5C according to the present embodiment sets a target temperature (hereinafter referred to as set temperature) of the detected temperature of the temperature sensor associated with the control unit 5C among the plurality of temperature sensors S1 to S5 (see FIG. 1). The air conditioning capacity is changed and controlled so that

That is, as shown in FIG. 1, a plurality of temperature sensors S1 to S5 are arranged within the server room SR. Each of the temperature sensors S1 to S5 is provided at each of a plurality of locations within the server room SR, and detects the air temperature of the server room SR at the location.

In this embodiment, each of the plurality of temperature sensors S1 to S5 is arranged within one of the cold aisles Ci. That is, the set temperature according to this embodiment is the target "air temperature in cold aisle Ci."

The control unit 5C of each air conditioner 51 to 54 controls the air conditioning capacity using the temperature detected by the temperature sensor associated with the control unit 5C. Specifically, each of the air conditioners 51 to 54 changes and controls the air conditioning capacity so that the absolute value of the difference between the detected temperature and the set temperature becomes small.

That is, the temperature sensor S1 is associated with the control unit 5C of the air conditioner 51. The temperature sensor S2 is associated with the control unit 5C of the air conditioner 52. Temperature sensors S3 and S4 are associated with the control unit 5C of the air conditioner 53. The temperature sensor S5 is associated with the control unit 5C of the air conditioner 55.

For example, when the temperature detected by the temperature sensor S1 is higher than the set temperature, the control unit 5C of the air conditioner 51 makes the air conditioning capacity larger than the current air conditioning capacity. When the temperature detected by the temperature sensor S1 is lower than the set temperature, the control unit 5C of the air conditioner 51 makes the air conditioning capacity smaller than the current air conditioning capacity.

The operations of the other air conditioners 52 to 54 are also the same as that of the air conditioner 51. Note that the air conditioner 53 controls the air conditioning capacity using the larger of |detected temperature of temperature sensor S3−set temperature| and |detected temperature of temperature sensor S4−set temperature|.

The set temperature is a temperature predetermined for each of the temperature sensors S1 to S5, that is, for each of a plurality of locations in the server room SR. Therefore, each control unit 5C controls the air conditioning capacity using "(1) the set temperature Ts for the associated temperature sensor" and "(2) the detected temperature Td of the temperature sensor."

Hereinafter, the set temperature Ts for the temperature sensor Sn (where n = 1, 2, 3, 4, 5) will be referred to as set temperature Tsn (where n = 1, 2, 3, 4, 5). In addition, in the following explanation, all set temperatures Tsn are assumed to be the same from the viewpoint of easy understanding. Furthermore, the detected temperature Td of the temperature sensor Sn is written as the detected temperature Tdn (however, n=1, 2, 3, 4, 5), and the control unit of the air conditioner 5n (however, n=1, 2, 3, 4) 5C is referred to as a control unit 5Cn.

<2.2 Association change processing>
<Summary of association change processing>
In normal times, the association between one of the plurality of temperature sensors S1 to S5 and one of the plurality of air conditioners 51 to 54 is a predetermined correspondence, that is, the above-mentioned association. Then, the air conditioning system executes the association change process in an emergency.

Note that "normal time" refers to a state in which each air conditioner 5n is generating the necessary air conditioning capacity. The necessary air conditioning capacity refers to the air conditioning capacity required to bring the detected temperature Tdn close to the set temperature Tsn.

"Emergency" refers to a state in which, for example, one of the air conditioners 5n has stopped operating due to thermo-off, manual operation, or failure, or the air conditioning capacity has decreased, and the air conditioner does not have the necessary air conditioning capacity. means.

Hereinafter, one or more air conditioners among the plurality of air conditioners 5n that are not producing the necessary air conditioning capacity will be referred to as an abnormal air conditioner. One or more air conditioners other than the abnormal air conditioner among the plurality of air conditioners 5n are referred to as normal air conditioners.

In the association change process, the detected temperature Td (hereinafter referred to as abnormal temperature Te) used by the abnormal air conditioner becomes usable also by the normal air conditioner. Hereinafter, the normal air conditioner for which the abnormal temperature Te is available will be referred to as the utilized air conditioner.

That is, when an abnormal air conditioner occurs, the air conditioner in use can control the air conditioning capacity using |abnormal temperature Te - set temperature Ts|. Specifically, the control unit 5C controls the air conditioning capacity so that the larger one of the at least two temperature differences becomes smaller.

The first temperature difference among the two temperature differences is |abnormal temperature Te−set temperature Ts|. The second temperature difference among the two temperature differences is |detected temperature Td−set temperature Ts|. Note that the detected temperature Td is the detected temperature Td that the air conditioner in use normally uses.

Therefore, for example, when the air conditioner 51 becomes the abnormal air conditioner and the air conditioner 52 becomes the used air conditioner, the control unit 5C2 controls |detected temperature Td1 (abnormal temperature Te) - set temperature Ts1| and |detected temperature Td2 - The air conditioning capacity is controlled so that the temperature difference between the set temperatures Ts2|, whichever is larger, becomes smaller.

Note that the control unit 5C controls the air conditioning capacity so that the larger of the two temperature differences becomes smaller, so the air conditioning capacity is controlled so that the "second temperature difference" mentioned above becomes smaller. There may be cases where

However, in the air conditioning system according to the present embodiment, all set temperatures Ts are the same and the cold air supply from the abnormal air conditioner is stopped or reduced, so in many cases, the first temperature difference is the same as the first temperature difference. In many cases, the control unit 5C controls the air conditioning capacity so that the first temperature difference becomes smaller.

In the air conditioning system according to this embodiment, the association change process is executed by the integrated control unit 7. The integrated control unit 7 is composed of a microcomputer having ROM, RAM, CPU, and the like.

Note that a program for executing the association change process is stored in advance in a nonvolatile storage unit such as a flash memory provided in the integrated control unit 7. The integrated control unit 7 is input with at least signals indicating the detected temperature Tdn and the operating state of the air conditioner 5n. The integrated control unit 7 uses a signal indicating the operating state of the air conditioner 5n to determine whether it is a normal state or an emergency state.

<Details of association change processing>
When the integrated control unit 7 determines that at least one abnormal air conditioning has occurred and the air conditioning system is in an emergency state, it executes the association change process. That is, as shown in FIG. 3, after determining that there is an abnormal air conditioner, the integrated control unit 7 determines the air conditioner to be used (S3) when a predetermined time has elapsed (S1: YES). ). Note that (S1) and (S3) indicate the control step numbers shown in FIG.

In S3, if there is one normal air conditioner, the integrated control unit 7 sets that one normal air conditioner as the air conditioner to be used. If there are a plurality of normal air conditioners, the integrated control unit 7 executes a usage air conditioner determination process to determine one usage air conditioner.

If there are a plurality of abnormal air conditioners, the external control device 9 executes the association change process for each abnormal air conditioner. At this time, if one normal air conditioner is in a state where it uses multiple abnormal temperatures Te, the normal air conditioner will control its air conditioning capacity so that the largest "temperature difference from the set temperature" becomes small. do.

Note that, when an abnormal air conditioner occurs, the integrated control unit 7 notifies the administrator of the air conditioning system to that effect. Then, when the administrator inputs to the integrated control unit 7 that the abnormal air conditioner has disappeared, the integrated control unit 7 returns the air conditioning system to normal operation.

<Used air conditioner determination process>
The usage air conditioner determination process is a process for selecting the normal air conditioner that has a strong relationship with the air conditioning area (hereinafter referred to as the abnormal area) handled by the abnormal air conditioner from among the multiple normal air conditioners as the usage air conditioner. be.

That is, when an abnormal air conditioner occurs, the supply of conditioned air to the abnormal area is stopped or reduced, so that the air temperature in the abnormal area increases. When the air temperature in the abnormal area increases, there is a high possibility that the air temperature in the air conditioning area handled by the normal air conditioner (hereinafter referred to as the normal area) will also increase.

Then, when the detected temperature Td of the normal area rises, the normal air conditioner in charge of the normal area increases its air conditioning capacity in accordance with the rise of the detected temperature Td.
Therefore, after an abnormal air conditioner occurs, the integrated control unit 7 according to the present embodiment regards the normal air conditioner whose air conditioning capacity has increased the most as the most relevant normal air conditioner, and utilizes the normal air conditioner. Air conditioner.

Specifically, as shown in FIG. 4, after acquiring the amount of change of each normal air conditioner (S5), the integrated control unit 7 sets the related air conditioner with the largest amount of change as the air conditioner to be used (S7 ). Note that (S5) and (S7) indicate the control step numbers shown in FIG. 4.

In addition, related air conditioners refer to one or more normal air conditioners whose air conditioning capacity has changed beyond a predetermined range compared to before the abnormal air conditioner occurred. . The amount of change refers to the changed air conditioning capacity.

That is, the integrated control unit 7 determines the air conditioner to be used, using the amount of change as a parameter indicating the magnitude of the relationship. Note that the integrated control unit 7 according to the present embodiment grasps the air conditioning capacity using the temperature detected by the temperature sensor Sn.

Specifically, the integrated control unit 7 determines whether the temperature sensor Sn whose detected temperature Td has increased the most compared to before the occurrence of the abnormal air conditioner is the normal air conditioner (related air conditioner) associated with the normal air conditioner. Use air conditioner.

<3. Features of the air conditioning system according to this embodiment>
In the air conditioning system according to the present embodiment, when the necessary air conditioning capacity is not generated in the abnormal air conditioner, the air conditioning area handled by the abnormal air conditioner, that is, the abnormal area, is replaced by the normal air conditioner. It can become a state that can be monitored and adjusted.

Therefore, even if the necessary air conditioning capacity is not generated in the air conditioner due to the thermostat being turned off or the operation of the air conditioner being stopped manually or due to a failure, the abnormal area is effectively , it is possible to prevent the system from going into a non-monitoring state.

The air conditioning system according to this embodiment uses the amount of change in air conditioning capacity to determine which air conditioner to use. As a result, a normal air conditioner that has a large correlation with the abnormal area is set as the air conditioner to be used, so that the abnormal area can be effectively and appropriately monitored and adjusted.

The air conditioning system according to this embodiment determines which air conditioner to use when a predetermined time has elapsed after determining that there is an abnormal air conditioner. Thereby, a normal air conditioner that is highly relevant to the abnormal area can be reliably selected.

That is, immediately after an abnormal air conditioner occurs, it is highly likely that the detected temperature Td in the normal area does not change due to the influence of the abnormal area. However, if a predetermined period of time has elapsed after the occurrence of an abnormal air conditioner, it is highly likely that the detected temperature Td in the normal area has changed due to the influence of the abnormal area.

(Second embodiment)
The integrated control unit 7 according to the above-described embodiment grasped the air conditioning capacity using the detected temperatures Td of the temperature sensors S1 to S5. On the other hand, the integrated control unit 7 according to this embodiment grasps the air conditioning capacity using the temperature detected by the suction temperature sensor.

That is, as shown in FIG. 5, the air conditioning system includes a plurality of suction temperature sensors SSn (n=1, 2, 3, 4) that detect the temperature of the air sucked into each of the air conditioners 51 to 54. We are prepared.

The temperature detected by each suction temperature sensor SSn is input to the integrated control section 7. When an abnormal air conditioner occurs, the integrated control unit 7 regards the air conditioner associated with the suction temperature sensor SSn whose detected temperature has increased the most as a normal air conditioner that has a large correlation with the abnormal area. , the air conditioner in question is the air conditioner in use.

Note that the same constituent elements as in the above-described embodiment are given the same reference numerals as in the above-described embodiment. Therefore, in this embodiment, redundant explanations are omitted.
(Third embodiment)
The integrated control unit 7 according to the embodiment described above uses the amount of change in air conditioning capacity to determine which air conditioner to use. In contrast, the integrated control unit 7 according to the present embodiment determines the air conditioners to be used according to a predetermined correspondence relationship.

That is, the integrated control unit 7 or the non-volatile storage unit (not shown) stores in advance the correspondence between the abnormal air conditioners and the utilized air conditioners in case an abnormal air conditioner occurs. Then, the integrated control unit 7 determines the air conditioner to be used according to the stored correspondence relationship.

Note that the correspondence relationship is, for example, (a) when the air conditioner 51 becomes an abnormal air conditioner, the air conditioner 52 is the used air conditioner, (b) when the air conditioner 54 becomes an abnormal air conditioner, The main content is that the air conditioner 53 is used as the air conditioner.

(Fourth embodiment)
The integrated control unit 7 according to the embodiment described above uses the amount of change in air conditioning capacity to determine which air conditioner to use. In contrast, the integrated control unit 7 according to the present embodiment makes it possible to use the detected temperature that was used by the abnormal air conditioner in the normal air conditioner that is the shortest distance from the abnormal area.

That is, when the temperature sensor used by the abnormal air conditioner among the plurality of temperature sensors S1 to S5 is set as the abnormal sensor, it is possible for the integrated control unit 7 to grasp the distance from the abnormal sensor to the normal air conditioner. It is.

Then, the integrated control unit 7 makes it possible to use the temperature detected by the abnormal sensor in the normal air conditioner that is the shortest distance from the abnormal area. In addition, in this embodiment, the method of grasping the distance to the abnormal area is not limited.

Incidentally, if the distance between each temperature sensor S1 to S5 and each air conditioner 51 to 54 is stored in advance, the integrated control unit 7 uses the stored distance to determine the distance between the abnormal area and the temperature sensor S1 to S5. Understand distance.

Further, for example, if each temperature sensor S1 to S5 is provided with a wireless transmitter, the integrated control unit 7 can also use the wireless transmitter to grasp the distance to the abnormal area. .

(Other embodiments)
In the embodiment described above, the temperature Td detected by the abnormality sensor can be used as the detected temperature Td used for controlling the air conditioning capacity of the air conditioner used. However, the present disclosure is not limited thereto.

That is, the disclosure may be such that, for example, the integrated control unit 7 changes the set temperature Ts used to control the air conditioning capacity of the air conditioner in use, depending on the temperature Td detected by the abnormality sensor. In this case, it is desirable to change the set temperature Ts to a smaller value.

In the first and second embodiments, the related air conditioner with the largest change in air conditioning capacity is the used air conditioner. However, the present disclosure is not limited thereto. That is, in the disclosure, for example, a related air conditioner in which the amount of change in air conditioning capacity is larger than a predetermined value may be used as the used air conditioner. Note that in this case, there may be a case where a plurality of air conditioners are used.

The air conditioner according to the embodiment described above controls the air conditioning capacity using the larger value of |abnormal temperature Te−set temperature Ts| and |detected temperature Td−set temperature Ts|. However, the present disclosure is not limited thereto. That is, the disclosure may include, for example, a configuration in which the air conditioning capacity is controlled using the larger value of (abnormal temperature Te - set temperature Ts) and (detected temperature Td - set temperature Ts).

In the above-described embodiment, one abnormal air conditioner occurs. However, the application of the present disclosure is not limited thereto. That is, the disclosure is applicable even when a plurality of abnormal air conditioners occur. Note that when a plurality of abnormal air conditioners occur, it is desirable to have a configuration in which the detected temperature Td of the abnormal sensor with the largest temperature rise can be used.

In the embodiment described above, for example, the temperature sensor S1 is configured to include one temperature sensor and output one detected temperature. However, the present disclosure is not limited thereto.
That is, in the disclosure, for example, in the cold aisle Ci of the rack row R1, the temperature sensor S1 may be configured by a plurality of temperature sensors arranged at a plurality of locations. In this case, it is desirable to set the detected temperature of the temperature sensor with the highest temperature among the plurality of temperature sensors constituting the temperature sensor S1 as the detected temperature Td of the temperature sensor S1.

In the embodiment described above, all set temperatures Ts were the same. However, the application of the present disclosure is not limited thereto. That is, the disclosure is also applicable to an air conditioning system in which the set temperature Ts is different for each air conditioning area n (the range covered by the temperature sensor Sn).

The air conditioning system according to the embodiment described above was configured to include three or more air conditioners. However, the present disclosure is not limited thereto. That is, the disclosure is applicable to, for example, an air conditioning system that includes two air conditioners. Note that in this case, the process of determining the air conditioner to be used is substantially unnecessary.

In the air conditioning system according to the embodiment described above, the integrated control unit 7 executes the association change process and the usage air conditioner determination process. However, the present disclosure is not limited thereto. That is, the disclosure may be such that, for example, at least one of the association change process and the usage air conditioner determination process can be executed by any of the air conditioners 51 to 54.

The set temperature according to the above-described embodiment was the target "air temperature in cold aisle Ci." However, the present disclosure is not limited thereto. That is, the disclosure may be, for example, an air conditioning system in which the target "air temperature in hot aisle Hi" is the set temperature.

The integrated control unit 7 according to the second embodiment grasped the air conditioning capacity using the temperature detected by the suction temperature sensor. However, the present disclosure is not limited thereto. In other words, the disclosure discloses that, for example, the air conditioning capacity is determined by using the cooling capacity generated by the cooler 5A (for example, the number of rotations of the compressor) and the amount of air blown by the blower 5B (the number of rotations of the blower motor). You may.

Furthermore, the present disclosure is not limited to the above-described embodiments as long as it conforms to the spirit of the disclosure described in the above-described embodiments. Therefore, in a configuration in which at least two of the above-mentioned embodiments are combined, or in the above-mentioned embodiment, any of the illustrated structural features or the structural features described with reference numerals are abolished. It may be configured as follows.

51-54...Air conditioner 7...Integrated control unit S1-S5...Temperature sensor

Claims (4)

In an air conditioning system applied to a server room where multiple information and communication technology devices are installed,
a plurality of temperature sensors provided at each of a plurality of locations in the server room and detecting the air temperature of the server room at each location;
a plurality of air conditioners that supply conditioned air into the server room, the plurality of air conditioners capable of controlling air conditioning capacity using the temperature detected by at least one temperature sensor among the plurality of temperature sensors;
and a sensor usage determination unit that allows any one of the detected temperatures detected by each of the plurality of temperature sensors to be used by any one of the plurality of air conditioners,
Among the plurality of air conditioners, one or more air conditioners that are not generating the necessary air conditioning capacity is considered to be an abnormal air conditioner, and one or more air conditioners other than the abnormal air conditioner among the plurality of air conditioners is considered to be normal. When used as an air conditioner,
The sensor usage determination unit includes:
It is possible to perform the first function of determining the presence or absence of an abnormal air conditioner, and the second function of making the detected temperature used by the abnormal air conditioner usable also in the normal air conditioner .
A normal air conditioner that uses the detected temperature (hereinafter referred to as abnormal temperature) that was used by the abnormal air conditioner is used as the operating air conditioner, and the state in which each of the plurality of air conditioners is generating the necessary air conditioning capacity is called a normal state. When
For the air conditioner in use, "the temperature difference between the abnormal temperature and a predetermined temperature (hereinafter referred to as set temperature)" and "the temperature difference between the detected temperature and the set temperature that the said air conditioner normally uses" An air conditioning system that uses air conditioning to control air conditioning capacity . The related air conditioner is one or more normal air conditioners whose air conditioning capacity has changed beyond a predetermined range compared to before the abnormal air conditioner occurred, and the relevant air conditioner has changed. When the air conditioning capacity is the amount of change,
The air conditioning system according to claim 1, wherein if there are a plurality of related air conditioners when the second function is executed, the sensor usage determination unit is capable of determining the air conditioner to be used using the amount of change. . 3. The air conditioning system according to claim 2, wherein the sensor usage determination unit determines the associated air conditioner with the largest change as the usage air conditioner. 4. The air conditioning system according to claim 2, wherein the sensor usage determining unit determines which air conditioner to use when a predetermined time has elapsed after determining that there is an abnormal air conditioner.