JP2020134082A - Air conditioning system - Google Patents

Abstract

To disclose one example of an air conditioning system capable of suppressing an occurrence of a monitoring area in a non-monitoring state even in the case that an air conditioner becomes a stop state or that installation positions of air conditioners 5A to 5D are changed.SOLUTION: An air conditioning system associates a plurality of temperature sensors S1 to S17 with a plurality of air conditioners 5A to 5D by using position information of the respective temperature sensors S1 to S17 and position information of the respective air conditioners 5A to 5D. Consequently, appropriate association can be performed even in the case that any air conditioner becomes a stop state or that the installation positions of the air conditioners 5A to 5D are changed.SELECTED DRAWING: Figure 1

Description

The present disclosure relates to an air conditioning system.

For example, the air conditioning management system described in Patent Document 1 has the following configuration.
That is, the air conditioning management system includes a control controller, a plurality of temperature sensor terminals, and air conditioning equipment. The temperature sensor terminal acquires its own position information from the distance from other temperature sensor terminals, and transmits the acquired position information to the control controller. The control controller that has acquired the position information associates the temperature sensor terminal with the air conditioner. The control controller controls the air conditioner based on the associated information and the temperature information acquired from the temperature sensor terminal.

Japanese Unexamined Patent Publication No. 2011-64375

For example, when a plurality of temperature sensors are associated with one air conditioner, the air conditioner is in a thermo-off state and is virtually stopped, or due to a failure or the like. When the operation of the air conditioner is stopped, the monitoring areas of the plurality of temperature sensors associated with the air conditioner are in the non-monitoring state.

In view of the above points, the present disclosure is an example of an air conditioning system capable of suppressing the occurrence of a monitoring area in an unmonitored state when the air conditioner is stopped or the installation position of the air conditioner is changed. To disclose.

It is desirable that the air conditioning system includes, for example, at least one of the following constituent requirements. That is, the constituent requirements are a plurality of air conditioners (5A to 5D) for supplying air conditioning air, a plurality of air conditioners (5A to 5D) capable of transmitting a wireless signal, and a plurality of temperatures for detecting the air temperature. A plurality of temperature sensors (S1 to S17) which are sensors (S1 to S17) and capable of transmitting a wireless signal, a plurality of temperature sensors (S1 to S17), and a plurality of air conditioners (5A to 5D) each transmit. A position calculation unit (1, 53) and a position calculation unit (1, 53) that recognize the positions of a plurality of temperature sensors (S1 to S17) and the positions of a plurality of air conditioners (5A to 5D) using wireless signals. ) Is an association unit (1, 53) that associates each temperature sensor (S1 to S17) with each air conditioner (5A to 5D) by using the calculated position.

As a result, the association units (1, 53) of the air conditioning system utilize the position information of the plurality of temperature sensors (S1 to S17) and the position information of the plurality of air conditioners (5A to 5D) to each temperature sensor (S1). ~ S17) and each air conditioner (5A ~ 5D) are associated with each other.

On the other hand, in the air conditioning management system described in Patent Document 1, the air conditioner is stopped because the association is performed using only the position information of the temperature sensor without using the position information of the air conditioner. In this case, or when the installation position of the air conditioner is changed, it is not possible to make an appropriate association.

However, in the air conditioning system, each temperature sensor (S1 to S17) and each air conditioner (5A) are used by using the position information of the plurality of temperature sensors (S1 to S17) and the position information of the plurality of air conditioners (5A to 5D). Since it is associated with ~ 5D), even if the air conditioner is stopped or the installation position of the air conditioner is changed, an appropriate association is made without generating a monitoring area in an unmonitored state. Can be done.

Incidentally, the reference numerals in the parentheses are examples showing the correspondence with the specific configurations and the like described in the embodiments described later, and the present disclosure is limited to the specific configurations and the like shown in the symbols in the parentheses. It's not something.

It is a figure which shows the air-conditioning system which concerns on 1st Embodiment. It is a figure which shows the air-conditioning system which concerns on 1st Embodiment. It is a figure which shows the association process which concerns on 1st Embodiment. It is a figure which shows the air-conditioning system which concerns on 2nd Embodiment. It is a figure which shows the air-conditioning system which concerns on 2nd Embodiment.

The following "invention embodiment" shows an example of an embodiment belonging to the technical scope of the present disclosure. That is, the matters specifying the invention described in the claims are not limited to the specific configuration, structure, etc. shown in the following embodiments.

The arrows and the like indicating the directions attached to each figure are described in order to make it easier to understand the relationship between each figure. The invention presented in the present disclosure is not limited to the directions given in the drawings.

At least one member or part described with a reference numeral is provided unless otherwise specified such as "one". That is, if there is no notice such as "one", two or more of the members may be provided. The invention presented in the present disclosure comprises at least components such as members or sites described with reference numerals.

(First Embodiment)
1. 1. Outline of Air-Conditioning System In the present embodiment, an example of the air-conditioning system according to the present disclosure is applied to the air-conditioning system applied to the server room. A plurality of air conditioners 5A to 5D (see FIG. 1) and a plurality of racks 3A to 3D (see FIG. 2) are installed in the server room SR.

Each of the plurality of air conditioners 5A to 5D supplies air conditioning air (cold air in this embodiment) into the server room SR. As shown in FIG. 2, each of the plurality of air conditioners 5A to 5D supplies cold air into the server room SR from under the floor of the server room SR.

Each of the plurality of racks 3A to 3D is a shelf on which an ICT device (not shown) is mounted. The ICT device has at least an information processing unit (for example, a CPU, a GPU, etc.) that executes information processing.

The ICT device generates heat when performing information processing. Therefore, each of the air conditioners 5A to 5D supplies cold air into the server room SR in order to maintain the temperature of the ICT device (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 the present embodiment, as shown in FIG. 1, at least one (plurality in the present embodiment) rack rows R1 to R5 are configured in the server room SR.

Cold air is supplied to the space on one side of the rack rows R1 to R5 (hereinafter referred to as cold aisle Ci). The air that has cooled each ICT device and whose temperature has risen is discharged to the space on the other side (hereinafter, referred to as hot aisle Hi) across the rack rows R1 to R5.

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 each ICT device and flows into one of the hot aisle Hi.

The air in each hot aisle Hi is sucked into one of the air conditioners 5A to 5D and cooled. In the present embodiment, the air in each hot aisle Hi is sucked into one of the air conditioners 5A to 5D via the ceiling side space of the server room SR.

2. 2. Details of air conditioning system 2.1 Configuration and operation of each air conditioner <Configuration of each air conditioner>
Each of the plurality of air conditioners 5A to 5D has at least a cooler 51, a blower 52, a control unit 53, and the like, as shown in FIG. The cooler 51 is a heat exchanger for cooling air. The blower 52 sucks air from the server chamber SR and supplies the air that has passed through the cooler 51 to the server chamber SR.

<Operation of each air conditioner>
The control unit 53 controls at least one of the cooling capacity generated by the cooler 51 and the amount of air blown by the blower 52 (hereinafter, referred to as air conditioning capacity). The control unit 53 according to the present embodiment changes the set temperature so that the detection temperature of the temperature sensor associated with the control unit 53 among the plurality of temperature sensors S1 to S17 (see FIG. 1) becomes the target temperature. Control.

That is, as shown in FIG. 1, a plurality of temperature sensors S1 to S17 are arranged in the server room SR. Each temperature sensor S1 to S17 detects the air temperature in the server room SR. In this embodiment, the plurality of temperature sensors S1 to S17 are discretely arranged in any of the cold aisles Ci.

Then, the control unit 53 of each of the air conditioners 5A to 5D controls the air conditioning capacity by using the detection temperature of the temperature sensor associated with the control unit 53. Specifically, for example, when the temperature sensors S1 to S7 are associated with the control unit 53 of the air conditioner 5A, the temperature detected by the temperature sensors S1 to S7 is the target temperature of the control unit 53. The set temperature is changed and controlled so as to.

The “target temperature (hereinafter referred to as the target temperature)” is a specific temperature or a temperature range including the specific temperature. The "set temperature" is a temperature determined by the control unit 53 based on the target temperature, and is the temperature of the air sucked into the air conditioner provided with the control unit 53 or the temperature of the air supplied from the air conditioner. Is.

For example, when the detection temperature of the temperature sensors S1 to S7 is higher than the target temperature, the control unit 53 increases the air conditioning capacity by lowering the set temperature to the current set temperature. When the detection temperature of the temperature sensors S1 to S7 is lower than the target temperature, the control unit 53 reduces the air conditioning capacity by setting the set temperature higher than the current set temperature.

Hereinafter, "associating any one of the plurality of temperature sensors S1 to S17 with the control unit 53 provided in any of the plurality of air conditioners 5A to 5D" means "a plurality of the plurality of temperature sensors S1 to S17 and a plurality of them." Associate with any of the air conditioners 5A to 5D. "

2.2 Temperature sensor association <Outline of association>
The process for associating any of the plurality of temperature sensors S1 to S17 with any of the plurality of air conditioners 5A to 5D (hereinafter, referred to as an association process) is executed by the integrated control unit 1 shown in FIG.

In the association process according to the present embodiment, at least one of the cases where one temperature sensor is associated with one or two or more air conditioners and the case where one or two or more temperature sensors are associated with one air conditioner. Can occur.

Each temperature sensor S1 to S17 can transmit at least a radio signal indicating its own position information. As shown in FIG. 2, the transmitters 4A to 4C and the like that transmit the radio signal are provided, for example, in the ventilation passage under the floor. The signals indicating the detected temperatures detected by the temperature sensors S1 to S17 are transmitted to the associated air conditioner by wireless communication or wired communication using the transmitters 4A to 4C and the like.

Each of the air conditioners 5A to 5D can transmit at least a radio signal indicating its own position information. The transmitters 6A to 6D (see FIG. 1) that transmit the radio signal are provided, for example, in the ventilation passage under the floor.

Each air conditioner 5A to 5D has receivers 7A to 7D capable of receiving a radio signal transmitted from transmitters 4A to 4C and the like. Each control unit 53 can execute a position calculation function. The position calculation function utilizes radio signals transmitted by the plurality of temperature sensors S1 to S17 and the plurality of air conditioners 5A to 5D to position the plurality of temperature sensors S1 to S17 and the positions of the plurality of air conditioners 5A to 5D. It is a function to recognize.

Specifically, for example, the control unit 53 of the air conditioner 5A receives radio signals transmitted by the plurality of temperature sensors S1 to S17 and the other air conditioners 5B to 5D. Then, the control unit 53 calculates the horizontal distance and horizontal position from the air conditioner 5A to the temperature sensors S1 to S17, and the horizontal distance and horizontal position from the air conditioner 5A to the air conditioners 5B to 5D. ..

Similarly, for example, the control unit 53 of the air conditioner 5B receives radio signals transmitted by the plurality of temperature sensors S1 to S17 and the other air conditioners 5A, 5C, and 5D. Then, the control unit 53 determines the horizontal distance and horizontal position from the air conditioner 5B to the temperature sensors S1 to S17, and the horizontal distance and horizontal position from the air conditioner 5B to the air conditioners 5A, 5C, and 5D. Calculate.

The control unit 53 of the air conditioners 5C and 5D also executes the same position calculation function. Information having a horizontal distance and a horizontal position calculated by each of the air conditioners 5A to 5D (hereinafter referred to as position information) is transmitted to the integrated control unit 1 by wired transmission or wireless transmission.

The integrated control unit 1 calculates a control influence degree E using the received position information, and exerts a function of associating the temperature sensors S1 to S17 with the air conditioners 5A to 5D by using the control influence degree E. It is possible.

The control influence degree E is a parameter indicating the degree of change of the temperature sensors S1 to S17 with respect to the change of the air conditioning capacity generated by the air conditioners 5A to 5D. For example, when the change of each temperature sensor S1 to S17 with respect to the change of the air conditioning capacity is large, the parameter becomes a large value.

That is, the integrated control unit 1 recognizes the distance between the temperature sensors S1 to S17 and the air conditioners 5A to 5D by using the position information, and determines the control influence degree E by using the distance. The integrated control unit 1 according to the present embodiment uses the control influence degree E as a weight for associating any of the plurality of temperature sensors S1 to S17 with any of the plurality of air conditioners 5A to 5D.

For example, when the air conditioner 5A is associated with all of the temperature sensors S1 to S17, the air conditioner 5A is strongly influenced by the temperature sensor having the largest control influence E, and the temperature at which the control influence E is the smallest. The effect of the sensor is reduced.

The control influence degree E according to the present embodiment is, for example, a value determined by the following mathematical formula 1.
That is, one of the temperature sensors S1 to S17 is set to Si (i = 1 to 17 in the present embodiment), and any of the plurality of air conditioners 5A to 5D is set to the air conditioner 5j (in the present embodiment). j = A to D), the number of operating air conditioners is n (maximum 4 in this embodiment), and the distance between the temperature sensor Si and the air conditioner 5j is D (i, j).

The control influence degree E (i, j) of the air conditioner 5j on the temperature sensor Si is a value determined by the following mathematical formula 1.
E (i, j) = {AD (i, j)} / {A × (n-1)} ... Formula 1
A = D (i, A) + D (i, B) + D (i, C) + D (i, D)
However, A and n do not include air conditioners (hereinafter, also referred to as stop air conditioners) that do not exhibit the required air conditioning capacity.

Air conditioners that do not exhibit the required air conditioning capacity include, for example, "air conditioners that are in a thermo-off state and are virtually stopped" or "air conditioners that are stopped due to a failure, etc." Say. An operating air conditioner is an air conditioner other than a failed air conditioner.

Therefore, the integrated control unit 1 according to the present embodiment has the temperature sensors S1 to S17 and the air conditioners 5A to 5A so that the temperature sensor having the shortest distance D among the plurality of temperature sensors has a great influence on the air conditioning capacity. Associate with 5D.

<Details of association processing>
The association process shown in FIG. 3 is realized by the cooperation between each control unit 53 and the integrated control unit 1. The association process is automatically executed when manually instructed by the administrator or periodically.

The integrated control unit 1 and each control unit 53 are composed of a computer having at least a CPU, a ROM, a RAM, and the like, and execute an association process according to a program stored in advance in a non-volatile storage unit such as the ROM.

When the association process is started by the integrated control unit 1, the integrated control unit 1 has a control influence degree E stored in a non-volatile storage unit (not shown) such as a ROM, as shown in FIG. It is determined whether or not (i, j) is the initial setting value (S1). In addition, S1 and the like in parentheses are the reference numerals shown in FIG.

When the integrated control unit 1 determines that it is the initial setting value (S1: NO), the integrated control unit 1 executes S9. When the integrated control unit 1 determines that the value is not the initial setting value (S1: YES), the integrated control unit 1 acquires the distance between each of the plurality of temperature sensors S1 to S17 and the air conditioners 5A to 5D, that is, the position information (S3). ).

Next, the integrated control unit 1 determines whether or not the acquired position information has changed beyond a predetermined value with respect to the previously acquired position information (S5). When the integrated control unit 1 determines that the change has occurred in S5 (S5: NO), the integrated control unit 1 executes S9.

When the integrated control unit 1 determines that the change has not occurred in S5 (S5: YES), the integrated control unit 1 is an air conditioner in which the required air conditioning capacity is not exhibited among the plurality of air conditioners 5A to 5D, that is, a stop air conditioner. It is determined whether or not there is (S7).

When the integrated control unit 1 determines that there is no stop air conditioner (S7: NO), the integrated control unit 1 ends the association process. In other words, when the integrated control unit 1 determines that there is no stop air conditioner (S7: NO), it uses the current association and does not update the association.

When the integrated control unit 1 determines that the stop air conditioner is present (S7: YES), the integrated control unit 1 executes a process for updating the association. Specifically, the integrated control unit 1 acquires the number n of air conditioners other than the stop air conditioner, that is, the operating air conditioner (S9).

Next, the integrated control unit 1 acquires the distance D (i, j) for the number n of the operating air conditioners (S11), calculates the control influence degree E (i, j), and then performs a plurality of temperature sensors. Any one of S1 to S17 is associated with any of the plurality of air conditioners 5A to 5D (S13).

3. 3. Features of the air conditioning system according to the present embodiment The association processing of the air conditioning system according to the present embodiment uses the position information of the plurality of temperature sensors S1 to S17 and the position information of the plurality of air conditioners 5A to 5D to each temperature sensor S1. ~ S17 is associated with each of the air conditioners 5A to 5D.

Therefore, in the air conditioning system according to the present embodiment, even if any of the air conditioners is stopped or the installation positions of the air conditioners 5A to 5D are changed, the monitoring area in the non-monitoring state. Can be made to be properly associated without the occurrence of.

In the association process, the temperature sensors S1 to S17 are associated with the air conditioners 5A to 5D by using the control influence degree E (i, j). Thereby, each temperature sensor S1 to S17 can be appropriately associated with each air conditioner 5A to 5D.

The association process associates the temperature sensors S1 to S17 with the air conditioners 5A to 5D when it is determined that there is a stop air conditioner. As a result, it is possible to prevent unnecessary association processing from being executed.

The association process associates the temperature sensors S1 to S17 with the air conditioners 5A to 5D when it is determined that the acquired position information has changed beyond a predetermined value with respect to the previously acquired position information. .. As a result, it is possible to prevent unnecessary association processing from being executed.

(Second Embodiment)
The transmitters 4A to 4C, the transmitters 6A to 6D, and the receivers 7A to 7D according to the above-described embodiment are provided in the ventilation passage provided under the floor. On the other hand, the transmitters 4A to 4C, the transmitters 6A to 6D, and the receivers 7A to 7D according to the present embodiment are provided in a space other than the underfloor ventilation passage.

Specifically, FIG. 4 shows an example in which transmitters 4A to 4C, transmitters 6A to 6D, and receivers 7A to 7D are provided in the server room SR. In FIG. 4, the transmitters 4A to 4C are arranged in racks 3A to 3D and the like, and the transmitters 6A to 6D and the receivers 7A to 7D are arranged in air conditioners 5A to 5D.

FIG. 5 shows an example in which transmitters 4A to 4C, transmitters 6A to 6D, and receivers 7A to 7D are provided in the ceiling space of the server room. The same configuration requirements and the like as those in the above-described embodiment are designated by the same reference numerals as those in the above-described embodiment. Therefore, in the present embodiment, the duplicate description is omitted.

(Third Embodiment)
In the association processing according to the above-described embodiment, the value of the control influence degree E (i, j) was used as the weighting. On the other hand, in the association process according to the present embodiment, the operating air conditioner 5j is associated with the temperature sensor having the largest control influence degree E (i, j) among the plurality of temperature sensors S1 to S17.

(Fourth Embodiment)
In the association processing according to the present embodiment, the reciprocal of the distance D (i, j) is used as the control influence degree E (i, j). Then, the operating air conditioner 5j is associated with the temperature sensor having the largest control influence degree E (i, j) among the plurality of temperature sensors S1 to S17.

(Other embodiments)
The above-described embodiment was an air conditioning system applied to the server room SR. However, the disclosure according to the present specification is not limited thereto. That is, the disclosure may be, for example, a normal cooling air-conditioning system such as a building air-conditioning system or a heating air-conditioning system.

The control influence degree E (i, j) according to the above-described embodiment was a value obtained by Equation 1. However, the disclosure according to the present specification is not limited thereto. That is, the disclosure may be, for example, a value obtained by a definition other than Equation 1, as shown in the fourth embodiment.

The temperature sensors S1 to S17 and the air conditioners 5A to 5D according to the above-described embodiment have separate transmitters and receivers. However, the disclosure according to the present specification is not limited thereto. That is, the disclosure may be, for example, an air conditioning system using temperature sensors S1 to S17 with an integrated transmitter or receiver, or air conditioners 5A to 5D with an integrated transmitter or receiver. ..

In the air conditioning system according to the above-described embodiment, the temperature sensors S1 to S17 and the air conditioners 5A to 5D are associated with each other by utilizing the control influence degree E (i, j). However, the disclosure according to the present specification is not limited thereto.

In the air conditioning system according to the above-described embodiment, the position calculation function is executed by the control unit 53. However, the disclosure according to the present specification is not limited thereto. That is, the disclosure may be configured such that the position calculation function is executed by the integrated control unit 1, for example.

In the air conditioning system according to the above-described embodiment, the integrated control unit 1 executes the association process. However, the disclosure according to the present specification is not limited thereto. That is, the disclosure may be configured such that the association process is executed by the control unit 53, for example.

In the association process according to the above-described embodiment, the operation determination (S7), the position determination (S5), and the determination of whether or not the control influence degree is the initial setting value (S1) are executed. However, the disclosure according to the present specification is not limited thereto. That is, the disclosure may be, for example, an association process in which at least one control step of S7, S5 and S1 is abolished.

Furthermore, the present disclosure is not limited to the above-described embodiment as long as it conforms to the gist of the invention described in the above-described embodiment. Therefore, either the configuration in which at least two embodiments of the plurality of embodiments described above are combined, or the configuration requirements shown in the illustration or the configuration requirements described with reference numerals in the above-described embodiment are abolished. It may be a configured configuration.

1 ... Integrated control unit 4A to 4C ... Transmitter 5A to 5D ... Air conditioner 6A to 6D ... Transmitter 7A to 7D ... Receiver 51 ... Cooler 52 ... Blower 53 ... Control unit SR ... Server room S1 to S17 ... Temperature sensor

Claims (6)

Multiple air conditioners that supply air conditioning air, and multiple air conditioners that can transmit wireless signals,
Multiple temperature sensors that detect the air temperature, and multiple temperature sensors that can transmit wireless signals,
A position calculation unit that recognizes the positions of the plurality of temperature sensors and the positions of the plurality of air conditioners by using radio signals transmitted by the plurality of temperature sensors and the plurality of air conditioners.
An air conditioning system including an association unit that associates each temperature sensor with each air conditioner by using the position calculated by the position calculation unit. The associating unit can calculate the control influence degree by using the recognized position, and can exert the function of associating each temperature sensor with each air conditioner by using the control influence degree.
The air conditioning system according to claim 1, wherein the control influence degree indicates the degree of change of each temperature sensor with respect to the change of the air conditioning capacity generated by each air conditioner. The air conditioning system according to claim 2, wherein the association unit calculates the distance between each temperature sensor and each air conditioner using the recognized position, and determines the degree of control influence using the distance. It is equipped with an operation judgment unit that determines whether or not there is an air conditioner that does not exhibit the required air conditioning capacity among the plurality of air conditioners.
The association unit is any one of claims 1 to 3 that associates each temperature sensor with each air conditioner when it is determined by the operation determination unit that there is an air conditioner that does not exhibit the required air conditioning capacity. The air conditioning system described in. It is provided with a position determination unit that determines whether or not the position calculated by the position calculation unit has changed beyond a predetermined value with respect to the position calculated last time.
The air conditioning system according to any one of claims 1 to 4, wherein the association unit associates each temperature sensor with each air conditioner when it is determined that the association unit has changed at least by the position determination unit. With multiple air conditioners that supply air conditioning air,
Multiple temperature sensors that detect the air temperature, and multiple temperature sensors that can transmit wireless signals,
A distance calculation unit that calculates the distance between each temperature sensor and each air conditioner using radio signals transmitted by each of the plurality of temperature sensors.
An air conditioning system including an association unit that associates each temperature sensor with each air conditioner so that the distance calculated by the distance calculation unit is the shortest.

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