JP7542650B2 - Air conditioning system, air conditioning method, and air conditioning program - Google Patents

Description

The present disclosure relates to an air conditioning system that automatically extends the life of an air conditioner, an air conditioning method, and an air conditioning program for extending the life of an air conditioner.

Conventionally, a system is known that determines whether there are signs of an air conditioner failure, as well as whether there is performance degradation due to aging (see, for example, Patent Document 1). If the system determines that there are signs of an air conditioner failure, it notifies a monitoring staff member of information indicating the signs of failure, or predicts when the failure will occur. Furthermore, if the system determines that the performance of the air conditioner has deteriorated due to aging, it queries the user about the desired operation. The system then changes the values of the air conditioner's control parameters in order to have the air conditioner operate in accordance with the user's response.

JP 2016-065680 A

The system described in Patent Document 1 above does not change the operation of an air conditioner when there are signs of an impending failure in the air conditioner. As a result, the system may cause an air conditioner that is predicted to fail to continue to operate as if it were in normal operation, which would prevent the air conditioner from extending its life. Alternatively, the system may cause an air conditioner that is predicted to fail to operate in the same way as if it were in normal operation, and may not allow the air conditioner to operate at all. In this case, there is a risk that the air conditioner will become inoperable during seasons such as summer or winter when users require air conditioning.

Furthermore, the above system does not automatically determine the optimal operation to extend the life of the air conditioner when its performance is deteriorating, and does not make the air conditioner perform the determined operation. As a result, the air conditioner is more likely to deteriorate over time, its lifespan will be shortened, and it may become unable to operate at a time when the user needs it.

This disclosure has been made to solve the above-mentioned problems, and aims to provide an air conditioning system, an air conditioning method, and an air conditioning program that achieve both maintaining the operation of the air conditioner and extending its lifespan.

The air conditioning system according to the present disclosure includes an air conditioner that conditions the air of a room, a plurality of air conditioning sensors that detect values of a plurality of operating parameters that indicate the operating state of the air conditioner, a storage unit that stores values of a plurality of contrast parameters that indicate the operating state of each of a plurality of air conditioners including a comparison air conditioner under the same conditions as the air conditioner, and stores each of a plurality of pieces of comparison deterioration information that indicates, in a chronological order, at least one of the degree of deterioration of each of the plurality of air conditioners, the degree of deterioration of each of a plurality of parts in each of the plurality of air conditioners, and the degree of deterioration of two or more of the plurality of parts in each of the plurality of air conditioners, based on all or a portion of the values of the plurality of contrast parameters, and a storage unit that stores each of a plurality of pieces of comparison deterioration information that indicates, in a chronological order, at least one of the degree of deterioration of each of the plurality of air conditioners, the degree of deterioration of each of a plurality of parts in each of the plurality of air conditioners, based on all or a portion of the values of the plurality of contrast parameters, The system comprises a deterioration estimation unit that estimates the degree of deterioration of an object, which is the air conditioner or one or more of the multiple parts in the air conditioner, by comparing the deterioration degree of the object with all or a part of the values of the multiple comparison parameters; a life calculation unit that extracts extracted deterioration information, which is one piece of comparison deterioration information, from the multiple pieces of comparison deterioration information stored in the memory unit based on the time series deterioration degree estimated by the deterioration estimation unit within a predetermined comparison time range, and calculates the life time of the object from the present time to the time of failure using the extracted deterioration information; a control construction unit that constructs control content for extending the life time calculated by the life calculation unit based on the extracted deterioration information extracted by the life calculation unit; and an air conditioning control unit that controls the air conditioner based on the control content constructed by the control construction unit.

An air conditioning method according to the present disclosure is an air conditioning method executed by an air conditioning system including an air conditioner that conditions the air of a room, a plurality of air conditioning sensors that detect values of a plurality of operating parameters that indicate the operating state of the air conditioner, and a memory unit that stores values of a plurality of contrast parameters that indicate the operating state of each of a plurality of air conditioners including a comparison air conditioner under the same conditions as the air conditioner, and stores each of a plurality of pieces of comparison deterioration information that indicates, in a chronological order, at least one of the deterioration degree of each of the plurality of air conditioners, the deterioration degree of each of a plurality of parts in each of the plurality of air conditioners, and the deterioration degree of two or more of the plurality of parts in each of the plurality of air conditioners, based on the values of the plurality of contrast parameters, and The method includes a deterioration estimation step of estimating the degree of deterioration of an object, which is the air conditioner or one or more of the multiple parts in the air conditioner, by comparing the value of all or a part of the meter; a life calculation step of extracting extracted deterioration information, which is one piece of comparative deterioration information, from the multiple pieces of comparative deterioration information stored in the memory unit based on the degree of deterioration in time series within a predetermined comparison time range estimated in the deterioration estimation step, and calculating the life time of the object from the present time to the time of failure using the extracted deterioration information; a control construction step of constructing control content for extending the life time calculated in the life calculation step based on the extracted deterioration information extracted in the life calculation step; and an air conditioning control step of controlling the air conditioner based on the control content constructed in the control construction step.

The air conditioning program according to the present disclosure is an air conditioning program executed by an air conditioning system including an air conditioner that performs indoor air conditioning, a plurality of air conditioning sensors that detect values of a plurality of operating parameters that indicate the operating state of the air conditioner, and a memory unit that stores values of a plurality of contrast parameters that indicate the operating state of each of a plurality of air conditioners including a comparison air conditioner under the same conditions as the air conditioner, and stores each of a plurality of pieces of comparison deterioration information that indicates, in a chronological order, at least one of the deterioration degree of each of the plurality of air conditioners, the deterioration degree of each of a plurality of parts in each of the plurality of air conditioners, and the deterioration degree of two or more of the plurality of parts in each of the plurality of air conditioners, based on the values of the plurality of contrast parameters, and The air conditioning system realizes the following: a deterioration estimation function that estimates the degree of deterioration of an object, which is the air conditioner or one or more of the multiple parts in the air conditioner, by comparing it with all or part of the values of the parameters; a life calculation function that extracts extracted deterioration information, which is one piece of comparative deterioration information, from the multiple pieces of comparative deterioration information stored in the memory unit based on the time-series deterioration degree estimated by the deterioration estimation function within a predetermined comparison time range, and calculates the lifespan of the object from the present time to the time of failure using the extracted deterioration information; a control construction function that constructs control content for extending the lifespan calculated by the lifespan calculation function based on the extracted deterioration information extracted by the lifespan calculation function; and an air conditioning control function that controls the air conditioner based on the control content constructed by the control construction function.

According to the air conditioning system, air conditioning method, and air conditioning program disclosed herein, the deterioration degree of an object, which is an air conditioner or one or more parts of the air conditioner, is estimated from all or a part of a plurality of operating parameters and all or a part of the values of a plurality of comparison parameters. Then, based on the deterioration degree in time series, extracted deterioration information is extracted from the plurality of comparison deterioration information stored in the storage unit. Each of the plurality of comparison deterioration information is information indicating, in time series, at least one of the deterioration degree of each of the plurality of air conditioners, the deterioration degree of each of the plurality of parts in each air conditioner, and the deterioration degree of two or more parts in each air conditioner. The extracted deterioration information extracted based on the deterioration degree in time series of the object indicates how the deterioration of the object progresses. Then, using the extracted deterioration information, control contents for extending the life of the object and the air conditioner including the object are constructed, and the air conditioner is controlled according to the control contents. Therefore, according to the air conditioning system, the air conditioning method, and the air conditioning program, it is possible to extend the life of the air conditioner while maintaining its operation.

1 is a schematic diagram showing a configuration example of an air conditioning system according to a first embodiment; 1 is a schematic diagram showing a configuration example of an air conditioner according to a first embodiment. FIG. 2 is a block diagram illustrating functions of the air conditioning system according to the first embodiment. FIG. FIG. 11 is a diagram illustrating an example of contrast degradation information. 11 is a diagram illustrating an example of deterioration information generated by a deterioration estimation unit. FIG. 13 is a diagram illustrating an example of deterioration information in a case where the life time of an object is extended by control according to control content constructed by a control construction unit. FIG. FIG. 2 is a block diagram illustrating a schematic example of a detailed configuration of the air conditioning system according to the first embodiment. 4 is a flowchart illustrating a flow of an air conditioning process by the air conditioning system according to the first embodiment. FIG. 11 is a block diagram illustrating a schematic example of a detailed configuration of an air conditioning system according to a second embodiment. FIG. 11 is a block diagram illustrating a schematic example of a detailed configuration of an air conditioning system according to a third embodiment.

The air conditioning system 100 according to the embodiment will be described in detail below with reference to the drawings. Note that the size relationships between the components in the drawings may differ from the actual relationships.

Embodiment 1.
FIG. 1 is a schematic diagram showing a configuration example of an air conditioning system according to the first embodiment. The air conditioning system 100 includes an outdoor unit 1, an indoor unit 3, and a remote controller 5. The outdoor unit 1, the indoor unit 3, and the remote controller 5 are combined to form an air conditioner 101. The outdoor unit 1 and the indoor unit 3 communicate with each other wirelessly or by wire. The remote controller 5 communicates wirelessly with the indoor unit 3, for example, by infrared communication. The remote controller 5 may also communicate by wire with the indoor unit 3. The remote controller 5 receives an instruction input from a user and transmits an operation signal indicating the instruction to the indoor unit 3. The indoor unit 3 transmits a signal corresponding to the operation signal to the outdoor unit 1, which signal is used to reflect the instruction in the outdoor unit 1. In the following, the signal is also referred to as an operation signal. The outdoor unit 1 and the indoor unit 3 perform air conditioning as desired by the user according to the received operation signal. The remote controller 5 may transmit an operation signal to the outdoor unit 1 together with the indoor unit 3 or in place of the indoor unit 3.

In Fig. 1, the indoor unit 3 is shown as a ceiling-embedded type with air outlets in four directions, but the indoor unit 3 may be a wall-mounted type or a ceiling-suspended type. Also, in Fig. 1, an air conditioner 101 having one outdoor unit 1 and one indoor unit 3 is shown, but the air conditioner 101 may have one or more outdoor units 1 and one or more indoor units 3, for example, it may have one outdoor unit 1 and multiple indoor units 3.

The remote controller 5 has a wireless communication function using Bluetooth (registered trademark) or Wi-Fi (registered trademark), etc., and performs wireless communication with a terminal 7 having a communication function, such as a smartphone or a tablet terminal. The remote controller 5 may perform wired communication with the terminal 7 instead of wireless communication. The terminal 7 may accept input of air conditioning instructions from a user instead of the remote controller 5. In this case, the terminal 7 generates an operation signal indicating the instruction and transmits the operation signal to the remote controller 5 or the indoor unit 3. When the remote controller 5 receives an operation signal from the terminal 7, it transmits the operation signal to the indoor unit 3.

The remote controller 5 communicates with a server 9, for example on a cloud, via the network 2 using a wireless communication function or a wired communication function. The terminal 7 and the server 9 can communicate with each other using a wireless communication function or a wired communication function. Note that instead of the remote controller 5, or together with the remote controller 5, at least one of the outdoor unit 1 and the indoor unit 3 may be able to communicate with the terminal 7 and the server 9 using a wireless communication function or a wired communication function.

Figure 2 is a schematic diagram showing an example of the configuration of an air conditioner in embodiment 1. The outdoor unit 1 and the indoor unit 3 are connected via a refrigerant pipe 4 that circulates a refrigerant therein. This forms a refrigerant circuit 6 that includes the outdoor unit 1 and the indoor unit 3, and the refrigerant circulates in the refrigerant circuit 6.

The outdoor unit 1 has an outer shell formed by a housing, and inside the housing are an outdoor communication unit 10, an outdoor control device 11, a compressor 12, a flow switching device 13, an outdoor heat exchanger 14, an outdoor blower 15, an outdoor flow control valve 16, a shutoff valve 17, a pressure vessel 18, an outdoor heat exchanger temperature sensor 19, an outdoor air temperature sensor 20, a discharge side pressure sensor 21, a suction side pressure sensor 22, and a discharge side temperature sensor 23. In FIG. 2, the housing is indicated by a dotted line. The compressor 12, the flow switching device 13, the outdoor heat exchanger 14, and the outdoor flow control valve 16 are connected in sequence by refrigerant piping 4.

The outdoor communication unit 10 communicates with the indoor unit 3. The outdoor control device 11 is connected to the outdoor communication unit 10, the compressor 12, the flow path switching device 13, the outdoor blower 15, the outdoor flow rate adjustment valve 16, and the shutoff valve 17 by wiring (not shown). The outdoor control device 11 then controls the compressor 12, the flow path switching device 13, the outdoor blower 15, the outdoor flow rate adjustment valve 16, and the shutoff valve 17 in response to an operation signal received from the indoor unit 3 via the outdoor communication unit 10.

The compressor 12 compresses the refrigerant sucked in from the suction side and discharges it from the discharge side as a high-temperature, high-pressure gas refrigerant. The outdoor control device 11 inputs power from a power source (not shown) to the compressor 12 and applies a current. The outdoor control device 11 controls the power and current values. The outdoor control device 11 controls the outdoor communication unit 10 to transmit the power and current values to the indoor unit 3. Each of the power and current is an example of an operating parameter that indicates the operating state of the air conditioner 101. The outdoor control device 11 is also an example of an air conditioning sensor that obtains information indicating the power input to the compressor 12 and the current applied to the compressor 12.

The flow path switching device 13 includes, for example, a four-way valve, and switches the direction of the refrigerant flow path. The flow path switching device 13 switches the refrigerant flow path to switch between cooling and heating. In FIG. 2, the solid line portion of the flow path switching device 13 indicates the refrigerant flow path during cooling operation. Also, the dashed line portion indicates the refrigerant flow path during heating operation. Similarly, the solid line arrow in FIG. 2 indicates the direction in which the refrigerant flows during cooling operation, and the dashed line arrow indicates the direction in which the refrigerant flows during heating operation.

The outdoor heat exchanger 14 exchanges heat between the refrigerant and the outdoor air. The outdoor heat exchanger 14 functions as a refrigerant condenser during cooling operation and as a refrigerant evaporator during heating operation. The outdoor blower 15 includes an outdoor fan 15B such as a sirocco fan, turbo fan, or propeller fan driven by an outdoor drive source 15A such as a fan motor, and guides outdoor air to the outdoor heat exchanger 14 in the outdoor unit 1 and sends the air after heat exchange with the refrigerant to the outside. The outdoor blower 15 is an example of a blower.

The outdoor flow rate control valve 16 adjusts the flow rate of the refrigerant circulating between the outdoor unit 1 and the indoor unit 3 by changing the opening degree, and also reduces the pressure of the refrigerant compressed in the compressor 12. The outdoor flow rate control valve 16 is an expansion valve such as an electronic expansion valve.

When the shutoff valve 17 is opened, it allows the refrigerant to flow through the refrigerant circuit 6. When the shutoff valve 17 is closed, it blocks the flow of the refrigerant through the refrigerant circuit 6. The pressure vessel 18 is a vessel for storing the refrigerant.

The outdoor heat exchanger temperature sensor 19 is provided inside or outside the outdoor heat exchanger 14 and detects the temperature of the refrigerant in the outdoor heat exchanger 14. The outdoor air temperature sensor 20 is provided at the outdoor air intake port of the outdoor unit 1 and detects the outdoor air temperature. The discharge side pressure sensor 21 is provided in the refrigerant piping 4 on the side where the refrigerant is discharged from the compressor 12 and measures the pressure of the refrigerant discharged from the compressor 12. The suction side pressure sensor 22 is provided in the refrigerant piping 4 on the upstream side of the refrigerant with respect to the compressor 12 and measures the pressure of the refrigerant sucked into the compressor 12.

The discharge side temperature sensor 23 is provided on the refrigerant discharge side of the main body of the compressor 12 and detects the temperature of the main body of the compressor 12. The discharge side temperature sensor 23 may be provided in the refrigerant piping 4 on the discharge side and may detect the temperature of the refrigerant piping 4 or the temperature of the refrigerant discharged from the compressor 12. The outdoor heat exchanger temperature sensor 19, the outdoor air temperature sensor 20, the discharge side pressure sensor 21, the suction side pressure sensor 22, and the discharge side temperature sensor 23 are each examples of air conditioning sensors. In addition, the refrigerant temperature, outdoor air temperature, refrigerant pressure, or compressor 12 temperature measured by each of these air conditioning sensors are examples of operating parameters that indicate the operating state of the air conditioner 101.

The outdoor control device 11 is connected to the outdoor heat exchanger temperature sensor 19, the outdoor air temperature sensor 20, the discharge side pressure sensor 21, the suction side pressure sensor 22, and the discharge side temperature sensor 23 by wiring not shown, and obtains detection results from these air conditioning sensors.

The indoor unit 3 has an outer shell formed using a housing, and inside the housing are a first indoor communication unit 30, a second indoor communication unit 31, an indoor control device 32, an indoor heat exchanger 33, an indoor blower 34, an indoor flow control valve 35, an indoor heat exchanger temperature sensor 36, and an indoor temperature sensor 37. Note that in Figure 2, the housing is indicated by a dotted line. The first indoor communication unit 30 communicates with the remote controller 5. The second indoor communication unit 31 communicates with the outdoor unit 1.

The indoor control device 32 is connected to the first indoor communication unit 30, the second indoor communication unit 31, the indoor blower 34, and the indoor flow control valve 35 by wiring (not shown). The indoor control device 32 controls the indoor blower 34 and the indoor flow control valve 35 in response to an operation signal received from the remote controller 5 via the first indoor communication unit 30, and controls the second indoor communication unit 31 to transmit an operation signal to the outdoor unit 1.

The indoor heat exchanger 33 exchanges heat between the refrigerant from the outdoor unit 1 and the air sent from the room to the inside of the indoor unit 3 by the indoor blower 34. The indoor blower 34 includes an indoor fan 34B such as a sirocco fan, turbo fan, or propeller fan driven by an indoor driving source 34A such as a fan motor, and guides indoor air to the indoor heat exchanger 33 in the indoor unit 3 and sends the air after heat exchange with the refrigerant into the room. The indoor blower 34 controls the amount of air blown out from the indoor unit 3. The indoor blower 34 is an example of a blower.

The indoor flow rate control valve 35 adjusts the flow rate of the refrigerant circulating between the outdoor unit 1 and the indoor unit 3 by changing its opening. The indoor flow rate control valve 35 is an expansion valve such as an electronic expansion valve.

The indoor heat exchanger temperature sensor 36 is provided inside or outside the indoor heat exchanger 33 and detects the temperature of the refrigerant. The indoor temperature sensor 37 is provided at the indoor air intake port of the indoor unit 3 and detects the temperature of the indoor air. The indoor heat exchanger temperature sensor 36 and the indoor temperature sensor 37 are each examples of an air conditioning sensor. In addition, the refrigerant temperature or indoor air temperature measured by each of these air conditioning sensors are examples of operating parameters that indicate the operating state of the air conditioner 101.

The indoor control device 32 is connected to the indoor heat exchanger temperature sensor 36 and the indoor temperature sensor 37 by wiring (not shown) and acquires detection results from these air conditioning sensors. The indoor control device 32 controls the first indoor communication unit 30 to transmit the detection results of each of the indoor heat exchanger temperature sensor 36 and the indoor temperature sensor 37 to the remote controller 5.

The first indoor communication unit 30 may communicate with at least one of the terminal 7 and the server 9. In this case, the indoor control device 32 may control the first indoor communication unit 30 to transmit the values of the operating parameters detected by the indoor heat exchanger temperature sensor 36 and the indoor temperature sensor 37 to the terminal 7 or the server 9, whichever is capable of communicating with the first indoor communication unit 30.

The air conditioning system 100 can detect an abnormality in the air conditioner 101, such as an abnormality in the compressor 12, from the values of the operating parameters detected by the air conditioning sensors. For example, the value of the current applied to the compressor 12 can vary depending on the degree of deterioration of the compressor 12 or the outdoor control device 11. There is a reference value for the current or a reference range for the value of the current, at which it is determined that the compressor 12 or the outdoor control device 11 is not deteriorated and is operating normally. If the value of the current does not match the reference value, or if the value of the current is not within the reference range, it is determined that there is an abnormality in a part of the air conditioner 101, such as that the compressor 12 or the outdoor control device 11 is deteriorated.

Such prediction of air conditioner failure or estimation of deterioration of air conditioners using the detection results of air conditioning sensors has been done in the past. A conventional air conditioning system is known that contacts a maintenance person when it predicts an air conditioner failure. However, the air conditioning system does not necessarily change the operation of an air conditioner that is at risk of failure. Therefore, the air conditioning system may cause an air conditioner that is at risk of failure to operate in the same operation as in normal operation, and the life of the air conditioner cannot be extended. Alternatively, the air conditioning system may stop the operation of an air conditioner that is at risk of failure instead of operating it in the same way as in normal operation, and there is a possibility that the air conditioner will not be able to perform air conditioning during seasons such as summer or winter when users need air conditioning.

In addition, there is a known conventional air conditioning system that, when it estimates the deterioration of an air conditioner, notifies the user of the deterioration of the air conditioner and suggests to the user operation contents corresponding to the deterioration, such as operation contents that reduce power consumption. The air conditioning system ensures the comfort of the user by reflecting the operation contents selected by the user in the air conditioner. On the other hand, when the user desires operation contents corresponding to the deterioration of the air conditioner, the air conditioning system can reduce power consumption and suppress the processing volume of the air conditioner by having the air conditioner perform operation corresponding to the deterioration. In this way, the air conditioning system can reduce the burden on the air conditioner and slow the progression of deterioration. However, the operation contents for slowing the progression of deterioration may differ depending on which parts of the air conditioner are deteriorating, which part of the air conditioner is abnormal, or the type of environment in which the air conditioner is operating.

The air conditioning system 100 according to the first embodiment is capable of extending the life of the air conditioner 101 to the maximum extent possible while maintaining the comfort of the user without stopping the air conditioner 101, and thus enabling life extension according to the condition of the air conditioner 101. The air conditioning system 100 according to the first embodiment will be described in detail below.

3 is a block diagram illustrating the functions of the air conditioning system according to embodiment 1. The air conditioning system 100 includes a memory unit 80, a deterioration estimation unit 81, a life calculation unit 82, a control construction unit 83, and an air conditioning control unit 84.

The memory unit 80 stores a plurality of operating parameters for each of a plurality of air conditioners, including an air conditioner with the same conditions as air conditioner 101. The operating parameters correspond to the operating parameters described above. Below, an air conditioner with the same conditions as air conditioner 101 is described as a comparison air conditioner. Also, below, the operating parameters of the plurality of air conditioners stored in the memory unit 80 are described as comparison parameters. Furthermore, below, any air conditioner among the plurality of air conditioners is simply described as an air conditioner, without a reference number. And, the parts of the air conditioner are also described without a reference number.

The comparison air conditioner refers to an air conditioner that satisfies at least one of the following capacity conditions and environmental conditions. The capacity condition is a condition in which the difference between the capacity parameter value and the capacity parameter value of air conditioner 101 is equal to or less than a predetermined capacity threshold. The capacity parameter is a parameter that serves as an indicator of the capacity of the air conditioner. Examples of capacity parameters include refrigeration capacity, the set power input to the compressor when the air conditioner is first used, or the set current applied to the compressor when the air conditioner is first used. Additionally, the capacity parameter may be information indicating the model or specifications, such as a model number.

An environmental condition is a condition in which the difference between the value of an environmental parameter and the value of the environmental parameter of the air conditioner 101 is equal to or less than a predetermined environmental threshold. The environmental parameter is a parameter that serves as an indicator of the installation environment of the air conditioner. Examples of environmental parameters include the cumulative usage time of the air conditioner, the average temperature of the installation environment of the outdoor unit or indoor unit, information indicating the installation location such as a combination of latitude and longitude, information indicating the weather such as annual precipitation, and the number of indoor units of the air conditioner. Other environmental parameters include the annual average difference between the indoor temperature and the set temperature, the annual average operation time per day, the length of the refrigerant piping, the amount of refrigerant, the average number of people in the room, and the annual average or cumulative value of the power value input to the compressor.

The memory unit 80 stores the values of the capacity parameters and environmental parameters of each of the multiple air conditioners. The values of the capacity parameters and environmental parameters may be values pre-stored in each air conditioner, values manually input, or values detected by a sensor such as the air conditioning sensor or the human presence sensor. Alternatively, the values of the capacity parameters and environmental parameters may be values calculated using at least one of the values pre-stored in each air conditioner, values manually input, and values detected by a sensor such as the air conditioning sensor or the human presence sensor.

The storage unit 80 in the first embodiment classifies and stores normal values and abnormal values of each of the multiple comparison parameters of each of the multiple air conditioners. This will be described in detail below. Information indicating the state of each of the multiple parts included in the air conditioner can be obtained from the value of one or more comparison parameters among the multiple comparison parameters of the air conditioner. Examples of information indicating the state of each of the multiple parts include the degree of deterioration of each of the multiple parts, the degree of blockage of the air intake part in the air conditioner, and information indicating the occurrence or non-occurrence of a short circuit in the air conditioner. Note that the information indicating the state of each of the multiple parts includes information such as the part name for identifying each of the multiple parts. Hereinafter, a state in which a part is deteriorating, a state in which the intake part is blocked, and a state in which a short circuit has occurred are described as abnormal states. Note that an abnormal state exists for each part, and an abnormal state in which the intake part is blocked is the state of each part in the intake part, and an abnormal state in which a short circuit has occurred is the state of the part related to the short circuit. Hereinafter, the state of a part that is not in an abnormal state will be referred to as a normal state.

When each of the multiple parts is in a normal state, the value of each of the multiple contrast parameters is a reference value or a value within a reference range. On the other hand, when each of the multiple parts is in an abnormal state, the value of one or more of the multiple contrast parameters deviates from the reference value or deviates from the reference range. The normal value mentioned above corresponds to the reference value or a value within the reference range. The abnormal value mentioned above corresponds to a value that deviates from the reference value or a value that deviates from the reference range.

The memory unit 80 stores the abnormal values of each of the multiple contrast parameters for each of the multiple air conditioners in association with information indicating an abnormal state of each of the multiple parts in each of the multiple air conditioners. The abnormal values and information indicating the abnormal state are obtained in advance through experiments or learning by AI (Artificial Intelligence). Here, the information indicating the abnormal state of each of the multiple parts is, for example, a combination of information indicating each of the multiple parts that is deteriorating and information indicating the degree of deterioration of each of the multiple parts.

Specifically, the memory unit 80 stores, for example, an abnormal value of the current applied to the compressor, information indicating the part that is deteriorating when the abnormal value is detected, and the degree of deterioration of the part, in association with each other. Note that when the current applied to the compressor becomes an abnormal value, the part that is deteriorating is at least one of the compressor and the outdoor control device that controls the compressor. The magnitude of the abnormal value of the current may differ depending on whether the compressor or the outdoor control device is deteriorating. The memory unit 80 stores, for each abnormal value, information indicating the part that is deteriorating and information indicating the degree of deterioration of the part, in association with each other. In the first embodiment, the degree of deterioration of each of the multiple parts is indicated by a numerical value. Hereinafter, the numerical value indicating the degree of deterioration is simply referred to as the degree of deterioration.

In the first embodiment, the memory unit 80 stores the normal values of the multiple contrast parameters of each of the multiple air conditioners in association with information indicating the normal state of each of the multiple parts in each of the multiple air conditioners. However, the memory unit 80 may not store the normal values of the multiple contrast parameters of each of the multiple air conditioners and the information indicating the normal state of each of the multiple parts in each of the multiple air conditioners. The normal values and the information indicating the normal state are obtained in advance by experiments, learning by AI, or the like. Here, the information indicating the normal state of each of the multiple parts is, for example, a combination of information indicating each of the multiple parts that is not deteriorating and the degree of deterioration of each of the multiple parts.

The storage unit 80 may store information indicating the state of each of the multiple air conditioners, instead of or together with information indicating the state of each of the multiple parts in each of the multiple air conditioners. In this case, the storage unit 80 stores the values of the multiple comparison parameters of each of the multiple air conditioners in association with information indicating the state of each of the multiple air conditioners. The information indicating the state of each of the multiple air conditioners is information indicating the degree of deterioration of each of the multiple air conditioners, the degree of blockage of the air intake part of each of the multiple air conditioners, or the presence or absence of a short circuit in each of the multiple air conditioners. The degree of deterioration of each air conditioner is indicated by a numerical value, similar to the degree of deterioration of each of the above-mentioned parts, and hereinafter, the numerical value indicating the degree of deterioration of each air conditioner is referred to as the degree of deterioration of each air conditioner. The degree of deterioration of each air conditioner is obtained by experiment or learning by AI. The degree of deterioration of each air conditioner may be calculated using the degree of deterioration of each of a plurality of components in that air conditioner.

The storage unit 80 stores the values of the multiple contrast parameters detected in each of the multiple air conditioners at each of the multiple time points until each of the multiple air conditioners breaks down. The storage unit 80 also stores the values of the multiple contrast parameters detected in each of the multiple time points and the degree of deterioration of each of the multiple parts of each of the air conditioners at each of the multiple time points in association with each other. Note that the storage unit 80 may store the degree of deterioration of each of the air conditioners at each of the multiple time points instead of the degree of deterioration of each of the multiple parts of each of the air conditioners at each of the multiple time points. Alternatively, the storage unit 80 may store the degree of deterioration of each of the air conditioners at each of the multiple time points together with the degree of deterioration of each of the multiple parts of each of the air conditioners at each of the multiple time points. In this case, the memory unit 80 stores the values of multiple contrast parameters of each air conditioner detected at each of the multiple points in time in association with the degree of deterioration of each air conditioner.

The storage unit 80 in the first embodiment stores at least one of the deterioration degree of each of the multiple air conditioners, the deterioration degree of each of the multiple parts in each of the multiple air conditioners, and the deterioration degree of two or more of the multiple parts in a chronological order. Hereinafter, information indicating at least one of the deterioration degree of each of the multiple air conditioners, the deterioration degree of each of the multiple parts in each of the multiple air conditioners, and the deterioration degree of two or more of the multiple parts in a chronological order is referred to as comparative deterioration information. Note that the comparative deterioration information indicating the deterioration degree of each of the multiple air conditioners in a chronological order may be obtained from the comparative deterioration information indicating the deterioration degree of each of the multiple parts in each of the multiple air conditioners in a chronological order. In addition, the comparative deterioration information indicating the deterioration degree of two or more parts in a chronological order may be obtained from the comparative deterioration information indicating the deterioration degree of each of the two or more parts in a chronological order.

Figure 4 is a diagram illustrating comparative deterioration information. Three pieces of comparative deterioration information are shown in Figure 4. Each of the three pieces of comparative deterioration information is represented by a curve with the horizontal axis representing time and the vertical axis representing the degree of deterioration. Hereinafter, the curve will be referred to as a deterioration curve. In Figure 4, the deterioration curve is shown by a broken line. In Figure 4, deterioration curve A, deterioration curve B, and deterioration curve C are shown. Each of the deterioration curves A to C shows the degree of deterioration of each air conditioner, each part, or the above two or more parts in chronological order. Each of the multiple points D in Figure 4 shows the degree of deterioration of each air conditioner, each part, or the above two or more parts at each of multiple points in time, obtained by experiment or AI learning. Each of the deterioration curves A to C corresponds to an approximation curve of point D showing the degree of deterioration of each air conditioner, each part, or the above two or more parts at each of multiple points in time. "Design life time" in Figure 4 refers to a predetermined time assumed at the time of design as the life of each air conditioner, each component, or two or more components. The design life times of each of the multiple air conditioners may be different from each other, or may be the same. On the other hand, the design life times of each of the multiple components in any one air conditioner are different from each other, but may also be the same. The design life times of specific components in each of the multiple air conditioners may be the same from each other, or may be different. The degree of deterioration indicated by "failure" in Figure 4 corresponds to the degree of deterioration when each of the air conditioners, each component, or two or more components fail.

When each of deterioration curves A to C in Figure 4 is a deterioration curve that shows the change in the degree of deterioration of each air conditioner over time, the lifespan of the air conditioner whose change in the degree of deterioration over time is shown by deterioration curve B is equal to the design lifespan. On the other hand, the lifespan of the air conditioner whose change in the degree of deterioration over time is shown by deterioration curve A is shorter than the design lifespan assumed at the time of design. And the lifespan of the air conditioner whose change in the degree of deterioration over time is shown by deterioration curve C is longer than the design lifespan assumed at the time of design.

Referring again to Figure 3, the deterioration estimation unit 81 refers to the memory unit 80 and extracts values of a plurality of comparison parameters of the comparison air conditioner based on at least one of the capacity parameter value and the environmental parameter value of the air conditioner 101.

The deterioration estimation unit 81 compares all or part of the values of the multiple operating parameters detected by the multiple air conditioning sensors in the air conditioner 101 with all or part of the values of the multiple comparison parameters of the extracted comparison air conditioner. Note that the deterioration estimation unit 81 may compare all or part of the values of the multiple comparison parameters of each of the multiple air conditioners with all or part of the values of the multiple operating parameters of the air conditioner 101, instead of the values of the multiple comparison parameters of the comparison air conditioner. Alternatively, the deterioration estimation unit 81 may compare all or part of the values of the multiple comparison parameters of each of any part of the multiple air conditioners with all or part of the values of the multiple operating parameters of the air conditioner 101. Note that the operating parameters and the comparison parameters whose values are compared by the deterioration estimation unit 81 are parameters of the same type and whose values are detected by the same type of air conditioning sensors. For example, if the operating parameter is a current applied to the compressor 12, the deterioration estimation unit 81 sets the comparison parameter, the value of which is to be compared with the operating parameter, to the current applied to the compressor.

The deterioration estimation unit 81 estimates the degree of deterioration of the air conditioner 101 or one or more of the multiple parts in the air conditioner 101 based on the matching result. Hereinafter, the air conditioner 101 or the one or more parts in the air conditioner 101 for which the deterioration estimation unit 81 estimates the degree of deterioration will be described as the object. Below, it will be explained how the deterioration estimation unit 81 estimates the degree of deterioration of the object.

The deterioration estimation unit 81 calculates the difference between the value of each operating parameter and the value of each comparison parameter corresponding to each operating parameter. For example, the deterioration estimation unit 81 calculates the difference between the refrigerant temperature in the air conditioner 101 and the refrigerant temperature obtained from the comparison air conditioner. Then, the deterioration estimation unit 81 estimates the degree of deterioration of the air conditioner 101 or each of the multiple parts in the air conditioner 101 based on the difference between each value of the multiple operating parameters and each value of the multiple comparison parameters. Alternatively, the deterioration estimation unit 81 estimates the degree of deterioration of one or more parts in the air conditioner 101 based on the difference between the value of one operating parameter and the value of one comparison parameter, or the difference between each value of two or more operating parameters among the multiple operating parameters and each value of two or more comparison parameters among the multiple comparison parameters.

The deterioration estimation unit 81 estimates the degree of deterioration of the air conditioner 101 as follows. As described above, the memory unit 80 stores the degree of deterioration of the air conditioner in association with the values of multiple contrast parameters of the air conditioner. The deterioration estimation unit 81 estimates the degree of deterioration of the air conditioner 101, for example, based on the sum of the differences between the values of each of the multiple operating parameters and the values of each of the multiple contrast parameters. More specifically, the deterioration estimation unit 81 estimates the degree of deterioration of the air conditioner 101 to be the degree of deterioration associated with the value of the multiple contrast parameters that minimizes the sum.

The deterioration estimation unit 81 estimates the degree of deterioration of each of the multiple parts as follows. The memory unit 80 stores the degree of deterioration of each of the multiple parts in the air conditioner in association with the value of one or more contrast parameters of the air conditioner. When any one part in the air conditioner is in an abnormal state, the value of the one or more contrast parameters of the air conditioner becomes an abnormal value.

When the one part is in an abnormal state and the value of one contrast parameter is an abnormal value, the deterioration estimation unit 81 estimates the deterioration degree of the one part based on the difference between the value of one operating parameter corresponding to the one contrast parameter and the value of the one contrast parameter. Specifically, the deterioration estimation unit 81 estimates the deterioration degree of the one part as the deterioration degree associated with the value of the one contrast parameter in the memory unit 80 that has the smallest difference from the value of the one operating parameter.

On the other hand, when the one part is in an abnormal state and the values of two or more contrast parameters are abnormal, the deterioration estimation unit 81 estimates the deterioration degree of the one part based on the difference between each value of the two or more driving parameters corresponding to each of the two or more contrast parameters and each value of the two or more contrast parameters. Specifically, the deterioration estimation unit 81 estimates the deterioration degree of the one part as the deterioration degree associated with the value of the two or more contrast parameters that minimizes the sum of the differences between each value of the two or more driving parameters and each value of the two or more contrast parameters in the memory unit 80.

The deterioration estimation unit 81 may estimate the degree of deterioration of each part in the air conditioner 101, and estimate the degree of deterioration of the air conditioner 101 based on the degree of deterioration of each part. The deterioration estimation unit 81 may also estimate the degree of deterioration of any two or more parts out of the multiple parts in the air conditioner 101 from the degree of deterioration of each of the two or more parts. Here, the deterioration estimation unit 81 may estimate the degree of deterioration of the two or more parts as follows.

For example, the memory unit 80 stores the degree of deterioration of any two or more parts among the multiple parts in the air conditioner in association with the values of two or more contrast parameters among the multiple contrast parameters of the air conditioner. Note that when the two or more parts are in an abnormal state, the values of the two or more contrast parameters become abnormal values. The deterioration estimation unit 81 may estimate the degree of deterioration of the two or more parts based on the difference between each value of the two or more operation parameters corresponding to each of the two or more contrast parameters and each value of the two or more contrast parameters. Specifically, the deterioration estimation unit 81 estimates the degree of deterioration of the two or more parts as the degree of deterioration associated with the value of the two or more contrast parameters that minimizes the sum of the differences between each value of the two or more operation parameters and each value of the two or more contrast parameters in the memory unit 80.

The deterioration estimation unit 81 may use an AI function to refer to all or part of the values of a plurality of comparison parameters stored in the memory unit 80 based on all or part of the values of a plurality of operating parameters, and estimate the degree of deterioration of the object. In this case, the deterioration estimation unit 81 may refer to all or part of the values of a plurality of comparison parameters of the comparison air conditioner, or may refer to all or part of the values of a plurality of comparison parameters of each of the plurality of air conditioners. When the deterioration estimation unit 81 refers to all or part of the values of a plurality of comparison parameters of the comparison air conditioner, the deterioration estimation unit 81 may extract all or part of the values of a plurality of comparison parameters of the comparison air conditioner using an AI function.

The deterioration estimation unit 81 periodically acquires all or part of the values of the multiple operating parameters detected by the multiple air conditioning sensors in the air conditioner 101. In embodiment 1, the deterioration estimation unit 81 acquires all or part of the values of the multiple operating parameters every time a predetermined acquisition time elapses. The deterioration estimation unit 81 may also acquire all or part of the values of the multiple operating parameters at random timing. Then, the deterioration estimation unit 81 estimates the degree of deterioration of the object at each time point based on all or part of the values of the multiple operating parameters detected at each time point.

The deterioration estimation unit 81 generates deterioration information indicating the deterioration degree of the object in a time series from the estimated deterioration degree of the object at each time point. FIG. 5 is a diagram illustrating deterioration information generated by the deterioration estimation unit. The deterioration information shown in FIG. 5 indicates the deterioration degree of one object in a time series. As shown in FIG. 5, when the horizontal axis is time and the vertical axis is the deterioration degree, and the start point of time is the start time _t0 of use of the air conditioner 101, the deterioration information up to the current time _t1 is indicated by a line E. Point F in FIG. 5 indicates the deterioration degree of the object at each time point estimated by the deterioration estimation unit 81. Line E is a line obtained by connecting points F at each time point.

Returning to FIG. 3, the lifespan calculation unit 82 may generate the above-mentioned deterioration information instead of the deterioration estimation unit 81. In this case, the lifespan calculation unit 82 generates the deterioration information from the degree of deterioration of the object at each point in time estimated by the deterioration estimation unit 81.

When the object is an air conditioner 101, the life calculation unit 82 refers to the memory unit 80 and extracts comparative deterioration information indicating the degree of deterioration of the comparison air conditioner in a chronological order. When the object is one component in the air conditioner 101, the life calculation unit 82 refers to the memory unit 80 and extracts comparative deterioration information indicating the degree of deterioration of a component in the comparison air conditioner that corresponds to that one component in a chronological order. When the object is two or more components in the air conditioner 101, the life calculation unit 82 refers to the memory unit 80 and extracts comparative deterioration information indicating the degree of deterioration of two or more parts in the comparison air conditioner that correspond to the two or more components in a chronological order.

The life calculation unit 82 compares the deterioration information generated by the deterioration estimation unit 81 with the extracted comparative deterioration information. The life calculation unit 82 may compare the deterioration information with all the comparative deterioration information stored in the memory unit 80, or with any part of the comparative deterioration information. In this case, the life calculation unit 82 does not need to extract comparative deterioration information that indicates the degree of deterioration of the comparative air conditioner or one or more parts in the comparative air conditioner in a chronological order.

The life calculation unit 82 calculates the life of the object based on the result of comparing the deterioration information with the comparative deterioration information. Here, the life refers to the time from the present time until the object breaks down. In the following, the time until the failure is referred to as the failure time. The life calculation unit 82 may perform the above-mentioned processing using an AI function. How the life calculation unit 82 calculates the life will be described in detail below.

The lifespan calculation unit 82 compares the deterioration information with the comparison deterioration information, for example, as follows. The lifespan calculation unit 82 calculates the difference between the degree of deterioration at each point in time in a comparison time range of a predetermined length, ending at the current time, in the deterioration information, and the degree of deterioration at each point in time in a time range of the same length as the comparison time range, in the comparison deterioration information. The length of the comparison time range is determined arbitrarily. Hereinafter, the time range of the same length as the comparison time range in the comparison deterioration information is referred to as the comparison time range.

The life calculation unit 82 extracts a comparison time range from among all time ranges indicated by the comparison deterioration information, in which the difference at each point in the comparison time range is equal to or less than the difference threshold value, and in which the sum of the differences in the comparison time range is the smallest. In the comparison deterioration information, an approximation curve of the deterioration degree of the object up to the present time is shown in the extracted comparison time range. Hereinafter, the comparison time range extracted by the life calculation unit 82 is referred to as the extracted time range.

Here, the change over time in the degree of deterioration of the comparison air conditioner and the change over time in the deterioration of one or more parts in the comparison air conditioner are not necessarily uniformly determined. In other words, there may be various patterns in the change over time in the degree of deterioration of the comparison air conditioner and the change over time in the one or more parts. If there are multiple patterns of change over time in the degree of deterioration of the comparison air conditioner or the one or more parts, the memory unit 80 stores multiple pieces of comparison deterioration information indicating these multiple patterns.

When there are multiple pieces of comparative deterioration information for an air conditioner or one or more parts corresponding to the object in the storage unit 80, the life calculation unit 82 compares each of the multiple pieces of comparative deterioration information with the deterioration information. Then, the life calculation unit 82 extracts an extraction time range from all time ranges indicated by each of the multiple pieces of comparative deterioration information, in which the difference at each time point in the comparison time range is equal to or less than the difference threshold value and the sum of the differences in the comparison time range is the smallest. Furthermore, the life calculation unit 82 selects an extraction time range from the extraction time ranges in each of the multiple pieces of comparative deterioration information, in which the sum of the differences is the smallest. Hereinafter, the selected extraction time range is referred to as the selected time range. The life calculation unit 82 extracts the comparative deterioration information from which the selected time range is extracted from the multiple pieces of comparative deterioration information. Hereinafter, the comparative deterioration information from which the life calculation unit 82 extracts the selected time range is referred to as the extracted deterioration information. The extracted deterioration information is information that approximates the pattern of the deterioration progression of the object. If there is only one pattern in the change over time in the degree of deterioration of the comparison air conditioner or one or more parts in the comparison air conditioner, one piece of comparison deterioration information of the comparison air conditioner or one or more parts indicating that one pattern is stored in the storage unit 80. The extracted time range extracted by the life calculation unit 82 from that one piece of comparison deterioration information becomes the selected time range.

Returning to Fig. 5, the above-mentioned collation time range is set to be from the start time _t0 of use of the object to the current time _t1 . As shown in Fig. 5, the line E indicating the deterioration information is approximated by the deterioration curve G indicating the extracted deterioration information. That is, it is estimated that the deterioration of the object is progressing as indicated by the deterioration curve G.

Here, the failure time of the object shown by the deterioration curve G is the time indicated by _t2 . Therefore, the failure time of the object is estimated to be the time _t2 . The life calculation unit 82 calculates the time _T1 from the current time _t1 to the failure time _t2 . The time _T1 is estimated as the life time of the object from the current time _t1 .

Returning to FIG. 3, the control construction unit 83 constructs the control contents of the air conditioner 101 to extend the life time calculated by the life calculation unit 82. The function of the control construction unit 83 may be realized by AI. Note that the control construction unit 83 may construct the control contents only when the life time calculated by the life calculation unit 82 is equal to or less than the life threshold value. The control construction unit 83 will be described in detail below.

Based on the extracted deterioration curve extracted by the life calculation unit 82, the control construction unit 83 constructs the control contents of the air conditioner 101 for extending the life time of the object by referring to the storage unit 80. The storage unit 80 stores one or more control patterns for delaying the deterioration of at least one of each air conditioner, each component in each air conditioner, and one or more components in each air conditioner. For example, when the object is the compressor 12, the control patterns include lowering the frequency of the compressor 12, increasing the rotation speed of the outdoor fan 15B, and adjusting the opening of the outdoor flow control valve 16. In addition, when the object is the compressor 12, other control patterns include adjusting the timing of the determination process for the presence or absence of an abnormality in each component such as the compressor 12, which is executed when the air conditioner 101 is started.

Note that the control pattern that is effective in extending the life of the object may differ for each piece of extracted deterioration information. One or more control patterns are stored in the memory unit 80 in association with each piece of extracted deterioration information. For example, the memory unit 80 may store one control pattern for each piece of extracted deterioration information. Alternatively, the memory unit 80 may store one control pattern for each predetermined adjustment time range in the extracted deterioration information. In addition, the memory unit 80 may store one control pattern for each time point in the extracted deterioration information. The one control pattern is obtained through experiments or AI learning as something that extends the life of the object.

The storage unit 80 may store a plurality of control patterns for each piece of comparative deterioration information. Alternatively, the storage unit 80 may store a plurality of control patterns for each adjustment time range in each piece of comparative deterioration information. In addition, the storage unit 80 may store a plurality of control patterns for each time point in each piece of comparative deterioration information. In these cases, a larger weight may be associated with each of the plurality of control patterns as the deterioration progresses more slowly, based on experimental results obtained in advance or learning by AI. That is, a larger weight may be associated with each of the plurality of control patterns in the storage unit 80 as the life of each of the plurality of air conditioners, each of the plurality of parts in each of the plurality of air conditioners, or one or more parts among the plurality of parts is extended longer. The weight may be determined by experiment or learning by AI.

The control construction unit 83 constructs the control content of the air conditioner 101 based on at least one of the one or more control patterns that delay deterioration of the object stored in the storage unit 80. When multiple control patterns are stored in the storage unit 80 in the extracted deterioration information, the control construction unit 83 may construct the control content of the air conditioner 101 based on a randomly selected control pattern. In addition, when multiple control patterns are stored in the storage unit 80 in the extracted deterioration information and the weight is associated with each of the multiple control patterns, the control construction unit 83 may construct the control content based on the control pattern associated with the maximum weight. Alternatively, the control construction unit 83 may select two or more control patterns in descending order of the associated weight, and construct the control content based on the two or more control patterns.

When multiple control patterns are stored in the storage unit 80 for each adjustment time range, the control construction unit 83 may select the control pattern with the largest weight for each adjustment time range, or any control pattern. Alternatively, the control construction unit 83 may select two or more control patterns from the multiple control patterns for each adjustment time range in descending order of associated weight, or may select two or more arbitrary control patterns. The control construction unit 83 may then construct the control content of the air conditioner 101 for each adjustment time range based on the control pattern selected for each adjustment time range.

The control construction unit 83 can recognize which point in the extracted deterioration information the current point in time corresponds to, based on the current degree of deterioration of the object estimated by the deterioration estimation unit 81. In other words, the control construction unit 83 can recognize which point in the extracted deterioration information the current point in time corresponds to, by the extraction process of the extracted time range from the extracted deterioration information using the degree of deterioration performed by the life calculation unit 82.

When multiple control patterns are stored in the storage unit 80 for each time point in the extracted deterioration information, the control construction unit 83 may select the control pattern with the maximum weight for each time point, or an arbitrary control pattern. Alternatively, the control construction unit 83 may select two or more control patterns from the multiple control patterns for each time point in descending order of associated weights. Alternatively, the control construction unit 83 may select two or more arbitrary control patterns from the multiple control patterns for each time point. Then, the control construction unit 83 may construct the control content of the air conditioner 101 for each time point based on the control pattern selected for each time point.

The air conditioning control unit 84 controls the air conditioner 101 according to the control content constructed by the control construction unit 83. Next, the function of the air conditioning system 100 when control is being performed by the air conditioning control unit 84 will be described. Below, a case will be described in which multiple control patterns are associated in the memory unit 80 with each piece of extracted deterioration information, each time point in the extracted deterioration information, or each adjustment time range in the extracted deterioration information.

The deterioration estimation unit 81 in the first embodiment acquires all or part of the values of a plurality of operating parameters from the air conditioner 101 every time a predetermined correction time elapses while the air conditioning control unit 84 controls the air conditioner 101. The deterioration estimation unit 81 then estimates the degree of deterioration of the object based on all or part of the values of the plurality of operating parameters. Note that the correction time may be the same length as the acquisition time or the adjustment time range.

While the air conditioning control unit 84 controls the air conditioner 101, the control construction unit 83 determines whether the deterioration degree of the object at the current time estimated by the deterioration estimation unit 81 is smaller than the deterioration degree at the current time in the extracted deterioration information. If the deterioration degree of the object at the current time is equal to or greater than the deterioration degree at the current time in the extracted deterioration information, the control construction unit 83 selects a control pattern other than the control pattern used in the control content up to the current time and associated with the extracted deterioration information or the current time in the extracted deterioration information. Then, the control construction unit 83 constructs the control content based on the selected control pattern. In this case, if the control patterns in the storage unit 80 are weighted, the control construction unit 83 may make the weight of the control pattern used in the control content up to the current time smaller than the weight at the current time. Then, the control construction unit 83 may construct the control content using one control pattern associated with the maximum weight. Alternatively, the control construction unit 83 may construct the control content using two or more control patterns selected in descending order of weight. The air conditioning control unit 84 controls the air conditioner 101 in accordance with the control content constructed by the control construction unit 83 .

On the other hand, if the degree of deterioration of the object at the current time is less than the degree of deterioration at the current time in the extracted deterioration information, the control construction unit 83 instructs the air conditioning control unit 84 to continue to control the air conditioner 101 according to the control content at the current time. In this case, if the control patterns in the memory unit 80 are weighted, the control construction unit 83 may set the weight of the control pattern used in the control content up to the current time to be equal to or greater than the weight at the current time.

Fig. 6 is a diagram illustrating deterioration information when the life time of an object is extended by control according to the control content constructed by the control construction unit. In Fig. 6, it is assumed that control according to the control content is executed after time _t1 , and the deterioration information of the object after time _t1 is indicated by a dashed line H. As shown in Fig. 6, the life time of the object is extended by a further time _T2 from time _T1 by the control according to the control content. The failure time of the object is time _{t3 ,} which is time T2 after time _t2 .

Next, referring to FIG. 7, the detailed configuration of the air conditioning system 100 according to embodiment 1 will be described. FIG. 7 is a block diagram that illustrates a schematic example of the detailed configuration of the air conditioning system according to embodiment 1. The components in FIG. 7 that have been described with reference to FIG. 1 to FIG. 6 will not be described unless there are special circumstances. In embodiment 1, the memory unit 80, the deterioration estimation unit 81, the life calculation unit 82, and the control construction unit 83 are included in the server 9, and the air conditioning control unit 84 is included in the remote controller 5. The dashed arrows in FIG. 7 indicate where each of the units is included, and each of the units is included on the side facing the dashed arrow.

As described with reference to FIG. 2, the outdoor control device 11 is connected to each of the following multiple air conditioning sensors in the outdoor unit 1, and acquires detection results from each of the multiple air conditioning sensors. The multiple air conditioning sensors are the outdoor heat exchanger temperature sensor 19, the outdoor air temperature sensor 20, the discharge side pressure sensor 21, the suction side pressure sensor 22, and the discharge side temperature sensor 23 in FIG. 2. As described above, the outdoor control device 11 is an example of an air conditioning sensor, and detects the value of the current applied to the compressor 12 and the value of the power input to the compressor 12. The outdoor control device 11 controls the outdoor communication unit 10 to transmit the detection results of each of the multiple air conditioning sensors in the outdoor unit 1 to the indoor unit 3. The second indoor communication unit 31 receives the detection results of each of the multiple air conditioning sensors in the outdoor unit 1 from the outdoor unit 1.

The outdoor communication unit 10 may communicate with at least one of the remote controller 5, the terminal 7, and the server 9. In this case, the outdoor control device 11 may control the outdoor communication unit 10 to transmit the values of the operating parameters detected by the multiple air conditioning sensors in the outdoor unit 1 to a device among the remote controller 5, the terminal 7, and the server 9 with which it can communicate.

As explained with reference to FIG. 2, the indoor control device 32 is connected to multiple air conditioning sensors in the indoor unit 3 and acquires detection results from the multiple air conditioning sensors. The multiple air conditioning sensors in the indoor unit 3 are an indoor heat exchanger temperature sensor 36 and an indoor temperature sensor 37. The indoor control device 32 controls the first indoor communication unit 30 to transmit the detection results of each of the multiple air conditioning sensors in the indoor unit 3 to the remote controller 5. The indoor control device 32 also controls the first indoor communication unit 30 to transmit the detection results of each of the multiple air conditioning sensors in the outdoor unit 1, which the second indoor communication unit 31 has received from the outdoor unit 1, to the remote controller 5.

The first indoor communication unit 30 may communicate with at least one of the terminal 7 and the server 9. In this case, the indoor control device 32 may control the first indoor communication unit 30 to transmit the values of operating parameters detected by multiple air conditioning sensors in the outdoor unit 1 and the indoor unit 3 to a device capable of communicating with the terminal 7 or the server 9. The first indoor communication unit 30 is an example of an air conditioning communication unit.

The remote controller 5 includes a remote control communication unit 50, a remote air conditioning communication unit 51, a remote control device 52, an air conditioning operation unit 53, an air conditioning display unit 54, and an air conditioning memory unit 55. The remote control communication unit 50 communicates with the indoor unit 3. The remote control communication unit 50 may also communicate with the outdoor unit 1.

The remote air conditioning communication unit 51 communicates with the terminal 7 and the server 9. The remote air conditioning communication unit 51 is an example of an air conditioning communication unit. The remote control device 52 controls the remote control communication unit 50, the remote air conditioning communication unit 51, and the air conditioning display unit 54. The air conditioning operation unit 53 includes, for example, a hard button and accepts input of instructions from the user. The air conditioning display unit 54 is, for example, a liquid crystal display having a backlight. The backlight is a light source that irradiates the liquid crystal display from the side or back of the air conditioning display unit 54. The air conditioning display unit 54 displays various information on the screen according to instructions from the remote control device 52. The air conditioning memory unit 55 stores information necessary for the operation of the air conditioner 101, such as the set temperature set by the user. The above-mentioned air conditioning control unit 84 may be included in the remote control device 52.

The remote control communication unit 50 receives the values of multiple operating parameters detected by multiple air conditioning sensors in the outdoor unit 1 and the indoor unit 3 from the indoor unit 3 at each of the above-mentioned acquisition times. The remote control device 52 controls the remote air conditioning communication unit 51 to transmit the values of the multiple operating parameters received by the remote control communication unit 50 to the server 9.

The server 9 includes a server communication unit 90. The deterioration estimation unit 81 included in the server 9 estimates the degree of deterioration of the object as described above based on all or part of the values of multiple operating parameters acquired from the remote controller 5 via the server communication unit 90. Then, the life calculation unit 82 extracts extracted deterioration information based on the degree of deterioration as described above, and calculates the life time of the object. The control construction unit 83 constructs control content based on the extracted deterioration information as described above. The control construction unit 83 controls the server communication unit 90 to transmit a control signal indicating the control content to the remote controller 5.

The air conditioning control unit 84 in the remote controller 5 controls the outdoor unit 1 and the indoor unit 3 according to the control content indicated by the control signal received from the server 9. Specifically, the air conditioning control unit 84 controls the remote control communication unit 50 to transmit a control signal indicating the control content to the indoor unit 3. When the remote control communication unit 50 communicates with the outdoor unit 1, the air conditioning control unit 84 may control the remote control communication unit 50 to transmit a control signal to the outdoor unit 1.

When the first indoor communication unit 30 receives the control signal, if the control signal instructs control of a part in the indoor unit 3, the indoor control unit 32 controls the part. If the control signal instructs control of a part in the outdoor unit 1, the indoor control unit 32 controls the second indoor communication unit 31 to transmit the control signal to the outdoor unit 1.

When the first outdoor communication unit 10 receives the control signal, the outdoor control device 11 controls the compressor 12, the outdoor blower 15, the outdoor flow rate control valve 16, etc., in response to the control signal. When the control signal instructs a change in the frequency of the compressor 12, the outdoor control device 11 controls the frequency of the compressor 12 to change the frequency. When the control signal instructs a change in the rotation speed of the outdoor blower 15, the outdoor control device 11 controls the outdoor drive source 15A in the outdoor blower 15 to change the rotation speed. When the control signal instructs a change in the opening degree of the outdoor flow rate control valve 16, the outdoor control device 11 changes the opening degree of the outdoor flow rate control valve 16.

The life of the air conditioner 101 is extended by operating components in at least one of the outdoor unit 1 and the indoor unit 3 according to the control content constructed by the control construction unit 83.

While the air conditioner 101 is operating according to the control content, the remote control communication unit 50 of the remote controller 5 receives from the indoor unit 3 the values of multiple operating parameters detected by multiple air conditioning sensors in the outdoor unit 1 and the indoor unit 3 at each of the above-mentioned correction times. The remote control device 52 controls the remote air conditioning communication unit 51 to transmit the values of the multiple operating parameters received by the remote control communication unit 50 to the server 9.

The deterioration estimation unit 81 included in the server 9 estimates the degree of deterioration of the object as described above based on all or part of the values of multiple operating parameters acquired from the remote controller 5 via the server communication unit 90. The control construction unit 83 then determines whether the degree of deterioration is equal to or greater than the degree of deterioration indicated by the extracted deterioration information. Note that the extracted deterioration information is comparative deterioration information extracted by the life calculation unit 82 before the air conditioning control unit 84 performs control.

If the degree of deterioration estimated by the deterioration estimation unit 81 is equal to or greater than the degree of deterioration indicated by the extracted deterioration information, the control construction unit 83 reconstructs the control content. In this case, the control construction unit 83 constructs the control content using a control pattern other than the control pattern used in constructing the previous control content. The control construction unit 83 then controls the server communication unit 90 to transmit a control signal indicating the constructed control content to the remote controller 5. Since the operation of the air conditioner 101 is similar below, a description thereof will be omitted.

The air conditioning control unit 84 in the remote controller 5 may control the air conditioning display unit 54 to display the following control content information when the air conditioner 101 is operating based on the control content constructed by the control construction unit 83. The control content information includes at least one of information indicating that the control content is being executed, information indicating the control content, and the life time calculated by the life calculation unit 82. This allows the user of the air conditioner 101 to recognize the operating status of the air conditioner 101 or the life time of the air conditioner 101. In addition, when the control content information includes the life time, the life time may be calculated by the life calculation unit 82 before the air conditioning control unit 84 performs control. Alternatively, the life time may be calculated by the life calculation unit 82 for each correction time. In this case, the life calculation unit 82 extracts the extracted deterioration information as described above for each correction time based on the degree of deterioration estimated by the deterioration estimation unit 81 for each correction time, and calculates the life time.

The terminal 7 is used by a user of the air conditioner 101, or a maintenance company for the air conditioner 101, etc. The terminal 7 comprises a terminal communication unit 70, a terminal operation unit 71, a terminal control unit 72, and a terminal display unit 73. The terminal communication unit 70 communicates with the remote controller 5 and the server 9. The terminal operation unit 71 accepts input of instructions from the user of the terminal 7. The terminal control unit 72 controls the terminal communication unit 70 and the terminal display unit 73 based on instructions input to the terminal operation unit 71 or signals received by the terminal communication unit 70. The terminal display unit 73 displays various information on the screen in accordance with instructions from the terminal control unit 72.

When the air conditioner 101 is operating based on the control content constructed by the control construction unit 83, the air conditioning control unit 84 in the remote controller 5 may control the remote side air conditioning communication unit 51 to transmit the following command signal to the terminal 7. The command signal instructs the terminal display unit 73 to display the above control content information on the screen.

The terminal control unit 72 controls the terminal display unit 73 according to the command signal received by the terminal communication unit 70. The terminal display unit 73 displays control content information according to the instructions of the terminal control unit 72. This allows the user of the terminal 7 to recognize the operating status of the air conditioner 101, the life time of the air conditioner 101, etc.

Here, there is a risk that operation to extend the life of the air conditioner 101 or components in the air conditioner 101 may impair the comfort of the user of the air conditioner 101. In order to maintain user comfort, the air conditioning system 100 according to embodiment 1 further comprises the following components. Below, we will explain the air conditioning system 100 when it comprises these components.

2, the indoor unit 3 includes a human sensor 38, a left/right airflow direction control unit 39, a left/right airflow direction changing plate 40, an up/down airflow direction control unit 41, and an up/down airflow direction changing plate 42. The indoor control device 32 also includes a human body information management unit 44, an area management unit 45, an airflow direction control management unit 46, and an airflow volume control management unit 47.

The human presence sensor 38 includes, for example, an infrared sensor, and detects the temperature distribution in the room. The human presence sensor 38 outputs temperature distribution information, such as a thermal image, indicating the detected temperature distribution to the indoor control device 32. The human presence sensor 38 may be installed in the room separately from the indoor unit 3. In this case, the human presence sensor 38 communicates with the indoor unit 3 via wired or wireless communication, and transmits the temperature distribution information to the indoor unit 3.

As described above, the indoor drive source 34A and the indoor fan 34B control the amount of air blown out from the indoor unit 3. The left/right air direction control unit 39, the left/right air direction changing plate 40, the up/down air direction control unit 41, and the up/down air direction changing plate 42 control the direction of the air blown out from the indoor unit 3. Hereinafter, the indoor drive source 34A, the indoor fan 34B, the left/right air direction control unit 39, the left/right air direction changing plate 40, the up/down air direction control unit 41, and the up/down air direction changing plate 42 are referred to as the air blowing mechanism 43.

The human body information management unit 44 determines the presence or absence of a person in the room based on the temperature distribution information acquired from the human presence sensor 38. Furthermore, when a person is present in the room, the human body information management unit 44 identifies the position of the person in the room. The human body information management unit 44 stores information for identifying each position in the room, such as the coordinates of each position. For example, the human body information management unit 44 stores in advance a thermal image generated by the human presence sensor 38 when there is no person in the room as a reference thermal image. Then, the human body information management unit 44 calculates the temperature difference between the thermal image acquired from the human presence sensor 38 and the reference thermal image, and determines that a person is present in a position where the temperature difference is equal to or greater than a threshold value.

Based on the temperature distribution information when there is a person in the room, the human body information management unit 44 generates human position information including information indicating multiple areas into which the room is divided and information on the presence or absence of a person in each area. The human body information management unit 44 transmits the human position information to the remote controller 5 via the first indoor communication unit 30. When the remote control communication unit 50 receives the human position information, the remote side control device 52 in the remote controller 5 controls the remote side air conditioning communication unit 51 to transmit the human position information to the user's terminal 7. When the terminal communication unit 70 receives the human position information, the terminal control unit 72 controls the terminal display unit 73 to display the human position information. The user's terminal 7 in the first embodiment accepts input of instructions regarding the air conditioning content from the user who has confirmed the human position information. The remote side control device 52 may control the air conditioning display unit 54 to display the human position information.

When the first indoor communication unit 30 receives an operation signal from the remote controller 5 or the terminal 7 instructing the direction of air blown from the indoor unit 3, the area management unit 45 identifies the area to which the user wishes air to be blown based on the operation signal. The operation signal includes information indicating the area to which the user wishes air to be blown. Hereinafter, the area to which the user wishes air to be blown is referred to as an adjustment area.

The operation signal that indicates the direction of the air blown out from the indoor unit 3 may include information indicating the location to which the user wishes the air to be blown, such as the coordinates of the location, instead of the information indicating the area to which the user wishes the air to be blown. In this case, the area management unit 45 stores information that identifies each location, such as the coordinates of each location in the room, and information that associates each location with the area that includes that location.

When the area management unit 45 receives an operation signal for controlling the airflow from the indoor unit 3 from the remote controller 5 or the terminal 7, it identifies the airflow from the indoor unit 3 based on the operation signal. The airflow identified by the area management unit 45 is hereinafter referred to as the adjusted airflow. Furthermore, information including at least one of the adjusted area and the adjusted airflow is hereinafter referred to as the adjusted information.

The airflow direction control management unit 46 generates an airflow direction control signal for controlling the airflow direction from the indoor unit 3 based on the adjustment area identified by the area management unit 45. The airflow direction control management unit 46 outputs the generated airflow direction control signal to at least one of the left/right airflow direction control unit 39 and the up/down airflow direction control unit 41. The output destination of the airflow direction control signal is based on the adjustment area.

The air volume control management unit 47 generates an air volume control signal for controlling the air volume from the indoor unit 3 based on the adjusted air volume specified by the area management unit 45. The air volume control management unit 47 outputs the generated air volume control signal to the indoor drive source 34A.

The left-right wind direction control unit 39 and the up-down wind direction control unit 41 each include an actuator, and when a wind direction control signal is input, the left-right wind direction control unit 39 converts the wind direction control signal into physical movement. When a wind direction control signal is input, the left-right wind direction control unit 39 adjusts the orientation of the left-right wind direction change board 40 in response to the wind direction control signal. When a wind direction control signal is input, the up-down wind direction control unit 41 adjusts the orientation of the up-down wind direction change board 42 in response to the wind direction control signal. The left-right wind direction change board 40 is a plate-shaped unit that controls the wind direction in the left-right direction. The up-down wind direction change board 42 is a plate-shaped unit that controls the wind direction in the up-down direction. The left-right wind direction change board 40 and the up-down wind direction change board 42 are each examples of wind direction change boards. Furthermore, the left-right wind direction control unit 39 and the up-down wind direction control unit 41 are each examples of wind direction control units.

When an airflow control signal is input, the indoor driving source 34A drives the indoor fan 34B in accordance with the airflow control signal.

The airflow direction control management unit 46 transmits airflow direction information indicating the orientation of each of the left/right airflow direction vanes 40 and the up/down airflow direction vanes 42, or the airflow direction from the indoor unit 3, based on the airflow control signal, to the remote controller 5 via the first indoor communication unit 30. The airflow volume control management unit 47 transmits airflow information indicating the rotation speed of the indoor fan 34B, or the air volume by the indoor fan 34B, based on the airflow control signal, to the remote controller 5 via the first indoor communication unit 30.

In addition, instead of the wind direction information being transmitted by the wind direction control management unit 46 and the air volume information being transmitted by the air volume control management unit 47, the area management unit 45 may transmit adjustment information to the remote controller 5. The wind direction information, air volume information, and adjustment information are each examples of air blowing information indicating the air blowing contents from the indoor unit 3.

The remote control device 52 in the remote controller 5 has a person position information management unit 56, an operation management unit 57, and an adjustment area management unit 58. When the remote control communication unit 50 receives person position information from the indoor unit 3, the person position information management unit 56 stores the person position information in the air conditioning memory unit 55. The person position information management unit 56 controls the remote air conditioning communication unit 51 to transmit the person position information to the user's terminal 7. When the terminal communication unit 70 receives person position information from the remote controller 5, the terminal control unit 72 in the terminal 7 controls the terminal display unit 73 to display the person position information. The person position information management unit 56 may control the air conditioning display unit 54 to display the person position information.

The operation management unit 57 stores the contents of instructions regarding the set temperature or operation mode, etc., input via the air conditioning operation unit 53 in the air conditioning memory unit 55. The operation mode is, for example, a type of operation, such as cooling, heating, or dehumidification. The operation management unit 57 stores the contents of instructions indicated by the operation signal received from the terminal 7 in the air conditioning memory unit 55. The operation management unit 57 controls the remote control communication unit 50 to transmit the operation signal indicating the instruction input via the air conditioning operation unit 53 and the operation signal received from the terminal 7 to the indoor unit 3.

When the operation management unit 57 receives air-blowing information from the indoor unit 3, it controls the remote air-conditioning communication unit 51 to transmit the air-blowing information to the terminal 7. When the terminal communication unit 70 receives air-blowing information from the remote controller 5, the terminal control unit 72 in the terminal 7 controls the terminal display unit 73 to display the air-blowing information. When the remote control communication unit 50 receives air-blowing information from the indoor unit 3, the operation management unit 57 may control the air-conditioning display unit 54 to display the air-blowing information.

The adjustment area management unit 58 stores information indicating the adjustment area indicated by the instruction input via the air conditioning operation unit 53 and the adjustment air volume indicated by the instruction in the air conditioning memory unit 55. The air conditioning memory unit 55 stores information indicating the area in the room.

When the remote air conditioning communication unit 51 receives an operation signal from the terminal 7 instructing the air conditioning content, the adjustment area management unit 58 identifies the adjustment area from the operation signal. The operation signal may indicate a position, such as the coordinates of the position to which the user wishes to blow air, or may indicate an area to which the user wishes to blow air. When the operation signal indicates a position to which the user wishes to blow air, the air conditioning memory unit 55 stores information indicating each of the positions, such as the coordinates of each position in the room, in association with the area including each of the positions. The adjustment area management unit 58 then refers to the air conditioning memory unit 55 and identifies the adjustment area from the information indicating the position to which the user wishes to blow air.

The adjustment area management unit 58 stores the adjustment area and the adjusted air volume identified from the operation signal received from the terminal 7 in the air conditioning memory unit 55. The adjustment area management unit 58 also controls the remote control communication unit 50 to transmit an operation signal indicating the adjustment area and the adjusted air volume to the indoor unit 3.

With the above configuration, the air conditioner 101 ensures user comfort. There may be cases where the control content generated by the control construction unit 83 conflicts with the instructions input to the remote controller 5 or terminal 7. In this case, the air conditioning control unit 84 may instruct the control construction unit 83 in the server 9 via the remote air conditioning communication unit 51 to construct the control content using a control pattern other than the control pattern used in constructing the control content.

The following describes the hardware configuration of the air conditioning system 100 according to the first embodiment, other than the existing hardware configuration. The functions of the memory unit 80 can be realized by a storage device such as a hard disk drive (HDD). Each of the deterioration estimation unit 81, the life calculation unit 82, the control construction unit 83, and the air conditioning control unit 84 can be configured by a processor such as a central processing unit (CPU) or a micro processing unit (MPU), and a memory such as a read only memory (ROM) or a random access memory (RAM). The functions of the deterioration estimation unit 81, the life calculation unit 82, the control construction unit 83, and the air conditioning control unit 84 can be realized by the processor reading and executing the air conditioning program stored in the memory. Note that all or some of the functions of the memory unit 80, the deterioration estimation unit 81, the life calculation unit 82, the control construction unit 83, and the air conditioning control unit 84 may be realized by dedicated hardware. In addition, all or part of the functions of each of the memory unit 80, the deterioration estimation unit 81, the life calculation unit 82, the control construction unit 83, and the air conditioning control unit 84 may be realized by dedicated hardware.

Below, the flow of air conditioning processing by the air conditioning system 100 according to embodiment 1 will be described with reference to Figure 8. Figure 8 is a flowchart illustrating the flow of air conditioning processing by the air conditioning system according to embodiment 1. In step S1, the deterioration estimation unit 81 acquires values of all or part of a plurality of operating parameters, which are the current detection results by all or part of the plurality of air conditioning sensors.

In step S2, the deterioration estimation unit 81 refers to the memory unit 80 and acquires all or part of the values of a plurality of comparison parameters of the comparison air conditioner based on at least one of the values of the capacity parameter and the value of the environmental parameter. In step S3, the deterioration estimation unit 81 compares all or part of the values of the plurality of operating parameters acquired in step S1 with all or part of the values of the plurality of comparison parameters of the comparison air conditioner, and estimates the degree of deterioration of the object. When the object is an air conditioner 101, the deterioration estimation unit 81 may estimate the degree of deterioration of the air conditioner 101 based on the degree of deterioration of each of a plurality of parts of the air conditioner 101.

In step S4, the deterioration estimation unit 81 generates deterioration information indicating the estimated deterioration degree in a time series. The deterioration information is obtained, for example, by the deterioration estimation unit 81 accumulating the deterioration degree at each time point and storing it in the memory unit 80.

In step S5, the deterioration estimation unit 81 determines whether the entire time range indicated by the deterioration information generated in step S4 is equal to or greater than the comparison time range. If the entire time range indicated by the deterioration information is less than the comparison time range (step S5: NO), in step S6, the deterioration estimation unit 81 determines whether the acquisition time has elapsed since the values of all or part of the above-mentioned multiple operating parameters were acquired in step S1. If the acquisition time has not elapsed (step S6: NO), the deterioration estimation unit 81 keeps the air conditioning process in step S6. If the acquisition time has elapsed (step S6: YES), the deterioration estimation unit 81 returns the air conditioning process to step S1. If the entire time range indicated by the deterioration information is equal to or greater than the comparison time range (step S5: YES), the deterioration estimation unit 81 moves the air conditioning process to step S7.

The processing of step S6 in embodiment 1 is processing in the case where the deterioration estimation unit 81 requests the air conditioner 101 to transmit all or some of the values of the above-mentioned multiple operating parameters, for example via the server communication unit 90. If the values of the multiple parameters are automatically transmitted from the air conditioner 101 to the deterioration estimation unit 81 every time the acquisition time elapses, the processing of step S6 may not be required. In this case, if the time range indicated by the deterioration information in step S5 is less than the matching time range, the deterioration estimation unit 81 returns the processing to step S1, and if the time range is equal to or greater than the matching time range, the deterioration estimation unit 81 transfers the processing to step S7.

In step S7, the life calculation unit 82 refers to the memory unit 80 and acquires one or more pieces of comparative deterioration information of the comparison air conditioner. In step S8, the life calculation unit 82 extracts a selected time range and extracted deterioration information from the one or more pieces of comparative deterioration information acquired in step S7. In this case, the life calculation unit 82 compares the degree of deterioration at each point in the comparison time range in the deterioration information generated by the deterioration estimation unit 81 in step S4 with the degree of deterioration at each point in the comparison time range in the one or more pieces of comparative deterioration information acquired in step S7. Then, the life calculation unit 82 extracts a selected time range and extracted deterioration information from the one or more pieces of comparative deterioration information based on the comparison result.

In step S9, the life calculation unit 82 calculates the life time of the object using the extracted deterioration information. In step S10, the control construction unit 83 selects at least one control pattern from one or more control patterns associated with the extracted deterioration information, each time point in the extracted deterioration information, or each adjustment time range in the extracted deterioration information in the storage unit 80. Note that here, it is assumed that multiple control patterns are associated with the extracted deterioration information, each time point in the extracted deterioration information, or each adjustment time range in the extracted deterioration information in the storage unit 80. The control construction unit 83 selects one control pattern or two or more control patterns from the multiple control patterns. When selecting one control pattern, the control construction unit 83 selects, for example, one control pattern associated with the maximum weight in the storage unit 80. When selecting two or more control patterns, the control construction unit 83 selects the two or more control patterns in descending order of weight in the storage unit 80, for example.

In step S11, the control construction unit 83 constructs control content based on at least one control pattern selected in step S10. In step S12, the control construction unit 83 instructs the air conditioning control unit 84 to control the air conditioner 101 based on the constructed control content. The air conditioning control unit 84 controls the air conditioner 101 based on the control content constructed by the control construction unit 83.

In step S13, the deterioration estimation unit 81 determines whether the correction time has elapsed. If the correction time has not elapsed (step S13: NO), the deterioration estimation unit 81 returns the air conditioning process to step S13. If the correction time has elapsed (step S13: YES), in step S14, the deterioration estimation unit 81 acquires all or part of the values of the multiple operating parameters at the current time.

In step S15, the deterioration estimation unit 81 estimates the deterioration degree of the object based on all or part of the values of the multiple operating parameters and all or part of the values of the multiple comparison parameters of the comparison air conditioner acquired in step S14. In step S16, the control construction unit 83 determines whether the deterioration degree estimated by the deterioration estimation unit 81 in step S15 is equal to or greater than the current deterioration degree in the extracted deterioration information extracted in step S8. If the deterioration degree estimated by the deterioration estimation unit 81 is less than the current deterioration degree in the extracted deterioration information (step S16: NO), the control construction unit 83 returns the air conditioning process to step S12. In step S12, the control construction unit 83 does not need to instruct the air conditioning control unit 84 if the air conditioning control unit 84 continues to perform the process up to the current time in the absence of an instruction from the control construction unit 83.

If the degree of deterioration estimated by the deterioration estimation unit 81 is equal to or greater than the current degree of deterioration in the extracted deterioration information (step S16: YES), in step S17, the control construction unit 83 selects at least one control pattern other than the control pattern selected immediately before. In step S18, the control construction unit 83 constructs control content based on the at least one control pattern selected in step S17. In this case, if the control pattern is weighted in the storage unit 80, the control construction unit 83 may reduce the weight associated with the control pattern selected immediately before. Then, the control construction unit 83 may select at least one control pattern other than the control pattern selected immediately before according to the magnitude of the weight. After the process of step S18, the control construction unit 83 returns the air conditioning process to step S12. Note that, when the air conditioner 101 stops operation based on the above control content and then resumes operation, the air conditioning system 100 may perform the air conditioning process from step S1 or may perform the process from step S12.

The effects of the air conditioning system 100 according to the first embodiment will be described below. The air conditioning system 100 according to the first embodiment includes an air conditioner 101, a plurality of air conditioning sensors, a memory unit 80, a deterioration estimation unit 81, a life calculation unit 82, a control construction unit 83, and an air conditioning control unit 84. The air conditioner 101 performs indoor air conditioning. The plurality of air conditioning sensors detect the values of a plurality of operating parameters indicating the operating state of the air conditioner 101. The memory unit 80 stores the values of a plurality of comparison parameters indicating the operating state of each of the plurality of air conditioners, including a comparison air conditioner under the same conditions as the air conditioner 101. The memory unit 80 also stores each of a plurality of pieces of comparison deterioration information indicating, in a time series, at least one of the deterioration degree of each of the plurality of air conditioners, the deterioration degree of each of the plurality of parts in each of the plurality of air conditioners, and the deterioration degree of two or more parts among the plurality of parts in each of the plurality of air conditioners, based on the values of the plurality of comparison parameters. The deterioration estimation unit 81 estimates the deterioration degree of the air conditioner 101 or the object, which is one or more of the parts of the air conditioner 101, based on all or part of the values of the multiple operating parameters and all or part of the values of the multiple comparison parameters. The life calculation unit 82 extracts extracted deterioration information from the multiple comparison deterioration information stored in the storage unit 80 based on the time-series deterioration degree in the collation time range estimated by the deterioration estimation unit 81. Then, the life calculation unit 82 uses the extracted deterioration information to calculate the life time from the current time to the time of failure of the object. The control construction unit 83 constructs control contents for extending the life time calculated by the life calculation unit 82 based on the extracted deterioration information extracted by the life calculation unit 82. The air conditioning control unit 84 controls the air conditioner 101 based on the control contents constructed by the control construction unit 83.

According to the above configuration, the deterioration estimation unit 81 estimates the deterioration degree of the object, and the life calculation unit 82 extracts extracted deterioration information based on the deterioration degree in time series, so that the air conditioning system 100 can obtain information on how the deterioration of the object progresses. Then, the control construction unit 83 uses the extracted deterioration information to construct control content for extending the life time of the object, and the air conditioning control unit 84 controls the air conditioner 101 according to the control content, so that the air conditioning system 100 can extend the life of the air conditioner 101 while maintaining its operation.

The deterioration estimation unit 81 in the first embodiment extracts all or part of the values of multiple contrast parameters of the comparison air conditioner from the values of all comparison parameters indicating the operating states of the multiple air conditioners. The deterioration estimation unit 81 then estimates the degree of deterioration of the object based on all or part of the values of the multiple contrast parameters extracted and all or part of the values of the multiple operating parameters. This allows the deterioration estimation unit 81 to reduce the amount of degradation degree estimation processing.

In the first embodiment, when the target object is an air conditioner 101, the deterioration estimation unit 81 estimates the degree of deterioration of the air conditioner 101 based on the degree of deterioration of each of a plurality of parts in the air conditioner 101. Since the air conditioner 101 is made up of a plurality of parts, the deterioration estimation unit 81 estimates the degree of deterioration of the air conditioner 101 using the degree of deterioration of each of the plurality of parts, thereby improving the accuracy of estimating the degree of deterioration of the air conditioner 101.

In the first embodiment, the life calculation unit 82 compares one or more pieces of comparative deterioration information indicating the deterioration degree of one of the plurality of air conditioners and the plurality of parts in each of the plurality of air conditioners corresponding to the object in a time series with the deterioration degree of the object at each of the plurality of time points in the comparison time range estimated by the deterioration estimation unit 81. Based on the comparison result, the life calculation unit 82 extracts extracted deterioration information from the one or more pieces of comparative deterioration information. Then, the life calculation unit 82 predicts the time of failure of the object using the extracted deterioration information, and calculates the life time based on the time of failure and the current time. As a result, the life calculation unit 82 can accurately extract extracted deterioration information by comparing the one or more pieces of comparative deterioration information with the deterioration degree of the object at each of the plurality of time points. Then, the control construction unit 83 constructs the control contents of the air conditioner 101 based on the extracted deterioration information, so that the life of the air conditioner 101 can be extended.

The life calculation unit 82 in the first embodiment extracts extracted deterioration information from one or more pieces of comparison deterioration information that indicate, in a time series, the degree of deterioration of the comparison air conditioner and any of the plurality of parts in the comparison air conditioner that correspond to the target object. This allows the life calculation unit 82 to reduce the amount of processing when extracting the extracted deterioration information.

In the first embodiment, the storage unit 80 stores one or more control patterns for slowing deterioration of each of the multiple air conditioners or each of the multiple parts in each of the multiple air conditioners, in association with each of the multiple pieces of comparative deterioration information. The control construction unit 83 constructs control content using at least one of the one or more control patterns associated with the extracted deterioration information. This allows the control construction unit 83 to quickly construct control content that slows deterioration of the target object.

The storage unit 80 in the first embodiment stores two or more pieces of comparative deterioration information, or one piece of comparative deterioration information, among the plurality of pieces of comparative deterioration information indicating the deterioration degree of the plurality of air conditioners and any of the plurality of parts in each of the plurality of air conditioners in a time series, in association with a plurality of control patterns for delaying deterioration of the plurality of air conditioners and any of the plurality of parts in each of the plurality of air conditioners. The storage unit 80 also stores a weight associated with each of the plurality of control patterns. The weight associated with each of the plurality of control patterns is larger the longer the life of the plurality of air conditioners and any of the plurality of parts in each of the plurality of air conditioners. When a plurality of control patterns are associated with the extracted deterioration information, the control construction unit 83 selects at least one control pattern from the plurality of control patterns in descending order of the associated weight. This allows the control construction unit 83 to quickly and easily construct control content that extends the life of the air conditioner 101. Therefore, the control construction unit 83 can reduce the amount of processing, and the air conditioning control unit 84 can operate the air conditioner 101 while extending the life of the air conditioner 101.

The weights in the first embodiment are determined by learning using artificial intelligence. This allows the control construction unit 83 to construct control content that maximizes the lifespan of the air conditioner 101. Therefore, the air conditioning control unit 84 can operate the air conditioner 101 while maximizing the lifespan of the air conditioner 101.

The deterioration estimation unit 81 in the first embodiment estimates the deterioration degree of the object based on all or part of the values of the multiple operating parameters of the air conditioner 101 detected at a time point after the lapse of a predetermined correction time from the start of operation of the air conditioner 101 according to the control content constructed by the control construction unit 83. When the deterioration degree estimated by the deterioration estimation unit 81 is equal to or greater than the deterioration degree at a time point after the lapse of the correction time in the extracted deterioration information, and when multiple control patterns are associated with the extracted deterioration information, the control construction unit 83 reduces the weight associated with at least one control pattern used when constructing the control content. Then, the control construction unit 83 constructs the control content using at least one control pattern out of the multiple control patterns other than the at least one control pattern used when constructing the control content. As a result, when the constructed control content does not extend the life of the air conditioner 101, the control construction unit 83 can reconstruct the control content using another control pattern for extending the life. Therefore, the life of the air conditioner 101 can be reliably extended.

The deterioration estimation unit 81 in the first embodiment estimates the deterioration degree of the object based on all or part of the values of the multiple operating parameters of the air conditioner 101 detected at a time point after a predetermined correction time has elapsed from the start of operation of the air conditioner 101 according to the control content constructed by the control construction unit 83. When the deterioration degree estimated by the deterioration estimation unit 81 is equal to or greater than the deterioration degree at a time point after the correction time has elapsed in the extracted deterioration information, and when multiple control patterns are associated with the extracted deterioration information, the control construction unit 83 constructs the control content using at least one control pattern among the multiple control patterns other than the at least one control pattern used when constructing the control content. As a result, when the constructed control content does not extend the life of the air conditioner 101, the control construction unit 83 can reconstruct the control content using another control pattern to extend the life. Therefore, the life of the air conditioner 101 can be reliably extended.

The air conditioner 101 in the first embodiment circulates the refrigerant through the refrigerant circuit 6 and exchanges heat between the refrigerant and the indoor and outdoor air to condition the room. The air conditioner 101 has a compressor 12, an expansion valve, and a blower. The compressor 12 is provided in the refrigerant circuit 6 and compresses and discharges the refrigerant. The expansion valve is provided in the refrigerant circuit 6 and reduces the pressure of the refrigerant. The blower sends out the air after heat exchange to the room or the outside. Any of the one or more control patterns is a change control of the frequency of the compressor 12, a change control of the air volume of the blower, or a change control of the opening degree of the expansion valve. This allows the control construction unit 83 to construct control content that delays deterioration of the compressor 12, which is prone to deterioration.

The comparison air conditioner in the first embodiment satisfies at least one of the following: the difference between the capacity parameter value of the comparison air conditioner and the capacity parameter value of the air conditioner 101 is equal to or less than the capacity threshold value, and the difference between the environmental parameter value of the comparison air conditioner and the environmental parameter value of the air conditioner 101 is equal to or less than the environmental threshold value. Therefore, the accuracy of the estimation of the deterioration degree of the object by the deterioration estimation unit 81 using all or a part of the multiple comparison parameters of the comparison air conditioner is improved. In addition, the life calculation unit 82 can use the deterioration degree estimated by the deterioration estimation unit 81 to extract extracted deterioration information that accurately indicates the time change of the deterioration of the object from one or more pieces of comparison deterioration information that indicate the deterioration degree of the comparison air conditioner and one of the multiple parts of the comparison air conditioner that corresponds to the object in a time series. The control construction unit 83 can use the extracted deterioration information to construct control contents that reliably extend the life of the air conditioner 101.

The air conditioner 101 in the first embodiment circulates the refrigerant through the refrigerant circuit 6 and exchanges heat between the refrigerant and the air inside and outside the room to perform air conditioning of the room. The air conditioner 101 has a compressor 12. The compressor 12 is provided in the refrigerant circuit 6 and compresses and discharges the refrigerant. The comparison air conditioner satisfies at least one of the following: the difference between the value of the performance parameter of the comparison air conditioner and the value of the performance parameter of the air conditioner 101 is equal to or less than the performance threshold, and the difference between the value of the environmental parameter of the comparison air conditioner and the value of the environmental parameter of the air conditioner 101 is equal to or less than the environmental threshold. The value of the capacity parameter is determined by the refrigeration capacity, the information indicating the model or specifications, the model number, the set power value input to the compressor at the beginning of use of the compressor, or the set current value flowing through the compressor at the beginning of use of the compressor. The environmental parameter values are determined by the installation location of the air conditioner, the temperature at the installation location, the weather at the installation location, the cumulative usage time of the air conditioner, the average number of people in the room, the amount of refrigerant contained in the air conditioner, the length of the refrigerant piping, the time average or cumulative value of the power value input to the compressor, or the time average or cumulative value of the current value applied to the compressor. Therefore, the deterioration estimation unit 81 improves the estimation accuracy of the deterioration degree of the object using all or a part of the multiple comparison parameters of the comparison air conditioner. In addition, the life calculation unit 82 can use the deterioration degree estimated by the deterioration estimation unit 81 to extract extracted deterioration information that accurately indicates the time change of the deterioration of the object from one or more pieces of comparison deterioration information that indicate the deterioration degree of the comparison air conditioner and one of the multiple parts of the comparison air conditioner that corresponds to the object in a time series. The control construction unit 83 can use the extracted deterioration information to construct control content that reliably extends the life of the air conditioner 101.

In the first embodiment, one of the multiple operating parameters is the power input to the compressor 12 or the current applied to the compressor 12. This allows the deterioration estimation unit 81 to accurately estimate the degree of deterioration of the compressor 12.

The air conditioner 101 in the first embodiment further includes a remote controller 5 for remotely controlling the air conditioner 101. When the air conditioner 101 is operating based on the control content constructed by the control construction unit 83, the remote controller 5 displays at least one of information indicating that the control content is being executed, information indicating the control content, and the life time on the screen. This allows the user of the air conditioner 101 to know that the deterioration of the air conditioner 101 is progressing, that the air conditioner 101 is executing a process to slow down the progression of the deterioration, or the contents of the process. Therefore, the user can clearly understand the state of the air conditioner 101 and recognize the timing of contacting the maintenance company, thereby improving convenience.

In the air conditioning system 100 of the first embodiment, a memory unit 80, a deterioration estimation unit 81, a life calculation unit 82, and a control construction unit 83 are provided in a server 9 on a network 2, and an air conditioning control unit 84 is provided in an air conditioner 101. The air conditioner 101 has an air conditioning communication unit that communicates with the server 9. The air conditioning communication unit receives a control signal from the server 9 indicating the control content constructed by the control construction unit 83. This enables the air conditioning system 100 to reduce the processing volume of the air conditioner 101, to continue the operation of the air conditioner 101, and to extend the life of the air conditioner 101.

The air conditioning communication unit in the first embodiment communicates with the terminal 7 having a communication function. When the air conditioner 101 is operating based on the control content constructed by the control construction unit 83, the air conditioning control unit 84 controls the air conditioning communication unit to transmit a command signal to the terminal 7 instructing it to display on the screen at least one of information indicating that the control content is being executed, information indicating the control content, and the life time. In this way, when the user of the terminal 7 is a maintenance person, the air conditioning system 100 can inform the maintenance person that the air conditioner 101 needs maintenance, or the time when maintenance will be required. Therefore, the maintenance person can quickly perform maintenance before the air conditioner 101 breaks down, and can maintain the comfort of the user. In the case where the user of the terminal 7 is a user of the air conditioner 101, the air conditioning system 100 can inform the user that the air conditioner 101 is deteriorating, that the air conditioner 101 is performing a process to delay the progression of the deterioration, or the contents of the process. Therefore, the user can clearly understand the status of the air conditioner 101 and recognize the timing to contact a maintenance company, thereby improving convenience.

Embodiment 2.
In the above-mentioned first embodiment, the memory unit 80, the deterioration estimation unit 81, the life calculation unit 82, and the control construction unit 83 are included in the server 9, and the air conditioning control unit 84 is included in the remote controller 5. In the second embodiment, the memory unit 80 is included in the server 9, and the deterioration estimation unit 81, the life calculation unit 82, the control construction unit 83, and the air conditioning control unit 84 are included in the remote controller 5. An air conditioning system 100 according to the second embodiment will be described below.

An example configuration of the air conditioning system 100 according to embodiment 2 is shown in FIG. 1, as in embodiment 1, and an example configuration of the air conditioner 101 in embodiment 2 is shown in FIG. 2, as in embodiment 1. Furthermore, the functions of the air conditioning system 100 according to embodiment 2 are illustrated in FIG. 3, as in embodiment 1. In the following, components similar to those in embodiment 1 and functional blocks similar to those in embodiment 1 are given the same reference numerals as those in embodiment 1. Furthermore, unless there are special circumstances, explanations of the same contents as those in embodiment 1 will be omitted.

Figure 9 is a block diagram illustrating a schematic example of a detailed configuration of an air conditioning system according to embodiment 2. In embodiment 2, the memory unit 80 is included in the server 9, and the deterioration estimation unit 81, life calculation unit 82, control construction unit 83, and air conditioning control unit 84 are included in the remote controller 5. The dashed arrows in Figure 9 indicate where each of the units is included, and each unit is included on the side facing the dashed arrow.

All or part of the deterioration estimation unit 81, life calculation unit 82, control construction unit 83, and air conditioning control unit 84 may be included in the remote control device 52. The deterioration estimation unit 81 receives the values of multiple operating parameters detected by multiple air conditioning sensors in the outdoor unit 1 and the indoor unit 3 from the indoor unit 3 via the remote control communication unit 50. The deterioration estimation unit 81 may receive the values of multiple operating parameters detected by multiple air conditioning sensors in the outdoor unit 1 from the outdoor unit 1, and may receive the values of multiple operating parameters detected by multiple air conditioning sensors in the indoor unit 3 from the indoor unit 3.

The deterioration estimation unit 81 controls the remote side air conditioning communication unit 51 to send a first request signal requesting multiple comparison parameters indicating the operating state of the comparison air conditioner to the server 9. The first request signal includes at least one of the capacity parameter value and the environmental parameter value of the air conditioner 101. Based on the first request signal, the server 9 refers to the memory unit 80 and extracts the values of the multiple comparison parameters indicating the operating state of the comparison air conditioner. The server 9 then transmits the extracted values of the multiple comparison parameters of the comparison air conditioner to the remote controller 5 via the server communication unit 90.

The deterioration estimation unit 81 estimates the deterioration degree of the object based on all or part of the values of the multiple operating parameters received from the indoor unit 3 and all or part of the values of the multiple comparison parameters of the comparison air conditioner received from the server 9. When the estimation of the deterioration degree of the object is performed based on some values of the multiple operating parameters and some values of the multiple comparison parameters of the comparison air conditioner, the deterioration estimation unit 81 may receive the values of the part of the operating parameters from the indoor unit 3. In this case, the deterioration estimation unit 81 controls the remote side air conditioning communication unit 51 to transmit a first request signal requesting the values of the part of the multiple comparison parameters of the comparison air conditioner to the server 9. In response to the first request signal, the server 9 transmits the values of the part of the multiple comparison parameters of the comparison air conditioner to the remote controller 5 via the server communication unit 90.

The deterioration estimation unit 81 may control the remote side air conditioning communication unit 51 to transmit a first request signal to the server 9 requesting values of all or part of the multiple comparison parameters indicating the operating state of each of the multiple air conditioners. In this case, the server 9 transmits all or part of the values of the multiple comparison parameters of each of the multiple air conditioners to the remote controller 5 via the server communication unit 90 in response to the first request signal. The deterioration estimation unit 81 acquires all or part of the values of the multiple comparison parameters of the comparison air conditioner from the received values of all the comparison parameters based on at least one of the capacity parameter value and the environmental parameter value of the air conditioner 101.

The life calculation unit 82 controls the remote side air conditioning communication unit 51 to transmit to the server 9 a second request signal requesting one or more pieces of comparative deterioration information indicating, in a time series, the degree of deterioration of the comparative air conditioner and any of the multiple parts in the comparative air conditioner that correspond to the target object. The second request signal may be transmitted to the server 9 together with the first request signal, or may be transmitted to the server 9 separately from the first request signal. When the second request signal is transmitted to the server 9 separately from the first request signal, the second request signal includes at least one of the values of the above-mentioned performance parameters and the values of the environmental parameters. The server 9 refers to the storage unit 80 based on the second request signal, extracts the one or more pieces of comparative deterioration information, and transmits the extracted one or more pieces of comparative deterioration information to the remote controller 5 via the server communication unit 90.

The lifespan calculation unit 82 extracts extracted deterioration information from one or more comparison deterioration information received from the server 9 based on the deterioration information generated by the deterioration estimation unit 81 and the degree of deterioration of the object at each point in time within the matching time range.

In addition, the life calculation unit 82 may control the remote side air conditioning communication unit 51 to transmit a second request signal requesting multiple pieces of comparative deterioration information indicating the deterioration degree of the multiple air conditioners and the multiple parts in each of the multiple air conditioners in a time series. The server 9 transmits to the remote controller 5 multiple pieces of comparative deterioration information indicating the deterioration degree of the multiple air conditioners and the multiple parts in each of the multiple air conditioners in a time series based on the received second request signal. The life calculation unit 82 may control the remote side air conditioning communication unit 51 to transmit a second request signal requesting one or more pieces of comparative deterioration information indicating, in a time series, the deterioration degree of any of the multiple air conditioners and the multiple parts in each of the multiple air conditioners corresponding to the target object. The server 9 transmits to the remote controller 5 the one or more pieces of comparative deterioration information based on the received second request signal.

The control construction unit 83 controls the remote side air conditioning communication unit 51 to transmit to the server 9 a third request signal requesting one or more control patterns associated with the extracted deterioration information extracted by the life calculation unit 82. The third request signal includes the extracted deterioration information extracted by the life calculation unit 82 or information identifying the extracted deterioration information. The server 9 refers to the storage unit 80 and extracts the one or more control patterns based on the third request signal. The server 9 then transmits information indicating the one or more control patterns to the remote controller 5 via the server communication unit 90. Note that, if a weight is associated with each control pattern in the storage unit 80, the server 9 transmits the weight associated with the one or more control patterns together with the one or more control patterns to the remote controller 5. The control construction unit 83 constructs control content based on at least one control pattern among the one or more control patterns received from the server 9 via the remote side air conditioning communication unit 51.

The air conditioning control unit 84 in the second embodiment may control the air conditioning display unit 54 to display control content information on a screen when the air conditioner 101 is operating based on the control content constructed by the control construction unit 83. The air conditioning control unit 84 may also control the remote air conditioning communication unit 51 to send a command signal to the terminal 7 instructing it to display the control content information on a screen. When the terminal communication unit 70 receives the command signal, the terminal control unit 72 controls the terminal display unit 73 to display at least one of information indicating that the control content is being executed, information indicating the control content, and the life time of the object on the screen.

The flow of the air conditioning process by the air conditioning system 100 according to embodiment 2 is illustrated in FIG. 8, as in embodiment 1. The contents of the air conditioning process other than the following are the same as those of embodiment 1, and therefore will not be described. In embodiment 2, in step S2, the deterioration estimation unit 81 controls the remote side air conditioning communication unit 51 to send a first request signal to the server 9, instead of referring to the memory unit 80. The deterioration estimation unit 81 then acquires all or part of the values of multiple comparison parameters of the comparison air conditioner from the server 9 via the remote side air conditioning communication unit 51.

The process of step S6 in the second embodiment is a process in which the deterioration estimation unit 81 requests all or some of the values of a plurality of operating parameters from the indoor unit 3 via the remote control communication unit 50. The process of step S6 may be omitted if all or some of the values of the plurality of parameters are automatically transmitted from the indoor unit 3 to the remote controller 5 every time the acquisition time elapses.

In the second embodiment, in step S7, the life calculation unit 82 controls the remote side air conditioning communication unit 51 to send a second request signal to the server 9 instead of referring to the memory unit 80. Then, the life calculation unit 82 acquires one or more pieces of comparative deterioration information from the server 9 via the remote side air conditioning communication unit 51. In the second embodiment, in step S10, the control construction unit 83 controls the remote side air conditioning communication unit 51 to send a third request signal to the server 9 instead of referring to the memory unit 80. The control construction unit 83 acquires from the server 9 via the remote side air conditioning communication unit 51 the extracted deterioration information, each time point in the extracted deterioration information, or a plurality of control patterns associated with each adjustment time range in the extracted deterioration information. The control construction unit 83 selects at least one control pattern from the plurality of control patterns.

The deterioration estimation unit 81, the life calculation unit 82, the control construction unit 83, and the air conditioning control unit 84 may be included in the indoor unit 3 instead of the remote controller 5. In this case, the first indoor communication unit 30 may communicate directly with the server 9 and the terminal 7, or may communicate with the server 9 and the terminal 7 via the remote controller 5.

The effects of the air conditioning system 100 according to the second embodiment will be described below. The air conditioning system 100 according to the second embodiment includes a memory unit 80 in a server 9 on a network 2. The air conditioning system 100 also includes a deterioration estimation unit 81, a life calculation unit 82, a control construction unit 83, and an air conditioning control unit 84 in an air conditioner 101. The air conditioner 101 has an air conditioning communication unit that communicates with the server 9. The deterioration estimation unit 81 controls the air conditioning communication unit to transmit to the server 9 a first request signal requesting all or part of the values of a plurality of comparison parameters that indicate the operating state of the comparison air conditioner stored in the memory unit 80. The life calculation unit 82 controls the air conditioning communication unit to transmit to the server 9 a second request signal requesting one or more pieces of comparison deterioration information that indicate, in a time series, the deterioration degree of the comparison air conditioner and any of the plurality of parts in the comparison air conditioner that correspond to the target object. The control construction unit 83 controls the air conditioning communication unit to transmit a third request signal requesting one or more control patterns associated with the extracted deterioration information extracted by the life calculation unit 82 in the memory unit 80. This allows the air conditioner 101 to acquire a portion of a large amount of information stored in the server 9, such as the values of multiple comparison parameters of each of the multiple air conditioners and multiple pieces of comparison deterioration information, and to construct control content for life extension. This reduces the amount of data in the air conditioner 101. Furthermore, the air conditioner 101 can quickly reflect the constructed control content.

Embodiment 3.
In the above-mentioned second embodiment, the memory unit 80 is included in the server 9, and the deterioration estimation unit 81, the life calculation unit 82, the control construction unit 83, and the air conditioning control unit 84 are included in the remote controller 5. In the third embodiment, the memory unit 80 is included in the server 9, the deterioration estimation unit 81, the life calculation unit 82, and the control construction unit 83 are included in the terminal 7, and the air conditioning control unit 84 is included in the remote controller 5. An air conditioning system 100 according to the third embodiment will be described below.

An example of the configuration of the air conditioning system 100 according to embodiment 3 is shown in FIG. 1, as in embodiments 1 and 2, and an example of the configuration of the air conditioner 101 in embodiment 3 is shown in FIG. 2, as in embodiments 1 and 2. In addition, the functions of the air conditioning system 100 according to embodiment 3 are illustrated in FIG. 3, as in embodiments 1 and 2. In the following, the same reference numerals as in embodiments 1 and 2 are used for components similar to those in embodiments 1 and 2, and functional blocks similar to those in embodiments 1 and 2. In addition, unless there are special circumstances, explanations of the same contents as those in embodiments 1 and 2 will be omitted.

Figure 10 is a block diagram illustrating a schematic example of a detailed configuration of an air conditioning system according to embodiment 3. In embodiment 3, the memory unit 80 is included in the server 9, the deterioration estimation unit 81, the life calculation unit 82, and the control construction unit 83 are included in the terminal 7, and the air conditioning control unit 84 is included in the remote controller 5. The dashed arrows in Figure 10 indicate where each of the units is included, and each unit is included on the side facing the dashed arrow.

All or part of the deterioration estimation unit 81, the life calculation unit 82, and the control construction unit 83 may be included in the terminal control unit 72. The air conditioning control unit 84 may be included in the remote control device 52.

The deterioration estimation unit 81 receives all or part of the values of the multiple operating parameters detected by all or part of the multiple air conditioning sensors in the outdoor unit 1 and the indoor unit 3 from the remote controller 5 via the terminal communication unit 70. The deterioration estimation unit 81 controls the terminal communication unit 70 to transmit a first request signal requesting all or part of the multiple comparison parameters indicating the operating state of the comparison air conditioner to the server 9. Based on the first request signal, the server 9 refers to the memory unit 80 and extracts all or part of the values of the multiple comparison parameters indicating the operating state of the comparison air conditioner. The server 9 then transmits all or part of the values of the multiple comparison parameters of the comparison air conditioner that have been extracted to the terminal 7 via the server communication unit 90.

The deterioration estimation unit 81 estimates the degree of deterioration of the object based on all or part of the values of multiple operating parameters received from the remote controller 5 and all or part of the values of multiple comparison parameters of the comparison air conditioner received from the server 9.

The deterioration estimation unit 81 may control the terminal communication unit 70 to transmit a first request signal to the server 9, requesting values of all or part of the multiple comparison parameters indicating the operating state of each of the multiple air conditioners. In this case, the server 9 transmits all or part of the values of the multiple comparison parameters of each of the multiple air conditioners to the terminal 7 via the server communication unit 90 in response to the first request signal. The deterioration estimation unit 81 acquires all or part of the values of the multiple comparison parameters of the comparison air conditioner from the received values of all the comparison parameters, based on at least one of the capacity parameter value and the environmental parameter value of the air conditioner 101.

The life calculation unit 82 controls the terminal communication unit 70 to transmit to the server 9 a second request signal requesting one or more pieces of comparative deterioration information indicating, in a time series, the degree of deterioration of the comparison air conditioner and any of the plurality of parts in the comparison air conditioner that corresponds to the target object. Based on the second request signal, the server 9 refers to the memory unit 80, extracts the one or more pieces of comparative deterioration information, and transmits the extracted one or more pieces of comparative deterioration information to the terminal 7 via the server communication unit 90.

The lifespan calculation unit 82 extracts extracted deterioration information from one or more comparison deterioration information received from the server 9 based on the deterioration information generated by the deterioration estimation unit 81 and the degree of deterioration of the object at each point in time within the matching time range.

In addition, the life calculation unit 82 may control the terminal communication unit 70 to transmit a second request signal requesting multiple pieces of comparative deterioration information indicating the deterioration degree of multiple air conditioners and multiple parts in each of the multiple air conditioners in a time series. In this case, the server 9 transmits the multiple pieces of comparative deterioration information to the terminal 7 based on the received second request signal. The life calculation unit 82 may control the terminal communication unit 70 to transmit a second request signal requesting one or more pieces of comparative deterioration information indicating the deterioration degree of any of the multiple air conditioners and multiple parts in each of the multiple air conditioners corresponding to the target object in a time series. In this case, the server 9 transmits the one or more pieces of comparative deterioration information to the terminal 7 based on the received second request signal.

The control construction unit 83 controls the terminal communication unit 70 to transmit to the server 9 a third request signal requesting one or more control patterns associated with the extracted deterioration information extracted by the life calculation unit 82. The server 9 refers to the storage unit 80 and extracts the one or more control patterns based on the third request signal. The server 9 then transmits information indicating the one or more control patterns to the terminal 7 via the server communication unit 90. Note that, if a weight is associated with each control pattern in the storage unit 80, the server 9 transmits the weight associated with the one or more control patterns together with the one or more control patterns to the terminal 7. The control construction unit 83 constructs control content based on at least one control pattern of the one or more control patterns received from the server 9 via the terminal communication unit 70.

The control construction unit 83 instructs the air conditioning control unit 84 in the remote controller 5 via the terminal communication unit 70 to control the air conditioner 101 based on the constructed control content. The air conditioning control unit 84 controls the outdoor unit 1 and the indoor unit 3 in response to the instructions from the control construction unit 83.

The air conditioning control unit 84 in the third embodiment may control the remote air conditioning communication unit 51 to send a command signal to the terminal 7 instructing it to display control content information on a screen when the air conditioner 101 is operating based on the control content constructed by the control construction unit 83. When the terminal communication unit 70 receives the command signal, the terminal control unit 72 controls the terminal display unit 73 to display at least one of information indicating that the control content is being executed, information indicating the control content, and the life time of the object on the screen.

The flow of the air conditioning process by the air conditioning system 100 according to the third embodiment is illustrated in FIG. 8, as in the first and second embodiments. The contents of the air conditioning process are the same as those of the first and second embodiments, except for the following contents, and therefore will not be described. In the third embodiment, in each of steps S1 to S14, the deterioration estimation unit 81 acquires all or part of the values of a plurality of operating parameters, which are detection results by all or part of the plurality of air conditioning sensors, from the remote controller 5 via the terminal communication unit 70. In the third embodiment, in step S2, the deterioration estimation unit 81 controls the terminal communication unit 70 to transmit a first request signal to the server 9, instead of referring to the storage unit 80. Then, the deterioration estimation unit 81 acquires all or part of the values of a plurality of comparison parameters of the comparison air conditioner from the server 9 via the terminal communication unit 70.

The process of step S6 in the third embodiment is a process in which the deterioration estimation unit 81 requests all or part of the values of a plurality of operating parameters from the remote controller 5 via the terminal communication unit 70. The process of step S6 may be omitted in a case where all or part of the values of the plurality of parameters are automatically transmitted from the remote controller 5 to the terminal 7 every time the acquisition time elapses.

In the third embodiment, in step S7, the life calculation unit 82 controls the terminal communication unit 70 to send a second request signal to the server 9 instead of referring to the memory unit 80. Then, the life calculation unit 82 acquires one or more pieces of comparative deterioration information from the server 9 via the terminal communication unit 70. In the third embodiment, in step S10, the control construction unit 83 controls the terminal communication unit 70 to send a third request signal to the server 9 instead of referring to the memory unit 80. The control construction unit 83 acquires from the server 9 via the terminal communication unit 70 the extracted deterioration information, each time point in the extracted deterioration information, or a plurality of control patterns associated with each adjustment time range in the extracted deterioration information. The control construction unit 83 selects at least one control pattern from the plurality of control patterns.

In embodiment 3, in step S12, the control construction unit 83 instructs the air conditioning control unit 84 in the remote controller 5 via the terminal communication unit 70 to control the air conditioner 101 based on the constructed control content.

The effects of the air conditioning system 100 according to the third embodiment will be described below. The air conditioning system 100 according to the third embodiment includes a memory unit 80 in a server 9 on a network 2, a deterioration estimation unit 81, a life calculation unit 82, and a control construction unit 83 in a terminal 7 having a communication function, and an air conditioning control unit 84 in an air conditioner 101. The air conditioner 101 has an air conditioning communication unit that communicates with the server 9 and the terminal 7. The terminal 7 has a terminal communication unit 70 that communicates with the air conditioner 101 and the server 9. The deterioration estimation unit 81 controls the terminal communication unit 70 to transmit a first request signal to the server 9, requesting all or part of the values of a plurality of comparison parameters that indicate the operating state of the comparison air conditioner stored in the memory unit 80. The life calculation unit 82 controls the terminal communication unit 70 to transmit a second request signal to the server 9, requesting one or more pieces of comparison deterioration information that indicate the deterioration degree of the comparison air conditioner and any of the plurality of parts in the comparison air conditioner that correspond to the object in a time series. The control construction unit 83 controls the terminal communication unit 70 to transmit a third request signal requesting one or more control patterns associated with the extracted deterioration information extracted by the life calculation unit 82 in the storage unit 80. The control construction unit 83 then instructs the air conditioning control unit 84 via the terminal communication unit 70 to control the air conditioner 101 based on the constructed control content. This allows the terminal 7 to acquire a portion of a large amount of information stored in the server 9, such as the values of multiple comparison parameters of each of the multiple air conditioners and multiple pieces of comparison deterioration information, and to construct control content for extending the life of the air conditioner 101. Therefore, the air conditioning system 100 can reduce the amount of data in the air conditioner 101 and the amount of processing by the air conditioner 101.

The terminal 7 in the third embodiment has a terminal display unit 73 and a terminal control unit 72. The terminal display unit 73 displays information on the screen. The terminal control unit 72 controls the terminal display unit 73. When the air conditioner 101 is operating based on the control content constructed by the control construction unit 83, the air conditioning control unit 84 controls the air conditioning communication unit to transmit a command signal to the terminal 7 to instruct the terminal 7 to display on the screen at least one of information indicating that the control content is being executed, information indicating the control content, and the above-mentioned life time. When the terminal communication unit 70 receives the command signal, the terminal control unit 72 controls the terminal display unit 73 to display at least one of information indicating that the control content is being executed, information indicating the control content, and the life time. In this way, when the user of the terminal 7 is a maintenance person, the air conditioning system 100 can inform the maintenance person that the air conditioner 101 needs maintenance or the time when maintenance is needed. Therefore, the maintenance person can quickly perform maintenance before the air conditioner 101 breaks down, and the comfort of the user can be maintained. If the user of the terminal 7 is also the user of the air conditioner 101, the air conditioning system 100 can inform the user that the air conditioner 101 is deteriorating, that the air conditioner 101 is executing processing to slow the progression of the deterioration, or the details of the processing, etc. Therefore, the user can clearly grasp the state of the air conditioner 101 and recognize the timing to contact a maintenance company, improving convenience.

Although embodiments 1 to 3 have been described above, the contents of this disclosure are not limited to these embodiments and include any conceivable content.

REFERENCE SIGNS LIST 1 Outdoor unit, 2 Network, 3 Indoor unit, 4 Refrigerant piping, 5 Remote controller, 6 Refrigerant circuit, 7 Terminal, 9 Server, 10 Outdoor communication unit, 11 Outdoor control device, 12 Compressor, 13 Flow path switching device, 14 Outdoor heat exchanger, 15 Outdoor blower, 15A Outdoor driving source, 15B Outdoor fan, 16 Outdoor flow control valve, 17 Shutoff valve, 18 Pressure vessel, 19 Outdoor heat exchanger temperature sensor, 20 Outdoor air temperature sensor, 21 Discharge side pressure sensor, 22 Suction side pressure sensor, 23 Discharge side temperature sensor, 30 First indoor communication unit, 31 Second indoor communication unit, 32 Indoor control device, 33 Indoor heat exchanger, 34 Indoor blower, 34A Indoor driving source, 34B Indoor fan, 35 Indoor flow control valve, 36 Indoor heat exchanger temperature sensor, 37 Indoor temperature sensor, 38 Human presence sensor, 39 Left/right air direction control unit, 40 Left/right air direction change plate, 41 Up/down air direction control unit, 42 Up/down air direction change plate, 43 Air blowing mechanism, 44 Human body information management unit, 45 Area management unit, 46 Air direction control management unit, 47 Air volume control management unit, 50 Remote control communication unit, 51 Remote side air conditioning communication unit, 52 Remote side control device, 53 Air conditioning operation unit, 54 Air conditioning display unit, 55 Air conditioning memory unit, 56 Human position information management unit, 57 Operation management unit, 58 Adjustment area management unit, 70 Terminal communication unit, 71 Terminal operation unit, 72 Terminal control unit, 73 Terminal display unit, 80 Memory unit, 81 Deterioration estimation unit, 82 Life calculation unit, 83 Control construction unit, 84 Air conditioning control unit, 90 Server communication unit, A, B, C, G Deterioration curve, D, F Points, E, H Line, T _T1 time (life time), _T2 time, _t0 time when use begins, _t1 time (present time), _t2 time (time when failure occurs).

Claims (22)

An air conditioner that conditions the air in the room;
A plurality of air conditioning sensors that detect values of a plurality of operating parameters that indicate an operating state of the air conditioner;
a storage unit that stores values of a plurality of contrast parameters indicating the operating state of each of a plurality of air conditioners, including a comparison air conditioner having the same conditions as the air conditioner, and stores each of a plurality of pieces of comparison deterioration information indicating, in a chronological order, at least one of the deterioration degree of each of the plurality of air conditioners, the deterioration degree of each of a plurality of parts in each of the plurality of air conditioners, and the deterioration degree of two or more of the plurality of parts in each of the plurality of air conditioners, based on all or a portion of the values of the plurality of contrast parameters;
a deterioration estimation unit that compares all or a part of the values of the plurality of operating parameters detected by the plurality of air conditioning sensors with all or a part of the values of the plurality of comparison parameters of the extracted comparison air conditioner to estimate a deterioration degree of an object that is the air conditioner or one or more of a plurality of parts in the air conditioner;
a life calculation unit that extracts extracted deterioration information, which is one of the comparative deterioration information, from the plurality of pieces of comparative deterioration information stored in the storage unit based on the deterioration degree of the time series in a predetermined comparison time range estimated by the deterioration estimation unit, and calculates a life time from the present time to a failure time of the object using the extracted deterioration information;
a control construction unit that constructs a control content for extending the life time calculated by the life calculation unit based on the extracted deterioration information extracted by the life calculation unit;
An air conditioning control unit that controls the air conditioner based on the control content constructed by the control construction unit;
An air conditioning system equipped with: The deterioration estimation unit is
The air conditioning system according to claim 1 , wherein, when the object is the air conditioner, a degree of deterioration of the air conditioner is estimated based on a degree of deterioration of each of the plurality of components in the air conditioner. The life calculation unit is
The air conditioning system of claim 1 or 2, further comprising: a comparison unit that compares one or more of the plurality of pieces of comparative deterioration information, which indicates, in a time series, the degree of deterioration of any of the plurality of air conditioners and the plurality of parts in each of the plurality of air conditioners corresponding to the object, with the degree of deterioration of the object at each of a plurality of points in the comparison time range estimated by the deterioration estimation unit; extracts the extracted deterioration information from the one or more pieces of comparative deterioration information based on the comparison result; predicts the time of failure of the object using the extracted deterioration information; and calculates the lifetime based on the time of failure and the current time. The life calculation unit is
An air conditioning system as described in any one of claims 1 to 3, wherein the extracted deterioration information is extracted from one or more of the plurality of comparison deterioration information that indicate, in a chronological order, the degree of deterioration of the comparison air conditioner and any of the plurality of parts in the comparison air conditioner that correspond to the target object. The storage unit is
one or more control patterns for delaying deterioration of each of the plurality of air conditioners, each of a plurality of components in each of the plurality of air conditioners, or two or more of the plurality of components in each of the plurality of air conditioners, are stored in association with each of the plurality of pieces of comparative deterioration information;
The control construction unit
The air conditioning system according to any one of claims 1 to 4 , wherein the control content is constructed using at least one of the one or more control patterns associated with the extracted deterioration information. The storage unit is
two or more pieces of comparative deterioration information, or one piece of comparative deterioration information, among the plurality of pieces of comparative deterioration information indicating a deterioration degree in time series of the plurality of air conditioners and any of the plurality of components in each of the plurality of air conditioners, are associated with a plurality of the control patterns for delaying deterioration of the plurality of air conditioners and any of the plurality of components in each of the plurality of air conditioners, and are stored;
storing a weight associated with each of the plurality of control patterns;
The weights associated with each of the plurality of control patterns are
the greater the life span of the plurality of air conditioners and any of the plurality of components in each of the plurality of air conditioners is extended,
The control construction unit
The air conditioning system according to claim 5 , wherein, when the extracted deterioration information is associated with the plurality of control patterns, the at least one control pattern is selected from the plurality of control patterns in descending order of the associated weight . The air conditioning system according to claim 6 , wherein the weights are determined by learning using artificial intelligence. The deterioration estimation unit is
Estimating the degree of deterioration of the object based on values of all or a part of the plurality of operating parameters of the air conditioner detected at a time point after a predetermined correction time has elapsed from a time point at which the air conditioner starts operating in accordance with the control content constructed by the control construction unit;
The control construction unit
When the degree of deterioration estimated by the deterioration estimation unit is equal to or greater than the degree of deterioration in the extracted deterioration information at a time point after the correction time has elapsed, and when the extracted deterioration information is associated with a plurality of control patterns, a weight associated with at least one of the control patterns used when constructing the control content is reduced;
The air conditioning system according to claim 6 or 7, wherein the control content is constructed using at least one control pattern among the plurality of control patterns other than the at least one control pattern used when constructing the control content . The deterioration estimation unit is
Estimating the degree of deterioration of the object based on values of all or a part of the plurality of operating parameters of the air conditioner detected at a time point after a predetermined correction time has elapsed from a time point at which the air conditioner starts operating in accordance with the control content constructed by the control construction unit;
The control construction unit
The air conditioning system of claim 5, wherein when the degree of deterioration estimated by the deterioration estimation unit is equal to or greater than the degree of deterioration in the extracted deterioration information at a point after the correction time has elapsed, and when a plurality of control patterns are associated with the extracted deterioration information, the control content is constructed using at least one of the plurality of control patterns other than the at least one control pattern used when constructing the control content. The air conditioner includes:
A refrigerant is circulated through a refrigerant circuit, and heat is exchanged between the refrigerant and the air inside the room and the air outside the room, thereby performing air conditioning for the room,
a compressor provided in the refrigerant circuit and configured to compress and discharge the refrigerant;
an expansion valve provided in the refrigerant circuit to reduce the pressure of the refrigerant;
A blower that blows the air after heat exchange into the room or the outside of the room;
having
Any of the one or more control patterns is
The air conditioning system according to any one of claims 5 to 9 , wherein the control is a change control of a frequency of the compressor, a change control of an air volume of the blower, or a change control of an opening degree of the expansion valve. The comparative air conditioner is,
An air conditioning system as described in any one of claims 1 to 10, wherein the difference between the value of the capacity parameter of the comparison air conditioner and the value of the capacity parameter of the air conditioner is equal to or less than a predetermined capacity threshold, and the difference between the value of the environmental parameter of the comparison air conditioner and the value of the environmental parameter of the air conditioner is equal to or less than a predetermined environmental threshold. The air conditioner includes:
A refrigerant is circulated through a refrigerant circuit, and heat is exchanged between the refrigerant and the air inside the room and the air outside the room, thereby performing air conditioning for the room,
a compressor provided in the refrigerant circuit and configured to compress and discharge the refrigerant;
The comparative air conditioner is,
a difference between a value of a capacity parameter of the comparison air conditioner and a value of a capacity parameter of the air conditioner is equal to or less than a predetermined capacity threshold, and a difference between a value of an environmental parameter of the comparison air conditioner and a value of an environmental parameter of the air conditioner is equal to or less than a predetermined environmental threshold,
The value of the ability parameter is
It is determined by a refrigeration capacity, information indicating a model or specifications, a model number, a set power value input to the compressor at the beginning of use of the compressor, or a set current value flowing through the compressor at the beginning of use of the compressor,
The air conditioning system according to any one of claims 1 to 9, wherein the values of the environmental parameters are determined by the installation location of the air conditioner, the temperature at the installation location, the weather at the installation location, the cumulative usage time of the air conditioner, the average number of people in the room, the amount of refrigerant, the length of the refrigerant piping through which the refrigerant circulates in the refrigerant circuit, the time average or cumulative value of the power value input to the compressor, or the time average or cumulative value of the current value applied to the compressor. The air conditioning system according to claim 10 or 12 , wherein one of the plurality of operating parameters is a power input to the compressor or a current applied to the compressor. The air conditioner includes:
Further comprising a remote controller for remotely controlling the air conditioner,
The remote controller includes:
An air conditioning system as described in any one of claims 1 to 13, wherein when the air conditioner is operating based on the control content constructed by the control construction unit, at least one of information indicating that the control content is being executed, information indicating the control content , and the life time is displayed on a screen. The air conditioning system includes:
The storage unit is provided in a server on a network,
The deterioration estimation unit, the life calculation unit, the control construction unit, and the air conditioning control unit are provided in the air conditioner,
The air conditioner includes:
An air conditioning communication unit that communicates with the server,
The deterioration estimation unit is
controlling the air conditioning communication unit to transmit to the server a first request signal requesting all or a part of the values of the comparison parameters that indicate the operating state of the comparison air conditioner and that are stored in the memory unit;
The life calculation unit is
controlling the air conditioning communication unit to transmit to the server a second request signal requesting one or more pieces of comparison deterioration information indicating, in time series, the deterioration degree of the comparison air conditioner and any one of the plurality of parts in the comparison air conditioner corresponding to the target object;
The control construction unit
An air conditioning system as described in any one of claims 1 to 4, wherein the memory unit controls the air conditioning communication unit to transmit a third request signal requesting one or more control patterns that correspond to the extracted deterioration information extracted by the life calculation unit. The air conditioning communication unit is
Communicating with a terminal having a communication function;
The air conditioning system of claim 15, wherein when the air conditioner is operating based on the control content constructed by the control construction unit, a command signal is sent to the terminal instructing it to display on a screen at least one of information indicating that the control content is being executed, information indicating the control content, and the life time. The air conditioning system includes:
the storage unit, the deterioration estimation unit, the life calculation unit, and the control construction unit are provided in a server on a network;
The air conditioning control unit is provided in the air conditioner,
The air conditioner includes:
An air conditioning communication unit that communicates with the server,
The air conditioning communication unit is
The air conditioning system according to any one of claims 1 to 4 , wherein a control signal indicating the control content constructed by the control construction unit is received from the server. The air conditioning communication unit is
Communicating with a terminal having a communication function;
The air conditioning control unit is
The air conditioning system of claim 17, further comprising: controlling the air conditioning communication unit to send a command signal to the terminal instructing the terminal to display on a screen at least one of information indicating that the control content is being executed, information indicating the control content, and the life time when the air conditioner is operating based on the control content constructed by the control construction unit. The air conditioning system includes:
The storage unit is provided in a server on a network,
The deterioration estimation unit, the life calculation unit, and the control construction unit are provided in a terminal having a communication function,
The air conditioning control unit is provided in the air conditioner,
The air conditioner includes:
an air conditioning communication unit that communicates with the server and the terminal;
The terminal includes:
A terminal communication unit that communicates with the air conditioner and the server,
The deterioration estimation unit is
controlling the terminal communication unit to transmit to the server a first request signal requesting all or a part of the values of the comparison parameters that indicate the operating state of the comparison air conditioner and that are stored in the memory unit;
The life calculation unit is
controlling the terminal communication unit to transmit to the server a second request signal requesting one or more pieces of comparative deterioration information indicating, in time series, the degree of deterioration of the comparison air conditioner and any one of the plurality of parts in the comparison air conditioner corresponding to the target object;
The control construction unit
controlling the terminal communication unit to transmit, in the storage unit, a third request signal requesting the one or more control patterns associated with the extracted deterioration information extracted by the life calculation unit;
An air conditioning system according to any one of claims 1 to 4 , wherein the air conditioning control unit is instructed via the terminal communication unit to control the air conditioner based on the established control content. The terminal includes:
A terminal display unit that displays information on a screen;
A terminal control unit that controls the terminal display unit;
having
The air conditioning control unit is
when the air conditioner is operating based on the control content constructed by the control construction unit, controls the air conditioning communication unit to transmit to the terminal a command signal instructing the terminal to display on a screen at least one of information indicating that the control content is being executed, information indicating the control content, and the life time;
The terminal control unit
The air conditioning system of claim 19, wherein when the terminal communication unit receives the command signal, the terminal display unit is controlled to display at least one of information indicating that the control content is being executed, information indicating the control content, and the lifetime . An air conditioner that conditions the air in the room;
A plurality of air conditioning sensors that detect values of a plurality of operating parameters that indicate an operating state of the air conditioner;
a storage unit that stores the values of a plurality of comparison parameters indicating the operating state of each of a plurality of air conditioners, including a comparison air conditioner having the same conditions as the air conditioner, and stores each of a plurality of pieces of comparison deterioration information indicating, in a chronological order, at least one of the deterioration degree of each of the plurality of air conditioners, the deterioration degree of each of a plurality of parts in each of the plurality of air conditioners, and the deterioration degree of two or more of the plurality of parts in each of the plurality of air conditioners, based on the values of the plurality of comparison parameters;
An air conditioning method performed by an air conditioning system comprising:
a deterioration estimation step of estimating a deterioration degree of an object, which is the air conditioner or one or more of a plurality of parts of the air conditioner, by comparing all or a portion of the values of the plurality of operating parameters detected by the plurality of air conditioning sensors with all or a portion of the values of the plurality of comparison parameters of the extracted comparison air conditioner;
a life calculation step of extracting extracted deterioration information, which is one of the comparative deterioration information, from the plurality of pieces of comparative deterioration information stored in the storage unit based on the time-series deterioration degree in a predetermined comparison time range estimated in the deterioration estimation step, and calculating a life time from the present time to a failure time of the object using the extracted deterioration information;
a control construction step of constructing a control content for extending the life time calculated in the life calculation step based on the extracted deterioration information extracted in the life calculation step;
an air conditioning control step of controlling the air conditioner based on the control content constructed in the control construction step;
An air conditioning method comprising: An air conditioner that conditions the air in the room;
A plurality of air conditioning sensors that detect values of a plurality of operating parameters that indicate an operating state of the air conditioner;
a storage unit that stores the values of a plurality of comparison parameters indicating the operating state of each of a plurality of air conditioners, including a comparison air conditioner having the same conditions as the air conditioner, and stores each of a plurality of pieces of comparison deterioration information indicating, in a chronological order, at least one of the deterioration degree of each of the plurality of air conditioners, the deterioration degree of each of a plurality of parts in each of the plurality of air conditioners, and the deterioration degree of two or more of the plurality of parts in each of the plurality of air conditioners, based on the values of the plurality of comparison parameters;
An air conditioning program executed by an air conditioning system comprising:
a deterioration estimation function that compares all or a part of the values of the plurality of operating parameters detected by the plurality of air conditioning sensors with all or a part of the values of the plurality of comparison parameters of the extracted comparison air conditioner to estimate a deterioration degree of an object that is the air conditioner or one or more of a plurality of parts in the air conditioner;
a life calculation function that extracts extracted deterioration information, which is one of the comparative deterioration information, from the plurality of pieces of comparative deterioration information stored in the storage unit based on the time-series deterioration degree in a predetermined comparison time range estimated by the deterioration estimation function, and calculates a life time from the current time point to a failure point of the object using the extracted deterioration information;
A control construction function that constructs a control content for extending the life time calculated by the life calculation function based on the extracted deterioration information extracted by the life calculation function;
An air conditioning control function that controls the air conditioner based on the control content constructed by the control construction function;
An air conditioning program that realizes this in the air conditioning system.

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