JP7241524B2 - HVAC SYSTEM, HVAC EQUIPMENT, MANAGEMENT SERVER AND HVAC CONTROL ALGORITHM UPDATE METHOD - Google Patents

Description

The present invention relates to an air-conditioning system, air-conditioning equipment, a management server, and an air-conditioning control algorithm update method that perform air-conditioning control by executing an air-conditioning control algorithm.

Conventionally, some air conditioners perform air conditioning control using a control program acquired from an external device. Patent Literature 1 discloses a technique in which an air conditioner acquires a control program created based on information provided by a user and performs air conditioning control. The air conditioner described in Patent Literature 1 can perform air conditioning control suitable for the actual use environment by using a control program created based on information provided by the user.

JP-A-2002-22248

However, according to the conventional technology described above, the user inputs information about the usage environment, such as the size of the room, and transmits the information to the server device, and the maintenance personnel who operates the server device receives the information based on the information provided by the user. Therefore, a control program optimized for the air conditioner must be created. Therefore, there is a problem that it takes time to update the control program of the air conditioner.

SUMMARY OF THE INVENTION It is an object of the present invention to provide an air conditioning system capable of automatically updating an air conditioning control algorithm used in an air conditioner using information collected by the air conditioner.

In order to solve the above-described problems and achieve the object, an air conditioning system according to the present invention provides an air conditioner that transmits control information including measured values of specified measurement items, and control information acquired from the air conditioner. a management server that selects a first air-conditioning control algorithm to be used in the air-conditioning equipment using the air-conditioning equipment, and transmits the first air-conditioning control algorithm to the air-conditioning equipment. The air-conditioning equipment includes a storage unit that holds a second air-conditioning control algorithm used when performing air-conditioning control, and stores the second air-conditioning control algorithm held in the storage unit with the first air-conditioning control algorithm acquired from the management server. When updating the control algorithm and executing a plurality of second air conditioning control algorithms for trial operation, after executing one second air conditioning control algorithm for trial operation, the second air conditioning control algorithm for trial operation to be executed next requests the management server for the first air-conditioning control algorithm for trial operation corresponding to .

ADVANTAGE OF THE INVENTION According to this invention, an air-conditioning system is effective in the ability to automatically update the air-conditioning control algorithm used by an air-conditioner using the information collected by the air-conditioner.

1 is a diagram showing a configuration example of an air conditioning system according to Embodiment 1. FIG. 1 is a flow chart showing operations in an air conditioning system according to Embodiment 1, from when air conditioning equipment transmits control information collected during trial operation to a management server, to obtaining from the management server an air conditioning control algorithm to be used for normal operation. 4 is a flowchart showing analysis processing of the selection unit of the management server according to the first embodiment; Flowchart showing normal operation of the air conditioner according to Embodiment 1 4 is a flowchart showing operations of the air conditioner and the management server when the air conditioner according to Embodiment 1 performs normal air conditioning operation; FIG. 2 is a diagram showing an example of a hardware configuration included in each device of the air conditioning system according to Embodiment 1; FIG.

An air-conditioning system, air-conditioning equipment, a management server, and an air-conditioning control algorithm updating method according to embodiments of the present invention will be described below in detail with reference to the drawings. In addition, this invention is not limited by this embodiment.

Embodiment 1.
FIG. 1 is a diagram showing a configuration example of an air conditioning system 100 according to Embodiment 1 of the present invention. The air conditioning system 100 includes air conditioning equipment 110 , a management server 120 and an external device 130 . In the air conditioning system 100, each of the air conditioning equipment 110, the management server 120, and the external device 130 may be called an apparatus.

In the air-conditioning system 100 shown in FIG. 1, the air-conditioning equipment 110 communicates with the external device 130, and device information 134A including measured values obtained from the external device 130 by the measuring unit 133 provided in the external device 130. to get The air conditioner 110 updates the control information 113C held in the storage unit 113 using the obtained device information 134A as part of the control information 113C. The air conditioner 110 transmits to the management server 120 control information 113</b>C including measured values for prescribed measurement items to be measured by the air conditioner 110 or the external device 130 . Prescribed measurement items are measurement items for obtaining measurement values necessary for estimation processing when the management server 120 selects an air conditioning control algorithm to be used in the air conditioner 110 . The air conditioning equipment 110 includes a storage unit 113 that stores an air conditioning control algorithm 113B that is used when performing air conditioning control. Update. That is, the air conditioner 110 replaces the air conditioning control algorithm 113</b>B held in the storage unit 113 with the air conditioning control algorithm acquired from the management server 120 . The air conditioner 110 can automatically acquire and update the air conditioning control algorithm. The air conditioner 110 is, for example, an air conditioner. The air conditioner 110 uses the air conditioning control algorithm 113B held in the storage unit 113 to carry out air conditioning control.

Management server 120 communicates with air conditioner 110 and acquires control information 113C from air conditioner 110 . Management server 120 selects an air-conditioning control algorithm to be used in air-conditioning equipment 110 using control information 113</b>C acquired from air-conditioning equipment 110 and transmits the selected air-conditioning control algorithm to air-conditioning equipment 110 . Specifically, in the management server 120, the selection unit 122 uses the control information 113C to estimate the use environment of the air conditioner 110, the condition of the space to be air-conditioned by the air conditioner 110, and the like. The selection unit 122 selects an air conditioning control algorithm for the air conditioning equipment 110 that matches the estimation result. The communication unit 121 transmits the air conditioning control algorithm selected by the selection unit 122 to the air conditioner 110 . The management server 120 is, for example, a server provided in the cloud. In the following description, the air conditioning control algorithm 123A selected by the management server 120 and transmitted to the air conditioning equipment 110 is referred to as a first air conditioning control algorithm, and the air conditioning control algorithm 113B used when the air conditioning equipment 110 performs air conditioning control is referred to as This is sometimes referred to as a second air conditioning control algorithm.

External device 130 is an external apparatus connected to air conditioner 110 . The external device 130 includes a measurement unit 133 and transmits measurement values measured by the measurement unit 133 to the air conditioner 110 . Although the number of external devices 130 is one in the air conditioning system 100 shown in FIG. 1, this is an example, and the number of external devices 130 may be zero or two or more. The external device 130 is, for example, a device having functions such as a temperature sensor, a human sensor, and an illuminance sensor.

A configuration of the air conditioner 110 will be described. The air conditioner 110 includes a communication unit 111 , a data update unit 112 , a storage unit 113 , an air conditioning control unit 114 , a measurement unit 115 and an input unit 116 .

The communication unit 111 communicates with the management server 120 and the external device 130 using a communication method such as the Internet or Bluetooth (registered trademark). The communication unit 111 may communicate with the management server 120 and the external device 130 using a different communication method from each device.

The data update unit 112 updates each data held in the storage unit 113 with the information acquired by the communication unit 111 and the information acquired by the air conditioning control unit 114 .

Storage unit 113 holds data such as air conditioner basic information 113A, air conditioning control algorithm 113B, and control information 113C. The air conditioning equipment basic information 113A is information necessary for installing the air conditioning equipment 110, and includes, for example, the model name and the configuration of the air conditioning system 100 at the time of installation. The configuration of the air conditioning system 100 when installed includes the number of indoor units 114A and the number of outdoor units 114B installed. The air-conditioning control algorithm 113B is information necessary for realizing air-conditioning control, and is, for example, a program for operating the indoor unit 114A and the outdoor unit 114B. The control information 113C is information used by the management server 120 to select the air-conditioning control algorithm 113B used by the air-conditioning equipment 110, and is, for example, power consumption, indoor/outdoor temperature, and the like. Device information 134A acquired by communication unit 111 from external device 130 is included in control information 113C.

The air-conditioning control unit 114 executes the air-conditioning control algorithm 113B stored in the storage unit 113, operates the indoor unit 114A and the outdoor unit 114B, and performs air-conditioning control. The number of the indoor units 114A and the outdoor units 114B whose operations are controlled by the air conditioning control unit 114 is not limited to one, and may be plural. The air-conditioning control unit 114 can measure the amount of power used during air-conditioning control, that is, the amount of power used. Note that the air conditioner 110 does not have a configuration independent of the indoor unit 114A, the outdoor unit 114B, etc., but the communication unit 111, the data update unit 112, the storage unit 113, the air conditioning control unit 114, the measurement unit 115, and the input unit 116. Each configuration may be configured to be accommodated in the indoor unit 114A or the outdoor unit 114B. Regarding the air conditioner 110, an indoor unit 114A and an outdoor unit 114B are provided outside, and the communication unit 111, the data update unit 112, the storage unit 113, the air conditioning control unit 114, the measurement unit 115, and the input unit 116 are integrated into one device. may constitute

The measurement unit 115 performs various measurements. The air conditioner 110 shown in FIG. 1 has one measuring unit 115, but this is an example, and the number of measuring units 115 may be two or more. If one or more external devices 130 are connected to the air conditioner 110, the number of measurement units 115 may be zero. The measurement unit 115 includes, for example, a temperature sensor that measures the indoor temperature, a temperature sensor that measures the outdoor temperature, a motion sensor that detects the number of users in the room, and an illuminance sensor that detects the brightness of the room. but not limited to these. The measurement unit 115 measures specified measurement items and outputs the measured values.

Input unit 116 receives an operation from the user. The input unit 116 is, for example, a switch capable of receiving various operations. Note that the air conditioner 110 may be configured without the input unit 116 if it is possible to receive a user's operation from a remote controller (hereinafter referred to as a remote controller), not shown, via the communication unit 111 .

Next, the configuration of the management server 120 will be explained. The management server 120 includes a communication section 121 , a selection section 122 and a storage section 123 .

The communication unit 121 communicates with the air conditioner 110 by a communication method such as the Internet, for example.

The selection unit 122 uses the control information 113C acquired from the air conditioner 110 to select the air conditioning control algorithm used in the air conditioner 110 from the storage unit 123, that is, from among the plurality of air conditioning control algorithms held in the storage unit 123. Choose an algorithm.

The storage unit 123 holds a plurality of air conditioning control algorithms, air conditioning control algorithms 123A to 123N in the example of FIG. The air-conditioning control algorithms 123A to 123N are programs or the like that can be used when the air-conditioning equipment 110 performs air-conditioning control.

Next, the configuration of the external device 130 will be described. The external device 130 includes a communication section 131 , a device control section 132 , a measurement section 133 and a storage section 134 .

The communication unit 131 communicates with the air conditioner 110 using a communication method such as the Internet or Bluetooth.

The device control unit 132 executes a device control algorithm 134B held in the storage unit 134 and controls operations of the measuring unit 133 and the like. The device control unit 132 also writes and reads device information 134A held in the storage unit 134 .

The measurement unit 133 is a function of the external device 130 and performs various measurements. Although the external device 130 shown in FIG. 1 has one measuring unit 133, this is an example, and the number of measuring units 133 may be two or more. The measurement unit 133 includes, for example, a temperature sensor that measures the indoor temperature, a temperature sensor that measures the outdoor temperature, a motion sensor that detects the number of users in the room, and an illuminance sensor that detects the brightness of the room. but not limited to these. The measurement unit 133 measures prescribed measurement items and outputs the measured values.

Storage unit 134 holds data such as device information 134A and device control algorithm 134B. The device information 134A is information that can be acquired by the external device 130, such as a measured value measured by the measuring unit 133, for example. The device control algorithm 134B is information necessary to control the external device 130, and is, for example, a program for executing measurement in the measurement unit 133. FIG.

Next, in the air conditioning system 100, the operation of updating the air conditioning control algorithm 113B used when the air conditioning equipment 110 performs air conditioning control will be described.

First, the operation of performing a test run of the air conditioner 110 to acquire and update the air conditioning control algorithm 113B will be described. FIG. 2 shows the process from the transmission of control information 113C collected by air-conditioning equipment 110 during trial operation to management server 120 in air-conditioning system 100 according to Embodiment 1 to acquisition of an air-conditioning control algorithm to be used for normal operation from management server 120. It is a flow chart which shows operation.

After the air conditioner 110 is installed, the air conditioner 110 receives an instruction from the user to start the test operation of the air conditioner 110 (step S101). For example, the user instructs the air conditioner 110 to start the test operation via the input unit 116 of the air conditioner 110 or using the above-described remote controller.

In the air conditioner 110, the data updating unit 112 updates the control information 113C held in the storage unit 113 (step S102). Specifically, the data update unit 112 updates the information of the operation mode included in the control information 113C to "test run". Note that the control information 113C only needs to hold that the operation mode of the air conditioner 110 is the test operation, so the specific update method of the operation mode information is not limited.

In the air conditioner 110, the communication unit 111 transmits the control information 113C to the management server 120 (step S103). The control information 113C includes information indicating that the operation mode is test operation. Note that the control information 113C does not need to include the measured value measured by the measuring unit 115 of the air conditioner 110 and the measured value measured by the measuring unit 133 of the external device 130, that is, the device information 134A.

In the management server 120, the selection unit 122 acquires the control information 113C from the air conditioner 110 via the communication unit 121 and analyzes the control information 113C (step S104).

Analysis processing of the selection unit 122 of the management server 120 will be described in detail. FIG. 3 is a flow chart showing analysis processing of the selection unit 122 of the management server 120 according to the first embodiment. The selection unit 122 determines whether or not the current operation mode of the air conditioner 110 included in the control information 113C is test operation (step S201). When the current operation mode of the air conditioner 110 is test operation (step S201: Yes), the selection unit 122 determines whether or not the control information 113C acquired from the air conditioner 110 includes a measured value (step S202). . When the control information 113C does not include the measured value (step S202: No), the selection unit 122 selects an air-conditioning control algorithm for trial operation used in the air conditioner 110 from the storage unit 123 (step S203). The air-conditioning control algorithm for trial operation is an air-conditioning control algorithm preset to be performed by the air conditioner 110 during trial operation. The air-conditioning control algorithm for trial operation may be shared with the air-conditioning control algorithm used during normal operation of the air conditioner 110, or may be an air-conditioning control algorithm dedicated to trial operation. Also, the air-conditioning control algorithm for trial operation may be composed of a plurality of air-conditioning control algorithms, or may be composed of one air-conditioning control algorithm.

Returning to the description of the flowchart in FIG. In the management server 120, the communication unit 121 transmits the air conditioning control algorithm for trial operation selected by the selection unit 122 to the air conditioner 110 (step S105).

In the air conditioner 110, the communication unit 111 acquires from the management server 120 the air conditioning control algorithm selected by the management server 120 using the control information 113C. The data update unit 112 updates the air conditioning control algorithm 113B held in the storage unit 113 with the air conditioning control algorithm acquired from the management server 120 via the communication unit 111 (step S106).

In the air conditioner 110, the air conditioning control unit 114 executes the air conditioning control algorithm 113B held in the storage unit 113 to perform a test run (step S107). The air-conditioning control unit 114 performs control such as, for example, performing air-conditioning control for a certain period of time, or performing air-conditioning control until the space subject to air-conditioning control reaches a specified state, according to the air-conditioning control algorithm used in the test run. I do.

In the air conditioner 110, the air conditioning control unit 114 determines whether or not to end the test run (step S108). For example, if there are a plurality of air conditioning control algorithms for trial operation, and there is an air conditioning control algorithm for trial operation that has not been executed, the air conditioning control unit 114 determines not to end the trial operation (step S108: No), and step S107. to continue the test run. Note that when the air conditioning control unit 114 does not collectively acquire a plurality of air conditioning control algorithms for trial operation from the management server 120 but acquires them in multiple batches, after performing one air conditioning control algorithm for trial operation, The control server 120 may be requested to obtain an air-conditioning control algorithm for trial operation to be performed next.

The air-conditioning control unit 114 determines to end the test operation when there is no test-run air-conditioning control algorithm that has not been executed among the plurality of test-run air-conditioning control algorithms (step S108: Yes), and proceeds to step S109. It is assumed that the air conditioning controller 114 of the air conditioner 110 measures the amount of electric power used and the measurement unit 115 measures the indoor temperature, the outdoor temperature, and the like during the test run. It is also assumed that the communication unit 111 of the air conditioner 110 acquires the device information 134A including the measured values such as the indoor temperature and the outdoor temperature from the measurement unit 133 from the external device 130 during the trial operation.

In the air conditioner 110, the communication unit 111 transmits the control information 113C to the management server 120 (step S109). The control information 113C includes information indicating that the operation mode is test operation, measured values measured by the measuring unit 115 of the air conditioner 110, measured values measured by the measuring unit 133 of the external device 130, and the like. That is, the communication unit 111 transmits to the management server 120 the control information 113C including the measured values of the defined measurement items. Note that the communication unit 111 may also transmit the information of the air conditioner basic information 113A together with the control information 113C.

In the management server 120 , the communication unit 121 acquires the control information 113</b>C including the measured values of the prescribed measurement items from the air conditioner 110 . When the selection unit 122 acquires the control information 113C from the air conditioner 110 via the communication unit 121, the selection unit 122 analyzes the control information 113C (step S110).

The analysis processing of the selection unit 122 of the management server 120 will be described in detail using the flowchart of FIG. The selection unit 122 determines whether or not the current operation mode of the air conditioner 110 included in the control information 113C is test operation (step S201). When the current operation mode of the air conditioner 110 is test operation (step S201: Yes), the selection unit 122 determines whether or not the control information 113C acquired from the air conditioner 110 includes a measured value (step S202). . When the control information 113C includes the measured value (step S202: Yes), the selection unit 122 estimates the usage environment of the air conditioner 110 (step S204). That is, the selection unit 122 estimates the use environment of the air conditioner 110 using the measured values measured during the trial operation of the air conditioner 110 . The selection unit 122 selects, for example, the size of the space to be air-conditioned and the degree of temperature change as the usage environment in which the air conditioner 110 is used, using information such as the amount of power used and the room temperature included in the control information 113C. Estimate the ease, etc. When the air conditioner basic information 113A is acquired together with the control information 113C at the time of estimation, the selection unit 122 may use the information of the configuration at the time of installation of the air conditioning system 100 included in the air conditioner basic information 113A. The selection unit 122 selects an air conditioning control algorithm that matches the estimation result from the storage unit 123 as an air conditioning control algorithm that the air conditioner 110 uses during normal operation (step S205).

Here, for the measurement items such as power consumption and room temperature, target values are set in consideration of energy conservation and user comfort. , an air-conditioning control algorithm that eliminates differences between target values such as power consumption and room temperature and current measured values such as power consumption and room temperature. In addition, the storage unit 123 stores a set of air conditioning control algorithms for eliminating the difference between the target value and the current measured value for each size of the space to be air-conditioned and for each easiness of temperature change. shall be For example, if the air conditioner 110 is for home use, the size of the space to be air-conditioned can be controlled for less than 6 tatami mats, 6 to 10 tatami mats, 10 to 15 tatami mats, and so on. It summarizes the size of the target space for each range. In addition, each easiness of temperature change means, for example, a tropical zone in which the temperature of the space to be air-conditioned is easy to raise and difficult to lower, and a cold zone in which the temperature of the space to be air-conditioned is easy to lower and difficult to raise. It assumes the climatic zone where

The selection unit 122 selects an air-conditioning control algorithm that eliminates the difference between the measurement value of the measurement item for which the target value is set and the target value. In addition, the selection unit 122 selects an air-conditioning control algorithm set for a range including the measured values of a measurement item for which a plurality of ranges are set according to possible values. For example, the selection unit 122 selects the air conditioning equipment 110 in a tropical environment where the space to be air-conditioned has a size of 6 tatami mats or more and less than 10 tatami mats, and the temperature of the space to be air-conditioned is easy to raise and difficult to lower. If it is estimated that the air-conditioning control algorithm that eliminates the difference between the target value and the current measured value from among the set of air-conditioning control algorithms for tropical areas with a size of 6 tatami mats or more and less than 10 tatami mats to select. The selection unit 122 selects an air conditioning control algorithm that eliminates the difference between the target value and the current measured value. In this case, the air conditioning control algorithm is selected to increase the temperature by the difference of 3°C so that the current indoor temperature is 22°C to 25°C.

Returning to the description of the flowchart in FIG. In the management server 120, the communication unit 121 transmits the air conditioning control algorithm selected by the selection unit 122 to the air conditioning equipment 110 (step S111).

In the air conditioner 110, the communication unit 111 acquires from the management server 120 the air conditioning control algorithm selected by the management server 120 using the control information 113C. The data updating unit 112 updates the air conditioning control algorithm 113B held in the storage unit 113 with the air conditioning control algorithm acquired from the management server 120 via the communication unit 111 . Further, the data updating unit 112 updates the operation mode information from "test run" to "normal operation" for the control information 113C held in the storage unit 113 (step S112). For example, when the updated air-conditioning control algorithm 113B is in the "energy-saving mode" mode, the data updating unit 112 updates the operation mode to "normal operation energy-saving mode". However, it is sufficient that the control information 113C includes that the operation mode is "normal operation, energy saving mode", and specific update contents are not required.

Next, the operation of acquiring and updating the air conditioning control algorithm 113B while the air conditioning system 100 is operating normally will be described. FIG. 4 is a flowchart showing normal operation of the air conditioner 110 according to the first embodiment.

In a state where the trial operation is completed and the air conditioning operation is stopped, the air conditioning equipment 110 receives an instruction to start the air conditioning operation of the air conditioning equipment 110 from the user (step S301). The user instructs the air conditioning equipment 110 to start the air conditioning operation, for example, via the input unit 116 of the air conditioning equipment 110 or using the aforementioned remote controller.

In the air conditioner 110, the air conditioning control unit 114 executes the air conditioning control algorithm 113B stored in the storage unit 113 to perform air conditioning operation (step S302).

In the air conditioning system 100, operations of the air conditioning equipment 110 and the management server 120 when the air conditioning equipment 110 performs normal air conditioning operation will be described in detail. FIG. 5 is a flowchart showing operations of air conditioning equipment 110 and management server 120 when air conditioning equipment 110 according to Embodiment 1 performs normal air conditioning operation.

In the air conditioner 110, the air conditioning control unit 114 executes the air conditioning control algorithm 113B held in the storage unit 113 to perform air conditioning operation (step S401).

In the air conditioner 110, the communication unit 111 confirms whether or not it is connected to the external device 130 (step S402). When the communication unit 111 is connected to the external device 130 (step S402: Yes), the communication unit 111 acquires the device information 134A including the measured values from the external device 130 (step S403). That is, the communication unit 111 acquires the measured values measured by the measurement unit 133 from the external device 130 including the measurement unit 133 that measures the defined measurement items. In the air conditioner 110, the data update unit 112 updates the control information 113C held in the storage unit 113 with the device information 134A acquired from the external device 130 via the communication unit 111 (step S404). That is, the data updating unit 112 causes the storage unit 113 to hold the device information 134A. When the air conditioner 110 is not connected to the external device 130 (step S402: No), the operations of steps S403 and S404 are omitted, and the operation proceeds to step S405.

In the air conditioner 110, the communication unit 111 transmits the control information 113C to the management server 120 (step S405). The control information 113C includes information indicating that the operation mode is normal operation, measured values measured by the measuring unit 115 of the air conditioner 110, measured values measured by the measuring unit 133 of the external device 130, and the like. That is, the communication unit 111 transmits to the management server 120 the control information 113C including the measured values of the defined measurement items.

In the management server 120 , the communication unit 121 acquires the control information 113</b>C including the measured values of the prescribed measurement items from the air conditioner 110 . When the selection unit 122 acquires the control information 113C from the air conditioner 110 via the communication unit 121, the selection unit 122 analyzes the control information 113C (step S406).

The analysis processing of the selection unit 122 of the management server 120 will be described in detail using the flowchart of FIG. The selection unit 122 determines whether or not the current operation mode of the air conditioner 110 included in the control information 113C is test operation (step S201). When the current operation mode of the air conditioner 110 is normal operation, not trial operation (step S201: No), the selection unit 122 estimates the situation of the space to be air-conditioned by the air conditioner 110 (step S206). That is, the selection unit 122 uses the measured values measured during the normal operation of the air conditioner 110 to estimate the situation of the space to be air-conditioned by the air conditioner 110 . The selection unit 122 estimates the space situation using the measurement values measured by the measurement unit 115 of the air conditioner 110, the measurement values measured by the measurement unit 133 of the external device 130, and the like, which are included in the control information 113C. The condition of the space is, for example, the number of users present in the space, temperature unevenness in the space, and the like. Note that the selection unit 122 may estimate the state of the user as well as the state of the space. The user's condition is, for example, the user's feeling, such as hot or cold, comfortable or uncomfortable. The selection unit 122 selects an air conditioning control algorithm that matches the estimation result from the storage unit 113 as an air conditioning control algorithm that the air conditioner 110 uses during normal operation (step S205).

Returning to the description of the flowchart in FIG. In the management server 120, the communication unit 121 determines whether or not to change the air conditioning control algorithm used in the air conditioning equipment 110 (step S407). The communication unit 121 stores, for example, information identifying the air conditioning control algorithm transmitted to the air conditioner 110 last time, and the air conditioning control algorithm transmitted to the air conditioner 110 last time and the air conditioning control algorithm selected by the selection unit 122 this time. and are the same, it is determined not to be changed. If the air conditioning control algorithm transmitted to the air conditioner 110 last time differs from the air conditioning control algorithm selected by the selection unit 122 this time, the communication unit 121 determines to change.

When changing the air conditioning control algorithm used in the air conditioner 110 (step S407: Yes), the communication unit 121 transmits the air conditioning control algorithm selected by the selection unit 122 to the air conditioner 110 (step S408).

In the air conditioner 110, the communication unit 111 acquires from the management server 120 the air conditioning control algorithm selected by the management server 120 using the control information 113C. The data updating unit 112 updates the air conditioning control algorithm 113B held in the storage unit 113 with the air conditioning control algorithm acquired from the management server 120 via the communication unit 111 (step S409). Further, the data update unit 112 changes the information of the operation mode in the control information 113C held in the storage unit 113 when the operation mode is changed. For example, the data update unit 112 updates the operation mode to "normal operation comfort priority mode" when the operation mode is normal operation, but the updated air conditioning control algorithm 113B is the "comfort priority mode" mode. do. When the air conditioning control algorithm used in the air conditioning equipment 110 is not changed (step S407: No), the air conditioning system 100 omits the operations of steps S408 and S409.

Returning to the description of the flowchart in FIG. In the air conditioning equipment 110, the air conditioning control unit 114 determines whether or not an instruction to stop the air conditioning operation of the air conditioning equipment 110 has been received from the user (step S303). The user can instruct the air conditioner 110 to stop the air conditioning operation, for example, via the input unit 116 of the air conditioner 110 or using the aforementioned remote controller.

When the air conditioning system 100 has not received an instruction to stop the operation of the air conditioner 110 from the user (step S303: No), the operation of step S302 is repeatedly performed. When receiving an instruction to stop the operation of the air conditioner 110 from the user (step S303: Yes), the air conditioning control unit 114 stops the air conditioning operation of the air conditioner 110 (step S304). Specifically, the air conditioning control unit 114 stops reading the air conditioning control algorithm 113B from the storage unit 113, and stops the operation of the indoor unit 114A and the outdoor unit 114B. Note that the air conditioner 110 performs the operation of step S304 even when receiving an instruction to stop the operation of the air conditioner 110 from the user while performing the operation of step S302.

Next, the hardware configuration of the air conditioning system 100 will be explained. The communication unit 111 of the air conditioner 110, the communication unit 121 of the management server 120, and the communication unit 131 of the external device 130 are communication devices. The storage unit 113 of the air conditioner 110, the storage unit 123 of the management server 120, and the storage unit 134 of the external device 130 are memories. The measurement unit 115 of the air conditioner 110 and the measurement unit 133 of the external device 130 are sensors corresponding to measurement items. The input unit 116 of the air conditioner 110 is an input interface such as a switch. The data update unit 112 of the air conditioning equipment 110, the air conditioning control unit 114 of the air conditioning equipment 110, the selection unit 122 of the management server 120, and the device control unit 132 of the external device 130 are implemented by processing circuits. The processing circuitry is, for example, a processor 91 executing a program stored in the memory 92 and the memory 92 .

FIG. 6 is a diagram showing an example of a hardware configuration included in each device of the air conditioning system 100 according to Embodiment 1. As shown in FIG. When the processing circuit is composed of the processor 91 and the memory 92, each function of the processing circuit is implemented by software, firmware, or a combination of software and firmware. Software or firmware is written as a program and stored in memory 92 . In the processing circuit, each function is realized by the processor 91 reading and executing the program stored in the memory 92 . It can also be said that these programs cause a computer to execute the procedures and methods of operations performed by each device.

Here, the processor 91 may be a CPU (Central Processing Unit), a processing device, an arithmetic device, a microprocessor, a microcomputer, or a DSP (Digital Signal Processor). The memory 92 includes non-volatile or volatile memory such as RAM (Random Access Memory), ROM (Read Only Memory), flash memory, EPROM (Erasable Programmable ROM), EEPROM (registered trademark) (Electrically EPROM). semiconductor memories, magnetic discs, flexible discs, optical discs, compact discs, mini discs, or DVDs (Digital Versatile Discs).

The processing circuitry may be dedicated hardware. When the processing circuit is composed of dedicated hardware, the processing circuit is, for example, a single circuit, a composite circuit, a programmed processor, a parallel programmed processor, an ASIC (Application Specific Integrated Circuit), an FPGA (Field Programmable Gate Array), or a combination of these. Regarding the processing circuit of each device, each function may be realized by a plurality of processing circuits for each function, or each function may be collectively realized by one processing circuit.

It should be noted that each function of the processing circuit of each device may be partly realized by dedicated hardware and partly realized by software or firmware. Thus, the processing circuitry may implement each of the functions described above through dedicated hardware, software, firmware, or a combination thereof.

As described above, according to the present embodiment, in air-conditioning system 100, air-conditioning equipment 110 sends control information 113C including measured values such as power consumption and temperature measured in a space subject to air-conditioning control to the management server. 120. The management server 120 uses the acquired control information 113C to estimate the usage environment of the air conditioning equipment 110, the condition of the air conditioning control target space of the air conditioning equipment 110, and the like, select an air conditioning control algorithm that matches the estimation result, and perform air conditioning. Send to device 110 . The air conditioning equipment 110 updates the air conditioning control algorithm held in the storage unit 113 with the air conditioning control algorithm acquired from the management server 120 . As a result, in the air-conditioning system 100, the air-conditioning equipment 110 automatically selects an air-conditioning control algorithm suitable for the current environment without the need for the user to input in advance information about the usage environment, information about the conditions of the space to be air-conditioned, and the like. Air conditioning control can be performed using the acquired air conditioning control algorithm. The air conditioning system 100 can use the information collected by the air conditioner 110 to automatically update the air conditioning control algorithms used by the air conditioner 110 in response to changes in the environment or user needs. The information collected by the air conditioner 110 includes the measured value measured by the measurement unit 115 of the air conditioner 110, the power consumption measured by the air conditioning control unit 114 of the air conditioner 110, and the measurement unit 133 of the external device 130. information on the operation mode of the air conditioner 110, and the like.

When the air conditioning control algorithm used by the air conditioning equipment 110 is automatically updated, the air conditioning system 100 can be used by the air conditioning equipment 110 without the need for the user to input information or the work of maintenance personnel managing the management server 120. The air conditioning control algorithm used can be automatically updated. In addition, since the air conditioning control algorithm used in the air conditioning equipment 110 can be automatically updated, the manufacturer of the air conditioning equipment 110 does not need to customize the air conditioning equipment 110 before or after shipment of the air conditioning equipment 110, thereby reducing costs. can be reduced.

In addition, since the air conditioner 110 can acquire the air conditioning control algorithm from the management server 120 and update it according to the current air conditioning control state, it is not necessary to store many air conditioning control algorithms in advance. In addition, the air conditioner 110 acquires the air conditioning control algorithm for trial operation from the management server 120 when performing the trial operation, and updates the air conditioning control algorithm for trial operation with the air conditioning control algorithm used in normal operation after the end of the trial operation. , there is no need to store the air-conditioning control algorithm for trial operation in advance, and it is not necessary to store it during normal operation. Therefore, the storage unit 113 can be realized with a small memory capacity in the air conditioner 110, so that the cost can be reduced.

In the present embodiment, the air conditioning equipment 110 can automatically update the air conditioning control algorithm suitable for the current environment without receiving information input from the user. information can also be used. Since some users have preferences such as preferring to be cold or preferring to be hot, the user may be allowed to change the above-described target value. In this case, the user sets user preferences for the air conditioner 110 via the input unit 116 of the air conditioner 110 or using the aforementioned remote control. In the air conditioner 110 , the communication unit 111 transmits preference information received from the user to the management server 120 . Accordingly, in the management server 120, the selection unit 122 can select an air conditioning control algorithm based on the user's preference.

In addition, in the present embodiment, management server 120 acquires information about measured values measured by measuring unit 133 of external device 130 via air conditioning equipment 110, but directly from external device 130, measuring unit 133 You may acquire the information of the measured value measured by. However, in this case, it is necessary for the user or the like to perform connection settings so that communication can be performed between the external device 130 and the management server 120 . On the other hand, if the external device 130 communicates only with the air conditioner 110 as shown in FIG. Therefore, the user can save the trouble of making connection settings so that communication can be performed between the external device 130 and the management server 120 . Further, as shown in FIG. 1 , if the external device 130 communicates only with the air conditioning equipment 110 , the air conditioning system 100 can operate the external device 130 even in an environment where the external device 130 cannot directly communicate with the management server 120 . Measurements of device 130 can be utilized.

Embodiment 2.
In Embodiment 1, the external device 130 is assumed to be, for example, a stationary sensor, but is not limited to this. The external device 130 may be, for example, a wearable device that can be worn by the user, such as a smartwatch.

In the second embodiment, the configuration of the air conditioning system 100 and the configuration of each device included in the air conditioning system 100 are the same as those of the first embodiment as shown in FIG. When the external device 130 is a wearable device, the external device 130 holds information identifying the user in the storage unit 134 as device information 134A. In addition, the external device 130 is provided with a measurement unit 133 capable of measuring the pulse rate, amount of perspiration, etc. of the user wearing the external device 130, so that user-specific device information 134A can be obtained.

In management server 120, selection unit 122 acquires control information 113C from air conditioner 110 in the same procedure as in the first embodiment. The control information 113C includes device information 134A of the external device 130, that is, measured values such as the user's pulse rate and amount of perspiration. When estimating the space situation, the selection unit 122 can also estimate the state of the user in detail. The management server 120 holds in the storage unit 113 a set of air conditioning control algorithms for each user condition, for example, for hot, cold, comfortable, and uncomfortable conditions, and controls air conditioning according to the estimated user condition. By selecting an algorithm, even more detailed air conditioning control can be achieved.

The configuration shown in the above embodiment shows an example of the content of the present invention, and it is possible to combine it with another known technology, and one configuration can be used without departing from the scope of the present invention. It is also possible to omit or change the part.

100 air conditioning system, 110 air conditioning equipment, 111, 121, 131 communication unit, 112 data update unit, 113, 123, 134 storage unit, 113A air conditioning equipment basic information, 113B, 123A to 123N air conditioning control algorithm, 113C control information, 114 air conditioning Control unit, 114A indoor unit, 114B outdoor unit, 115, 133 measurement unit, 116 input unit, 120 management server, 122 selection unit, 130 external device, 132 device control unit, 134A device information, 134B device control algorithm.

Claims (20)

An air conditioner that transmits control information including measured values for specified measurement items;
a management server that selects a first air conditioning control algorithm to be used in the air conditioner using the control information acquired from the air conditioner and transmits the first air conditioning control algorithm to the air conditioner;
with
The air conditioner includes a storage unit that holds a second air conditioning control algorithm used when performing air conditioning control, and the first air conditioning control algorithm acquired from the management server is held in the storage unit. When updating the second air conditioning control algorithm and executing a plurality of second air conditioning control algorithms for test operation, after executing one of the second air conditioning control algorithms for test operation, requesting the management server for a first air conditioning control algorithm for trial operation corresponding to the second air conditioning control algorithm of
air conditioning system. The management server estimates the usage environment of the air conditioner using the measured values measured during the trial operation of the air conditioner, and selects a first air conditioning control algorithm that matches the estimated usage environment.
The air conditioning system of Claim 1. The management server uses the measured values measured during normal operation of the air conditioner to estimate the conditions of the space to be air-conditioned by the air conditioner, and performs the first air conditioning that matches the estimated condition of the space. select the control algorithm,
The air conditioning system according to claim 1 or 2. The management server selects, for a measurement item for which a target value is set, a first air conditioning control algorithm that eliminates a difference between the measurement value of the measurement item and the target value.
An air conditioning system according to any one of claims 1 to 3. The management server selects a first air conditioning control algorithm set for a range including the measured values of a measurement item for which a plurality of ranges are set according to possible values.
An air conditioning system according to any one of claims 1 to 4. an external device that includes a measurement unit and transmits the measured value measured by the measurement unit to the air conditioner;
6. The air conditioning system of any one of claims 1-5, comprising: The external device is a wearable device that can be worn by a user,
The air conditioning system of claim 6. a communication unit that transmits control information including measured values of specified measurement items to a management server, and acquires from the management server a first air conditioning control algorithm selected by the management server using the control information; ,
a storage unit that holds a second air-conditioning control algorithm used when performing air-conditioning control;
a data updating unit that updates the second air conditioning control algorithm held in the storage unit with the first air conditioning control algorithm acquired from the management server;
When executing a plurality of second air conditioning control algorithms for test operation, after executing one of the second air conditioning control algorithms for test operation, a test operation corresponding to the second air conditioning control algorithm for test operation to be performed next an air conditioning control unit that requests the management server for a first air conditioning control algorithm for
air conditioning equipment. a measurement unit that measures the defined measurement items and outputs the measured values;
The air conditioner according to claim 8, comprising: The communication unit acquires the measured value measured by the measurement unit from an external device including a measurement unit that measures the specified measurement item.
The air conditioner according to claim 8 or 9. a communication unit that acquires control information including measured values of specified measurement items from the air conditioner;
a storage unit that holds a plurality of first air conditioning control algorithms that can be used by the air conditioner;
a selection unit that selects a first air conditioning control algorithm used in the air conditioner from the storage unit using the control information acquired from the air conditioner;
with
The communication unit transmits the first air conditioning control algorithm selected by the selection unit to the air conditioner,
For each request of the first air conditioning control algorithm for commissioning from the air conditioner,
The selection unit selects one of the test run first air conditioning control algorithms from the storage unit,
The communication unit transmits one of the test run first air conditioning control algorithms selected by the selection unit to the air conditioning equipment.
Management server. The selection unit estimates the usage environment of the air conditioner using the measured values measured during the trial operation of the air conditioner, and selects a first air conditioning control algorithm that matches the estimated usage environment.
Management server according to claim 11 . The selection unit estimates the condition of a space to be subjected to air conditioning control by the air conditioner using the measured values measured during normal operation of the air conditioner, and selects a first air conditioner that matches the estimated condition of the space. select the control algorithm,
The management server according to claim 11 or 12. The selection unit selects a first air conditioning control algorithm that eliminates the difference between the measurement value of the measurement item for which the target value is set and the target value.
Management server according to any one of claims 11 to 13. The selection unit selects a first air conditioning control algorithm set for a range including the measured values of a measurement item for which a plurality of ranges are set according to possible values.
Management server according to any one of claims 11 to 14. A first step in which the air conditioning equipment transmits control information including measured values for specified measurement items;
A management server selects a first air conditioning control algorithm to be used in the air conditioner using the control information acquired from the air conditioner, and transmits the first air conditioning control algorithm to the air conditioner. a step of
The air conditioner has a storage unit that holds a second air conditioning control algorithm used when performing air conditioning control, and the first air conditioning control algorithm acquired from the management server is held in the storage unit. a third step of updating the second climate control algorithm;
When the air conditioner implements a plurality of second air conditioning control algorithms for test operation, after performing one of the second air conditioning control algorithms for test operation, the second air conditioning control for test operation is performed next. a fourth step of requesting the management server for a first air conditioning control algorithm for trial operation corresponding to the algorithm;
air conditioning control algorithm update method. In the second step, the management server estimates the use environment of the air conditioner using the measured values measured during the trial operation of the air conditioner, and performs first air conditioning control that matches the estimated use environment. choose an algorithm,
The air conditioning control algorithm update method according to claim 16. In the second step, the management server uses measured values measured during normal operation of the air conditioning equipment to estimate the conditions of the space to be air-conditioned by the air conditioning equipment, and estimate the conditions of the space. selecting a first climate control algorithm that matches
The air conditioning control algorithm update method according to claim 16 or 17. In the second step, the management server selects, for a measurement item for which a target value is set, a first air conditioning control algorithm that eliminates a difference between the measurement value of the measurement item and the target value.
The air conditioning control algorithm update method according to any one of claims 16 to 18. In the second step, the management server uses a first air conditioning control algorithm set for a range including the measured values of a measurement item for which a plurality of ranges are set according to possible values. select the
The air conditioning control algorithm update method according to any one of claims 16 to 19.

Images