JP7008052B2 - Air conditioning system defect detection method and equipment - Google Patents

Description

The present invention relates to a defect detection method and an apparatus for an air conditioning system.

The following Patent Document 1 proposes an air-conditioning system for air-conditioning a plurality of spaces in a building. This air conditioning system supplies air conditioned by one heat source, including at least one air conditioner, to multiple spaces.

Japanese Unexamined Patent Publication No. 2016-191483

In general, the central air-conditioning type air-conditioning system as described above has a problem that it takes a lot of time to find out which part is the cause when a problem occurs.

The present invention has been devised in view of the above circumstances, and an object of the present invention is to provide a method and an apparatus capable of detecting a malfunction of an air conditioning system at an early stage.

The present invention is a method for detecting a malfunction of an air-conditioning system for air-conditioning a plurality of spaces in a building with one heat source including at least one air conditioner, wherein the air-conditioning system includes the plurality of air conditioners. The actual temperature of each space is measured by the temperature sensor for each of the spaces, and the actual temperature is controlled so as to approach the target temperature set by the user. Based on the step of taking in the past air conditioning history data including at least the target temperature and the actual temperature at predetermined time intervals and the relationship between the target temperature and the actual temperature of the air conditioning history data. It is characterized by including a step of determining the presence or absence of a defect in the air conditioning system.

In the defect detection method of the air conditioning system according to the present invention, the air conditioning history data may be captured in the computer in the capture step, and the determination step may be executed by the computer.

In the defect detection method of the air conditioning system according to the present invention, the relationship may be a time change of the temperature difference between the target temperature and the actual temperature.

In the defect detection method of the air conditioning system according to the present invention, the determination step is based on a combination of a step of specifying a space in which the temperature difference increases with the passage of time as an air conditioning defective space and the air conditioning defective space. , The defect specifying step for specifying the defect location may be included.

In the defect detecting method of the air conditioning system according to the present invention, the defect specifying step is a first method of identifying a defect of the air conditioner when the combination of the air conditioning defective spaces is all the spaces in the building. It may include a specific step.

In the method for detecting a defect in the air conditioning system according to the present invention, the air conditioning history data includes the temperature of the suction port and the temperature of the air outlet of the air conditioner, and the first specific step is the said of the air conditioning history data. The process of calculating the air conditioning capacity of the air conditioner based on the temperature of the suction port and the temperature of the outlet, and when the air conditioning capacity is equal to or less than a predetermined threshold value, the air conditioner has a problem. It may include a step of identifying that there is.

In the method for detecting a defect in the air-conditioned system according to the present invention, the air-conditioned system sends air conditioned by the air conditioner to a first group composed of a part of the plurality of spaces. The defect identification step includes one fan and a second fan that sends the conditioned air to a second group composed of a space different from the space of the first group among the plurality of spaces. A second specific step of identifying a defect of the first fan or the second fan when the combination of the air-conditioned poor spaces is all the spaces of the first group or all the spaces of the second group. May include.

In the defect detection method of the air conditioning system according to the present invention, the air conditioning history data includes the rotation speeds of the first fan and the second fan, respectively, and the second specific step is the first of the air conditioning history data. The relationship between the rotation speed of one fan and the temperature difference of the second group, or the relationship between the rotation speed of the second fan of the air conditioning history data and the temperature difference of the first group. The defect of the first fan or the second fan may be specified based on the above.

In the defect detection method of the air conditioning system according to the present invention, the air conditioning system includes a damper for adjusting the air volume of each of the plurality of spaces, and in the defect specifying step, the combination of the air conditioning defective spaces is the first. A third that identifies a defect in the damper or the temperature sensor when the combination of the air-conditioned poor spaces is two or more spaces instead of all the spaces in one group and all the spaces in the second group. It may include a specific step.

In the method for detecting a defect in the air conditioning system according to the present invention, the third specific step is based on the plan information including the information regarding the connection of the dampers in the plurality of spaces and the information regarding the connection of the temperature sensors. A defect in the damper or the temperature sensor may be identified.

In the defect detection method of the air conditioning system according to the present invention, the defect specifying step may include a fourth specific step of identifying a defect of the temperature sensor when the combination of the air conditioning defective spaces is one space. ..

In the defect detection method of the air conditioning system according to the present invention, the fourth specific step may identify the defect of the temperature sensor based on the plan information including the information regarding the installation of the temperature sensor.

In the method for detecting a defect in the air-conditioned system according to the present invention, the air-conditioned system includes a fan that sends air conditioned by the air conditioner to the plurality of spaces, and a duct that connects the fan and the space. The step of determining the above may include an aged deterioration determination step of determining the presence or absence of aged deterioration of the air conditioner, the fan, or the duct.

The present invention is a device having an arithmetic processing device for detecting a malfunction of an air-conditioning system for air-conditioning a plurality of spaces in a building with one heat source including at least one air conditioner. For each of the plurality of spaces, the actual temperature of each space is measured by the temperature sensor, and the actual temperature is controlled so as to approach the target temperature set by the user. A history data acquisition unit that captures past air conditioning history data including at least the target temperature and the actual temperature for each of the plurality of spaces at predetermined time intervals, and the target temperature and the actual temperature of the air conditioning history data. It is characterized by including a determination unit for determining whether or not there is a defect in the air conditioning system based on the relationship with.

In the defect detection device of the air conditioning system according to the present invention, the relationship may be a time change of the temperature difference between the target temperature and the actual temperature.

In the defect detection device of the air conditioning system according to the present invention, the determination unit includes a space specifying unit that specifies a space in which the temperature difference increases with the passage of time as an air conditioning defective space.
Based on the combination of the air-conditioning defective spaces, the defect specifying portion for specifying the defect location may be included.

In the defect detection device of the air conditioning system according to the present invention, the defect specifying unit identifies the defect of the air conditioner when the combination of the air conditioning defective spaces is all the spaces in the building. A specific part may be included.

In the defect detection device of the air conditioning system according to the present invention, the air conditioning history data includes the temperature of the suction port and the temperature of the air outlet of the air conditioner, and the first specific unit is the air conditioning history data. The air conditioning capacity of the air conditioner is calculated based on the temperature of the suction port and the temperature of the outlet, and if the air conditioning capacity is equal to or less than a predetermined threshold value, the air conditioner has a problem. May be specified.

In the defect detection device of the air conditioning system according to the present invention, the air conditioning system sends air conditioned by the air conditioner to a first group composed of a part of the plurality of spaces. The defect identification unit includes one fan and a second fan that sends the air-conditioned air to a second group composed of a space different from the space of the first group among the plurality of spaces. When the combination of the air-conditioned poor spaces is all the spaces of the first group or all the spaces of the second group, the second specifying unit for specifying the defect of the first fan or the second fan. May include.

In the defect detection device of the air conditioning system according to the present invention, the air conditioning history data includes the rotation speeds of the first fan and the second fan, respectively, and the second specific unit is the first of the air conditioning history data. The relationship between the rotation speed of one fan and the temperature difference of the second group, or the relationship between the rotation speed of the second fan of the air conditioning history data and the temperature difference of the first group. The defect of the first fan or the second fan may be specified based on the above.

In the defect detection device of the air conditioning system according to the present invention, the air conditioning system includes a damper for adjusting the air volume of each of the plurality of spaces, and the defect specifying portion is a combination of the air conditioning defective spaces. A third that identifies a defect in the damper or the temperature sensor when the combination of the air-conditioned poor spaces is two or more spaces instead of all the spaces in one group and all the spaces in the second group. A specific part may be included.

In the defect detection device of the air conditioning system according to the present invention, the third specific unit is based on the plan information including the information regarding the connection of the dampers in the plurality of spaces and the information regarding the connection of the temperature sensor. A defect in the damper or the temperature sensor may be identified.

In the defect detection device of the air conditioning system according to the present invention, the defect specifying unit may include a fourth specifying unit that identifies a defect of the temperature sensor when the combination of the air conditioning defective spaces is one space. ..

In the defect detection device of the air conditioning system according to the present invention, the fourth specific unit may identify the defect of the temperature sensor based on the plan information including the information regarding the installation of the temperature sensor.

In the defect detection device of the air-conditioned system according to the present invention, the air-conditioned system includes a fan that sends air conditioned by the air conditioner to the plurality of spaces, and a duct that connects the fan and the space. The determination unit may include an aging deterioration determination unit for determining the presence or absence of aging deterioration of the air conditioner, the fan, or the duct.

The present invention takes in the air conditioning history data of the air conditioning system and determines whether or not there is a defect in the air conditioning system based on the relationship between the target temperature and the actual temperature, so that it is possible to detect the defect in the air conditioning system at an early stage. It becomes.

It is sectional drawing which shows an example of a building in which a defect of an air conditioning system is detected. It is a conceptual diagram which shows an example of the structure of a control means. It is a block diagram which shows an example of the structure of the defect detection device of an air conditioning system. It is a block diagram which shows an example of the structure of a judgment part. It is a flowchart which shows an example of the processing procedure of the detection method of this embodiment. (A) is a graph showing an example of air conditioning history data of one space included in the first group. FIG. 6B is a graph showing an example of air conditioning history data of one space included in the second group. It is a flowchart which shows an example of the processing procedure of a judgment process. It is a flowchart which shows an example of the processing procedure of a defect identification process. It is a flowchart which shows an example of the processing procedure of a 1st specific process. It is a flowchart which shows an example of the processing procedure of the 2nd specific process. (A) and (b) are graphs showing an example of the relationship between the rotation speed of the first fan and the temperature difference of the second group and time. It is a flowchart which shows an example of the processing procedure of the 3rd specific process. It is a flowchart which shows an example of the processing procedure of the 4th specific process. It is a flowchart which shows an example of the processing procedure of the aging deterioration determination process.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
In the defect detection method of the air conditioning system of the present embodiment (hereinafter, may be simply referred to as “detection method”), a defect of the air conditioning system for air-conditioning a plurality of spaces in the building is detected. FIG. 1 is a cross-sectional view showing an example of a building in which a malfunction of the air conditioning system is detected. It should be noted that the drawings are intended to enhance the understanding of the contents of the invention, and in addition to the exaggerated display, it is pointed out in advance that the scales and the like do not exactly match between the drawings.

The building 2 is exemplified as a house, but may be a building or the like, for example. The building 2 of the present embodiment is configured to include an underfloor space 3 and an above-floor space 4. In the present embodiment, the air-conditioned space 5 is provided in the above-floor space 4, but may be provided in the underfloor space 3.

The underfloor space 3 is a space surrounded by the foundation, the ground, and the floor on the first floor. The foundation is provided with an opening 6 for taking in the outside air A1. The outside air A1 taken in from the opening 6 exchanges heat with the heat in the ground where the temperature does not change much throughout the year through the ground.

The above-floor space 4 is a space provided above the underfloor space 3 via the floor. The floor space 4 of the present embodiment includes a plurality of spaces (living rooms) 5. The plurality of spaces 5 include spaces 5a and 5b on the first floor and spaces 5c and 5d on the second floor.

The space 5 of the present embodiment is divided into a plurality of groups 7. The group 7 of the present embodiment is composed of the first group 7A and the second group 7B, but may be composed of one group or three or more groups.

The first group 7A is composed of a part of the space 5 among the plurality of spaces 5. The first group 7A of the present embodiment is composed of the spaces 5a and 5b on the first floor, but may be composed of only one of these spaces or may include the other space. On the other hand, the second group 7B is composed of a space 5 different from the space 5 of the first group 7A (in this example, the spaces 5a and 5b on the first floor) among the plurality of spaces 5. The second group 7B of the present embodiment is composed of the spaces 5c and 5d on the second floor, but may be composed of one of these spaces or may include the other space.

The air conditioning system 8 of this embodiment is a central air conditioning type. The air conditioning system 8 is one heat source including at least one air conditioner 9, and is a plurality of spaces 5 in the building 2 (in this example, the spaces 5a and 5b on the first floor and the spaces 5c and 5d on the second floor). ) Is air-conditioned. The heat source of the present embodiment is composed of one air conditioner (air conditioner) 9, but may be composed of a plurality of air conditioners 9.

The air conditioning system 8 includes an air conditioner (heat source) 9 and a temperature sensor 11. Further, the air conditioning system 8 of the present embodiment includes a fan 12, a damper 13, a duct 14, and a control means 15, but the configuration is not limited to such a configuration, and some configurations are not limited to such a configuration. It may be omitted.

The air conditioner 9 and the fan 12 are housed inside the chamber box 16, for example. The chamber box 16 is formed in a box shape having a space inside thereof. The chamber box 16 of the present embodiment has an air supply port (not shown) for supplying air A3 circulating in a plurality of spaces 5 to the inside, and outside air for supplying outside air (underfloor air) A1 to the inside. An intake port (not shown) is provided. The outside air A1 of the present embodiment is taken in from the underfloor space 3 via the duct 17 and the outside air supply fan 18. The outside air A1 may be taken in directly from the outside.

The air conditioner 9 is, for example, a general household separate air conditioner. The air conditioner 9 includes an indoor unit and an outdoor unit (not shown) installed outside the building 2 as a set. The indoor unit has a suction port (not shown) and an outlet (not shown). The suction port is for taking air into the heat exchanger (not shown) inside the indoor unit. On the other hand, the outlet is for discharging the air A2 air-conditioned by the heat exchanger. The set temperature and air volume of the air conditioner 9 are controlled by, for example, the control means 15. In the present embodiment, the air-conditioned air A2 is purified by the filter 19 provided in the chamber box 16, but is not limited to such an embodiment.

The fan 12 is for sending the conditioned air A2 to a plurality of spaces 5 (in this example, the spaces 5a and 5b on the first floor and the spaces 5c and 5d on the second floor). The fan 12 of the present embodiment includes a first fan 12a and a second fan 12b.

The first fan 12a is for sending (supplying) the air-conditioned air A2 to the first group 7A (in this example, the spaces 5a and 5b on the first floor). On the other hand, the second fan 12b is for sending (supplying) the air-conditioned air A2 to the second group 7B (in this example, the spaces 5c and 5d on the second floor). The fan 12 may be composed of any one of the fans, or may be composed of three or more fans. The air volume of the fan 12 is controlled by the control means 15, for example, based on the ventilation frequency required for the building 2. The fan 12 of the present embodiment is configured as a constant air volume fan whose rotation speed is controlled so that the air volume is constant. The fan 12 is not limited to such a constant air volume fan.

The damper 13 is for adjusting the air volume of the air-conditioned air A2 in each of the plurality of spaces 5 (in this example, the spaces 5a and 5b on the first floor and the spaces 5c and 5d on the second floor). .. The damper 13 of the present embodiment can increase the air volume of the conditioned air A2 according to the size of the opening degree (opening area). The opening degree of the damper 13 is controlled by, for example, the control means 15. The damper 13 of the present embodiment is provided in each space 5.

The duct 14 connects between the fan 12 and the damper 13. The duct 14 of the present embodiment is configured to include a first duct 14a and a second duct 14b. The first duct 14a connects the first fan 12a and the dampers 13 and 13 provided in the spaces 5a and 5b on the first floor, respectively. In the first duct 14a of the present embodiment, a branch portion 25 is provided between the first fan 12a, the damper 13 of one space 5a on the first floor, and the damper 13 of the other space 5b on the first floor. ing. On the other hand, the second duct 14b connects the second fan 12b and the dampers 13 and 13 provided in the spaces 5c and 5d on the second floor, respectively. In the second duct 14b of the present embodiment, a branch portion 25 is provided between the second fan 12b, the damper 13 of one space 5c on the second floor, and the damper 13 of the other space 5d on the second floor. ing.

The temperature sensor 11 is for measuring the actual temperature of each space 5 (in this example, the spaces 5a and 5b on the first floor and the spaces 5c and 5d on the second floor). The temperature sensor 11 of the present embodiment is provided in each space 5, and is connected to the control means 15. The actual temperature measured by the temperature sensor 11 is transmitted to the control means 15.

The control means 15 controls each component (in this example, the air conditioner 9, the fan 12, the damper 13, and the temperature sensor 11) constituting the air conditioning system 8 based on a predetermined processing procedure (control procedure). It is for doing. The control means 15 of the present embodiment is configured by a computer and is installed, for example, on a partition wall of the space 5. FIG. 2 is a conceptual diagram showing an example of the configuration of the control means 15.

The control means 15 includes, for example, a calculation unit 20 including a CPU (central processing unit), a storage unit 21 in which processing procedures are stored in advance, and a working memory 22 for reading processing procedures from the storage unit 21. Has been done. An input means 23 and an output means 24 are connected to the calculation unit 20.

The input means 23 is composed of, for example, an operation button, a touch panel, or the like provided in the housing (shown in FIG. 1) of the control means 15. By the input means 23, for example, the information input by the user (resident or the like) can be transmitted to the calculation unit 20. The information to be input includes, for example, the target temperature of each space 5 shown in FIG. 1 (in this example, the spaces 5a and 5b on the first floor and the spaces 5c and 5d on the second floor), and the start and stop of the air conditioning operation. Instruction information etc. are included. Although the target temperature of the present embodiment is set for each of the plurality of spaces 5, it may be set for each group 7 (in this example, the first group 7A and the second group 7B) shown in FIG.

The output means 24 is configured as a display provided in the housing (shown in FIG. 1) of the control means 15. By transmitting a signal to the output means 24, the arithmetic unit 20 can display, for example, the operating status of the air conditioning system 8.

An air conditioner 9, a fan 12 (in this example, the first fan 12a and the second fan 12b), and a damper 13 are connected to the calculation unit 20. As a result, the calculation unit 20 adjusts the start and stop of these operations, the set temperature of the air conditioner 9, and the air volume of the fan 12 by transmitting signals to, for example, the air conditioner 9 and the fan 12. can do. Further, the arithmetic unit 20 transmits a signal to the damper 13, so that the damper 13 is provided in each space 5 (in this example, the spaces 5a and 5b on the first floor and the spaces 5c and 5d on the second floor). The opening can be adjusted respectively.

A temperature sensor 11 is connected to the calculation unit 20. As a result, the calculation unit 20 transmits a signal to the temperature sensor 11 to transmit the signals to the spaces 5 shown in FIG. 1 (in this example, the spaces 5a and 5b on the first floor and the spaces 5c and 5d on the second floor). The actual temperature can be measured by the temperature sensor 11 and the measurement result of the actual temperature can be transmitted to the calculation unit 20.

In the air conditioning system 8 of the present embodiment, for example, a plurality of spaces 5 shown in FIG. 1 (in this example, spaces 5a and 5b on the first floor, and 2) are based on a predetermined processing procedure (control procedure). For each of the floor spaces 5c and 5d), the actual temperature of each space 5 is measured by the temperature sensor 11. Then, the components (devices) of the air conditioning system 8 are controlled (for example, the set temperature of the air conditioner 9, the air volume of the fan 12, and the damper 13 so that these actual temperatures approach the target temperature set by the user. The opening etc. are controlled).

By the way, in the central air conditioning type air conditioning system 8 as in the present embodiment, it is composed of a plurality of components (in this example, an air conditioner (heat source) 9, a fan 12, a damper 13 and a temperature sensor 11). They are intricately controlled. Therefore, when a problem occurs in the air conditioning system 8, there is a problem that it takes a lot of time to find out which part is the cause.

In the detection method of the present embodiment, the above-mentioned malfunction of the air conditioning system 8 is detected. In the detection method of the present embodiment, a defect detection device for an air conditioning system (hereinafter, may be simply referred to as a “detection device”) is used. FIG. 3 is a block diagram showing an example of the configuration of the defect detection device 26 of the air conditioning system 8.

The detection device 26 of this embodiment is configured by a computer 27. As the computer 27, for example, a personal computer, a mobile information terminal (tablet type, etc.), a cloud server connected via the Internet, or the like can be adopted. The computer 27 may be configured by the control means 15 shown in FIGS. 1 and 2.

The detection device 26 (computer 27) of the present embodiment has an input unit 28 as an input device, an output unit 29 as an output device, and an arithmetic processing unit 30.

For the input unit 28, for example, a keyboard, a mouse, a touch panel, or the like is used. For the output unit 29, for example, a display device, a printer, or the like is used. The arithmetic processing device 30 includes an arithmetic unit (CPU) 31 that performs various arithmetic operations, a storage unit 32 that stores data, programs, and the like, and a working memory 33.

The storage unit 32 is a non-volatile information storage device composed of, for example, a magnetic disk, an optical disk, an SSD, a flash memory, or the like. The storage unit 32 includes a data unit 34 and a program unit 35.

The data unit 34 is for storing information necessary for detecting a malfunction of the air conditioning system 8 (shown in FIG. 1). The data unit 34 of the present embodiment includes a history data storage unit 34a, a relationship storage unit 34b, an air conditioning failure space storage unit 34c, a defect location storage unit 34d, and a plan information storage unit 34e.

The program unit 35 is a program for causing the calculation unit 31 to execute the detection method of the present embodiment. The program unit 35 of the present embodiment includes a history data acquisition unit 36 and a determination unit 37. FIG. 4 is a block diagram showing an example of the configuration of the determination unit 37.

The determination unit 37 includes a space identification unit 38, a defect identification unit 39, and an aged deterioration determination unit 40. The defect identification unit 39 includes a first specific unit 39a, a second specific unit 39b, a third specific unit 39c, and a fourth specific unit 39d. The program unit 35 is not limited to such an embodiment, and a part of the program unit 35 may be omitted. FIG. 5 is a flowchart showing an example of the processing procedure of the detection method of the present embodiment.

In the detection method of the present embodiment, first, the air conditioning history data is taken in (step S1). In step S1, as shown in FIGS. 3 and 4, the history data acquisition unit 36 of the program unit 35 is input to the work memory 33. Then, the history data acquisition unit 36 is executed by the calculation unit 31.

In step S1, past air conditioning history data is taken in at predetermined time intervals. The air-conditioning history data of the present embodiment shows that in the past before the detection method of the present embodiment was implemented, the air-conditioning system 8 shown in FIG. 1 had a plurality of spaces 5 (in this example, the spaces 5a and 5b on the first floor). , And the spaces 5c and 5d on the second floor) are historical information when each of them is air-conditioned.

The air conditioning history data is acquired prior to the implementation of step S1. The air conditioning history data may be stored, for example, in the storage unit 21 of the control means 15 shown in FIG. 2, or may be directly stored in the history data storage unit 34a of the detection device 26 shown in FIG. .. When the detection device 26 is composed of a cloud server or the like, the air conditioning history data is stored in the history data storage unit 34a via the Internet or the like.

The air conditioning history data includes the target temperature set by the user and the temperature sensor 11 for each space 5 (in this example, the spaces 5a and 5b on the first floor and the spaces 5c and 5d on the second floor). At least the actual temperature is included. In addition to the target temperature and the actual temperature, the air conditioning history data of the present embodiment includes the temperature of the suction port (not shown) of the air conditioner 9 and the temperature of the outlet (not shown). Further, the air conditioning history data includes the rotation speeds of the first fan 12a and the second fan 12b, respectively. In these air conditioning history data, the history that is not necessary in the processing procedure of the detection method may be omitted.

The time interval at which the air conditioning history data is acquired can be set as appropriate. In this embodiment, for example, air conditioning history data is acquired at time intervals of 5 to 30 minutes (10 minutes in this example). Further, the period for acquiring the air conditioning history data can be appropriately set. In order to reliably detect a malfunction of the air conditioning system 8, it is desirable that the air conditioning history data is continuously acquired, for example, for 30 to 90 days. In step S1, the past air conditioning history data acquired at the above time intervals in the above period is taken into the history data storage unit 34a (that is, the computer 27).

FIG. 6A is a graph showing an example of air conditioning history data of one space 5 included in the first group 7A. FIG. 6B is a graph showing an example of air conditioning history data of one space 5 included in the second group 7B. FIGS. 6A and 6B show the relationship between the target temperature and the actual temperature and the time, and the temperature of the suction port (not shown) and the temperature of the outlet (not shown) of the air conditioner 9 are shown. , The rotation speeds of the first fan 12a and the second fan 12b are omitted.

Next, in the detection method of the present embodiment, it is determined whether or not there is a defect in the air conditioning system 8 (determination step S2). In the determination step S2 of the present embodiment, it is determined whether or not there is a defect in the air conditioning system 8 based on the relationship between the target temperature of the air conditioning history data and the actual temperature. The relationship between the target temperature and the actual temperature can be obtained as appropriate. The relationship of the present embodiment is the time change of the temperature difference D (shown in FIGS. 6A and 6B) between the target temperature and the actual temperature. Such a relationship is acquired in each space 5 (in this example, the spaces 5a and 5b on the first floor and the spaces 5c and 5d on the second floor shown in FIG. 1).

In FIG. 6A, the temperature difference D in the space of the first group increases with the passage of time. On the other hand, in FIG. 6B, the temperature difference D in the space of the second group becomes smaller with the passage of time. In this way, the temperature difference D changes with the passage of time. FIG. 7 is a flowchart showing an example of the processing procedure of the determination step S2.

In the determination step S2 of the present embodiment, first, the air-conditioning defective space is specified (step S21). In step S21, the space 5 in which the temperature difference D increases with the passage of time (for example, the space of the first group shown in FIG. 6A) is specified as a space with poor air conditioning. In step S21, first, as shown in FIGS. 3 and 4, the air conditioning history data stored in the history data storage unit 34a and the space specifying unit 38 of the program unit 35 are input to the work memory 33. To. Then, the space specifying unit 38 of the determination unit 37 is executed by the arithmetic unit 31 (that is, the computer 27).

In step S21, first, the relationship between the target temperature and the actual temperature (in this example, the spaces 5a and 5b on the first floor and the spaces 5c and 5d on the second floor) based on the air conditioning history data of each space 5 (in this example). That is, the time change of the temperature difference D) is acquired. The relationship between the target temperature and the actual temperature is stored in the relationship storage unit 34b (shown in FIG. 3).

As shown in FIG. 6A, in the space 5 in which the temperature difference D increases with the passage of time, the actual temperature deviates from the target temperature set by the user. As described above, since the air conditioning system of the present embodiment is controlled so that the actual temperature of each space 5 approaches the target temperature, the space in which the air conditioning history data as shown in FIG. 6A is acquired. In 5, it can be inferred that there is a problem with the air conditioning. Based on such a viewpoint, in step S21, the space 5 in which the temperature difference D increases with the passage of time is specified as a space with poor air conditioning. As shown in FIG. 6B, the space 5 in which the temperature difference D becomes smaller with the passage of time is air-conditioned according to the above control, so it can be inferred that there is no problem in air conditioning. ..

The determination criteria for specifying the air-conditioned poor space can be appropriately set as long as the space 5 in which the temperature difference D increases with the passage of time can be specified. In step S21 of the present embodiment, for example, in consideration of the influence on the actual temperature due to the opening and closing of the door of the user, the average value of the absolute values of the temperature difference D is a predetermined threshold value (for example, 2.0 to A space 5 larger than 3.0 ° C.) is specified as a space with poor air conditioning. The average value can be calculated as appropriate, and it is desirable that, for example, a temperature difference D for a predetermined time (for example, 2 to 4 hours) is used. In step S21, information (for example, a flag) for identifying the air-conditioned defective space is stored in the air-conditioned defective space storage unit 34c (shown in FIG. 3).

Next, in the determination step S2 of the present embodiment, the defective portion is specified based on the combination of the air-conditioned defective spaces (defect specifying step S22). In the defect identification step S22, first, the information for identifying the air-conditioning defective space stored in the air-conditioning defective space storage unit 34c (shown in FIG. 3) and the defect identifying unit 39 shown in FIG. 1 The specific unit 39a, the second specific unit 39b, the third specific unit 39c, and the fourth specific unit 39d) are input to the working memory 33 (shown in FIG. 3). Then, the defect specifying unit 39 of the determination unit 37 is executed by the calculation unit 31. FIG. 8 is a flowchart showing an example of the processing procedure of the defect specifying step S22.

In the defect specifying step S22 of the present embodiment, first, the combination of air conditioning defective spaces is determined (process S31). When the combination of the poorly air-conditioned spaces is all the spaces 5 in the building 2 shown in FIG. 1 (in this example, the spaces 5a and 5b on the first floor and the spaces 5c and 5d on the second floor), all of them. Space 5 is not properly air-conditioned (ie, based on the original control procedure). Therefore, there is a high possibility that the air conditioner 9 (shown in FIG. 1), which affects the air conditioning of all the spaces 5, has a problem. Therefore, in step S31, when the combination of the air-conditioned poor spaces is all the spaces 5 in the building 2, the first specific step S32 for identifying the defect of the air conditioner 9 is carried out.

In the first specific step S32 of the present embodiment, the first specific unit 39a of the determination unit 37 shown in FIG. 4 is executed by the calculation unit 31 (shown in FIG. 3), so that the presence or absence of a defect in the air conditioner 9 is present. Is identified. FIG. 9 is a flowchart showing an example of the processing procedure of the first specific step S32.

In the first specific step S32 of the present embodiment, first, the air conditioning capacity of the air conditioner 9 (shown in FIG. 1) is calculated (step S51). For the air conditioning capacity, for example, the temperature of the suction port (not shown) and the temperature of the outlet (not shown) of the air conditioner 9 included in the air conditioning history data are used in the same procedure as before (for example, Japanese Patent Application Laid-Open No. It can be calculated based on the procedure described in Japanese Patent Application Laid-Open No. 2017-083139. In step S51 of the present embodiment, the air conditioning capacity for the above-mentioned period is calculated for each of the above-mentioned time intervals.

Next, in the first specific step S32, it is determined whether or not the air conditioning capacity of the air conditioner 9 (shown in FIG. 1) is equal to or less than a predetermined threshold value (step S52). In step S52 of the present embodiment, it is determined whether or not the average value of the air conditioning capacity for the above period is equal to or less than the threshold value in consideration of the fluctuation of the air conditioning capacity of the air conditioner 9. The threshold value can be appropriately set based on the air conditioning capacity required for the air conditioner 9. The threshold value of this embodiment is set to, for example, 8 to 11 kW.

In step S52, when the air conditioning capacity of the air conditioner 9 (shown in FIG. 1) is equal to or less than the threshold value (“Y” in step S52), the air conditioning capacity of the air conditioner 9 is reduced. In this case, it is identified that the air conditioner 9 is defective (step S53). In step S53, the air conditioner 9 is stored as a defective portion in the defective portion storage unit 34d (shown in FIG. 3) for storing the defective portion of the air conditioning system 8. It is considered that the cause of the decrease in the air conditioning capacity is, for example, the leakage of the refrigerant of the air conditioner 9 or the installation space of the outdoor unit (not shown) is not secured based on the specifications of the air conditioner 9.

On the other hand, in step S52, when the air conditioning capacity of the air conditioner 9 (shown in FIG. 1) is larger than the threshold value (“N” in step S52), it is determined that the air conditioner 9 has no problem. In this case, the next step S54 is carried out.

Except for the above-mentioned malfunction of the air conditioner 9 (shown in FIG. 1), all the spaces 5 (in this example, the spaces 5a and 5b on the first floor and the spaces 5c and 5c on the second floor shown in FIG. 1). It is considered that the reason why the 5d) is not properly air-conditioned is that, for example, the air-conditioned air A2 is not sufficiently supplied due to the pressure loss due to the clogging of the filter 19 shown in FIG. When such pressure loss occurs, in the air conditioning system 8 of the present embodiment, when the fan 12 is configured as a constant air volume fan, it is shown in FIG. 1 in order to maintain the ventilation frequency required for the building 2. The rotation speed of the fan 12 (in this example, both the first fan 12a and the second fan 12b) increases. Therefore, in step S54, it is determined whether or not the rotation speed of the fan 12 in the air conditioning history data is larger than a predetermined threshold value.

The threshold value can be appropriately set based on the rotation speed of the fan 12 (in this example, the first fan 12a and the second fan 12b) in a state where the filter 19 shown in FIG. 1 is not clogged. Further, in step S54, it is desirable to obtain an average value of the rotation speed of the fan 12 in consideration of the fluctuation of the rotation speed of the fan 12 and compare the average value with the threshold value.

In step S54, when the rotation speed of the fan 12 (first fan 12a and second fan 12b in this example) shown in FIG. 1 is larger than the threshold value (“Y” in step S54), the filter 19 is clogged. There is pressure loss due to. In this case, it is identified that the filter 19 has a defect (step S55). In step S55, the filter 19 is stored as a defect location in the defect location storage unit 34d (shown in FIG. 3).

On the other hand, in step S54, when the rotation speed of the fan 12 is equal to or less than the threshold value (“N” in step S54), the pressure loss as described above does not occur, and the defect of the air conditioning system 8 cannot be identified. In this case, a series of processes in the first specific step S32 is completed. As described above, when the defect of the air conditioning system 8 cannot be identified in the step S54, the judgment history so far (in this example, the comparison result between the air conditioning capacity and the threshold value and the comparison between the rotation speed of the fan 12 and the threshold value). The result, etc.) may be input to the defect location storage unit 34d (shown in FIG. 3). Such a determination history is useful, for example, in creating a new procedure for determining a defect in the air conditioning system 8 when a defect is found in the air conditioning system 8. By adding this new procedure to the first specific process S32 shown in FIG. 9, the defect detection accuracy can be improved.

Next, as shown in FIG. 8, in the defect specifying step S22 of the present embodiment, in the step S31, the combination of the air-conditioned defective spaces is the all spaces 5a and 5b of the first group 7A shown in FIG. 1, or If it is determined that all the spaces 5c and 5d of the second group 7B, the second specific step S33 is carried out.

The reason why all the spaces 5a and 5b of the first group 7A or all the spaces 5c and 5d of the second group 7B are not properly air-conditioned is that, for example, the second fan 12b is connected to the first group 7A and It is considered that the air-conditioned air A2 cannot be sent to the first group 7A and the second group 7B based on the original control because the first fan 12a is connected to the second group 7B.

From such a viewpoint, in the second specific step S33, a defect of the first fan 12a or the second fan 12b is specified. In the second specific step S33 of the present embodiment, the second specific unit 39b of the determination unit 37 shown in FIG. 4 is executed by the calculation unit 31 (shown in FIG. 3), so that the first fan 12a or the second fan The presence or absence of a defect in 12b is specified. FIG. 10 is a flowchart showing an example of the processing procedure of the second specific step S33.

In the second specific step S33 of the present embodiment, first, the relationship between the rotation speed of the first fan 12a of the air conditioning history data and the temperature difference D of the second group (hereinafter, simply referred to as "first relationship"). Is required (step S61). 11 (a) and 11 (b) are graphs showing an example of the relationship between the rotation speed of the first fan 12a and the temperature difference of the second group 7B and time. In FIGS. 11A and 11B, the temperature difference D of the second group 7B is obtained by averaging the absolute values of the temperature differences of the second floor spaces 5c and 5d of the second group 7B.

The first relationship (relationship between the rotation speed of the first fan 12a and the temperature difference D of the second group) can be appropriately acquired. The first relationship of the present embodiment is required to be the relationship between the rate of increase in the rotation speed of the first fan 12a and the rate of increase in the temperature difference D of the second group. The rate of increase can be calculated as appropriate. In the present embodiment, it is calculated by using the respective rotation speeds and temperature difference D at the start and end of the predetermined period (for example, 2 to 4 hours). The first relationship is stored in the relationship storage unit 34b.

Next, in the second specific step S33 of the present embodiment, the relationship between the rotation speed of the second fan 12b of the air conditioning history data and the temperature difference D of the first group (hereinafter, simply referred to as “second relationship”). Is required (step S62). The second relationship (relationship between the rotation speed of the second fan 12b and the temperature difference D of the first group) can be appropriately acquired. The second relationship of the present embodiment is required to be the relationship between the rate of increase in the rotation speed of the second fan 12b and the rate of increase in the temperature difference D of the first group. The rate of increase can be calculated in the same manner as in step S61. The second relationship is stored in the relationship storage unit 34b.

Next, in the second specific step S33 of the present embodiment, the first relationship (relationship between the rotation speed of the first fan 12a and the temperature difference D of the second group) or the second relationship (second relationship). Based on the relationship between the rotation speed of the fan 12b and the temperature difference D of the first group 7A), it is determined whether or not there is a defect in the first fan 12a or the second fan 12b (step S63).

For example, when the first fan 12a is erroneously connected to the second group 7B, as shown in FIG. 11A, when the increase rate of the rotation speed of the first fan 12a increases, the second group 7B is connected. The amount of air-conditioned air A2 sent increases. As a result, for example, when the actual temperature of the space of the second group 7B does not reach the target temperature (in this example, during heating), the temperature difference D of the second group becomes smaller and the temperature difference D increases. The rate drops.

On the other hand, as shown in FIG. 11B, when the rate of increase in the rotation speed of the first fan 12a decreases, the amount of air-conditioned air A2 sent to the second group 7B decreases. As a result, when the actual temperature of the space of the second group 7B does not reach the target temperature (in this example, during heating), the temperature difference D becomes large, and the rate of increase of the temperature difference D increases.

In this way, when the first fan 12a is erroneously connected to the second group 7B and the actual temperature of the space 5 of the second group 7B does not reach the target temperature (in this example, during heating). , There is an antinomy relationship between the rotation speed of the first fan 12a and the temperature difference D of the second group. Even during cooling, if the actual temperature of the space of the second group 7B does not reach the target temperature, there is an antinomy relationship as in the case of heating. Since such an antinomy relationship is contrary to the air conditioning control aimed at by the air conditioning system 8, there is a problem in the first relationship.

After the actual temperature of the space 5 of the second group 7B reaches the target temperature, unlike the above-mentioned antinomy relationship, for example, when the rate of increase in the rotation speed of the first fan 12a increases, the second is The rate of increase in the temperature difference D of the two groups 7B also increases. Since such a relationship also violates the air conditioning control aimed at by the air conditioning system 8, there is a problem in the first relationship.

Similarly, when the second fan 12b is erroneously connected to the first group 7A and the actual temperature of the space 5 of the first group 7A does not reach the target temperature (in this example, during heating), There is an antinomy relationship between the rotation speed of the second fan 12b and the temperature difference D of the first group 7A. Since such an antinomy relationship is contrary to the air conditioning control aimed at by the air conditioning system 8, there is a problem in the second relationship.

After the actual temperature of the space 5 of the first group 7A reaches the target temperature, unlike the above-mentioned antinomy relationship, for example, when the increase rate of the rotation speed of the second fan 12b increases, the first is The rate of increase in the temperature difference D of 1 group 7A also increases. Such a relationship also violates the air conditioning control aimed at by the air conditioning system 8, and therefore has a problem in the second relationship.

In step S63, the relationship (first relationship) between the rotation speed of the first fan 12a and the temperature difference D of the second group, or the temperature difference D between the rotation speed of the second fan 12b and the temperature difference D of the first group 7A. It is determined whether or not there is a problem in the relationship (second relationship) with.

When it is determined in step S63 that there is a problem with the first relationship or the second relationship (“Y” in step S63), the first fan 12a or the second fan 12b shown in FIG. 1 is erroneously connected. It is highly possible that it has been done. In this case, it is specified that the first fan 12a or the second fan 12b has a defect (step S64).

In step S64, if it is determined that there is a problem with the first relationship, it is identified that the first fan 12a (shown in FIG. 1) has a problem. On the other hand, if it is determined that there is a problem with the second relationship, it is identified that the second fan 12b (shown in FIG. 1) has a problem. In step S64 of the present embodiment, the first fan 12a or (and) the second fan 12b is stored as a defect location in the defect location storage unit 34d (shown in FIG. 3).

On the other hand, when it is determined in step S63 that there is no problem with the first relationship and the second relationship (“N” in step S63), the first fan 12a and the second fan 12b shown in FIG. 1 have a problem. It is judged that there is no such thing. In this case, the next step S65 is carried out.

Except for the above-mentioned connection failure of the first fan 12a and the second fan 12b (shown in FIG. 1), the reason why the first group 7A or the second group 7B (shown in FIG. 1) is not properly air-conditioned is For example, for each duct 14a or 14b shown in FIG. 1, crushing or the like occurs in the region from the first fan 12a or the second fan 12b to the branch portions 25, 25, and the air-conditioned air A2 becomes the first due to pressure loss. It is considered that the supply is not sufficiently supplied to the 1st group 7A or the 2nd group 7B. When such pressure loss occurs, when the fan 12 is configured as a constant air volume fan as in the present embodiment, the fan 12 (in this example, in this example) is used to maintain the ventilation speed required for the building 2. , Both the first fan 12a and the second fan 12b) increase in rotation speed. Therefore, in step S65, it is determined whether or not the rotation speed of the fan 12 is larger than a predetermined threshold value. The threshold value can be set in the same manner as in step S54.

In step S65, when the rotation speed of the fan 12 (in this example, the first fan 12a or the second fan 12b shown in FIG. 1) is larger than the threshold value (“Y” in step S65), it is shown in FIG. There is a high possibility that the duct 14a or 14b is crushed or the like. In this case, it is identified that the duct 14a or 14b has a defect (step S66). In step S66, the duct 14a or 14b is stored as a defect location in the defect location storage unit 34d (shown in FIG. 3).

On the other hand, in step S65, when the rotation speed of the fan 12 (in this example, the first fan 12a and the second fan 12b shown in FIG. 1) is equal to or less than the threshold value (“N” in step S65), as described above. No pressure loss has occurred, and a defect in the air conditioning system 8 cannot be identified. In this case, a series of processes in the second specific step S33 is completed. As described above, when the defect of the air conditioning system 8 cannot be identified, the determination history so far may be input to the defect location storage unit 34d (shown in FIG. 3).

Next, as shown in FIG. 8, in the defect specifying step S22 of the present embodiment, in the step S31, the combination of the air-conditioned defective spaces is the all spaces 5 and the first group 7A of the first group 7A shown in FIG. When it is determined that the combination of the air-conditioned poor spaces is not all the spaces 5 of the two groups 7B but two or more spaces 5, the third specific step S34 is carried out.

The reason why the two or more spaces 5 are not properly air-conditioned is considered to be, for example, that the connection of the damper 13 and the temperature sensor 11 shown in FIGS. 1 and 2 to the control means 15 is not appropriate. Appropriate connection means that the damper 13 connected to the control means 15 and the space 5 provided with the temperature sensor 11 (for example, one space 5a on the first floor) and the damper 13 recognized by the control means 15. And the space 5 in which the temperature sensor 11 is provided (for example, one space 5a on the first floor) coincides with the space 5. On the other hand, when the connection is not appropriate, for example, the damper 13 and the temperature sensor 11 should be provided in one space 5a on the first floor, but are provided in the other space 5b on the first floor.

If the connection of the damper 13 shown in FIGS. 1 and 2 is not appropriate, the control means 15 cannot control the opening degree of the damper 13, and therefore the space 5 in which the damper 13 is provided cannot be properly air-conditioned. On the other hand, if the connection of the temperature sensor 11 shown in FIGS. 1 and 2 is not appropriate, the control means 15 cannot correctly measure the temperature of the space 5 in which the temperature sensor 11 is provided, so that the space 5 is used. It cannot be properly air-conditioned.

From this point of view, in the third specific step S34 of the present embodiment, a defect of the damper 13 or the temperature sensor 11 shown in FIGS. 1 and 2 is identified. In the third specific step S34 of the present embodiment, the third specific unit 39c of the determination unit 37 shown in FIG. 4 is executed by the calculation unit 31 (shown in FIG. 3), and is shown in FIGS. 1 and 2. A defect in the damper 13 or the temperature sensor 11 is identified. FIG. 12 is a flowchart showing an example of the processing procedure of the third specific step S34.

In the third specific step S34 of the present embodiment, first, it is determined whether or not there is an error in the connection of the damper 13 or the temperature sensor 11 shown in FIGS. 1 and 2 (step S71). In step S71, the plan information stored in the plan information storage unit 34e (shown in FIG. 3) is used. The plan information of this embodiment is the design information of the building 2. In this plan information, information regarding the connection of the damper 13 of each space 5 (in this example, the spaces 5a and 5b on the first floor and the spaces 5c and 5d on the second floor shown in FIG. 1) and each space 5 are included. Contains information about the connection of the temperature sensor 11.

The information regarding the connection of the damper 13 of the present embodiment includes, for example, the damper 13 of each space 5 (in this example, the spaces 5a and 5b on the first floor and the spaces 5c and 5d on the second floor shown in FIG. 1). With respect to wiring cords (not shown) that connect to the control means 15, the positions of the terminals of the control means 15 to which those cords are connected are shown. With such information, the relationship between the damper 13 actually connected to the control means 15 and the damper 13 recognized by the control means 15 can be specified.

Information regarding the connection of the temperature sensor 11 is, for example, the temperature sensor 11 and the control means 15 of each space 5 (in this example, the spaces 5a and 5b on the first floor and the spaces 5c and 5d on the second floor shown in FIG. 1). The positions of the terminals of the control means 15 to which these cords are connected are shown with respect to the wiring cords (not shown) and the like for connecting the cords and the like. With such information, the relationship between the temperature sensor 11 actually connected to the control means 15 and the temperature sensor 11 recognized by the control means 15 can be specified. Further, the information regarding the connection of the temperature sensor 11 may include the position where the temperature sensor 11 is installed in each space 5.

In step S71, whether the damper 13 and the temperature sensor 11 actually connected to the control means 15 and the damper 13 and the temperature sensor 11 recognized by the control means 15 match based on the above plan information. Whether or not it is judged. If the damper 13 and the temperature sensor 11 do not match, the damper 13 or the temperature sensor 11 is erroneously connected.

In step S71, when it is determined that the connection of the damper 13 or the temperature sensor 11 shown in FIG. 1 is incorrect (“Y” in step S71), a defect in the damper 13 or the temperature sensor 11 is identified (step). S72). In step S72, the damper 13 or the temperature sensor 11 is stored as the defective portion in the defective portion storage unit 34d (shown in FIG. 3).

On the other hand, if it is determined in step S71 that there is no error in the connection between the damper 13 and the temperature sensor 11 (“N” in step S71), the next step S73 is carried out.

Except for the above-mentioned malfunction of the damper 13 or the temperature sensor 11, the reason why the two or more spaces 5 are not properly air-conditioned is, for example, for each duct 14a or 14b shown in FIG. It is conceivable that crushing or the like occurs in the region from 25 to each damper 13, and the air-conditioned air A2 is not sufficiently supplied due to pressure loss. When such pressure loss occurs, the rotation speed of the fan 12 (in this example, the first fan 12a or the second fan 12b) increases. Therefore, in step S73, it is determined whether or not the rotation speed of the fan 12 is larger than a predetermined threshold value. The threshold value can be set in the same manner as in step S65.

In step S73, when the rotation speed of the fan 12 (in this example, the first fan 12a or the second fan 12b) is larger than the threshold value (“Y” in step S73), the duct 14 may be crushed or the like. Highly sex. In this case, it is identified that the duct 14 has a defect (step S74). In step S74, the fan 12 is stored as a defect location in the defect location storage unit 34d (shown in FIG. 3).

On the other hand, in step S73, when the rotation speed of the fan 12 is equal to or less than the threshold value (“N” in step S73), the pressure loss as described above does not occur, and the defect of the air conditioning system 8 cannot be identified. In this case, a series of processes in the third specific step S34 is completed. As described above, when the defect of the air conditioning system 8 cannot be identified, the determination history so far may be input to the defect location storage unit 34d (shown in FIG. 3).

Next, as shown in FIG. 8, in the defect specifying process S22 of the present embodiment, when it is determined in the process S31 that the combination of the air-conditioned defective spaces is one space 5 (shown in FIG. 3). The fourth specific step S35 is carried out.

As a cause of not properly air-conditioning one space 5, for example, a malfunction of the temperature sensor 11 can be considered. As an example of this problem, the temperature sensor 11 is obstructed by an obstacle such as furniture, so that the temperature of the space 5 cannot be accurately measured, and the control means 15 cannot appropriately control the supply of the air-conditioned air A2. Can be considered.

If one space 5 is not properly air-conditioned, unlike the case where two or more spaces 5 are not properly air-conditioned as described above, there is a possibility that the connection between the damper 13 and the temperature sensor 11 is incorrect. It is considered low. This is because if there is an error in the connection of the damper 13 or the temperature sensor 11 in one space 5, the connection of the damper 13 or the temperature sensor 11 in the other space 5 is inevitably incorrect, so two or more spaces 5 are appropriate. This is because it will not be air-conditioned.

From this point of view, in the fourth specific step S35 of the present embodiment, the fourth specific step S35 for identifying the defect of the temperature sensor 11 is carried out. In the fourth specific step S35 of the present embodiment, the failure of the temperature sensor 11 is identified by executing the fourth specific unit 39d of the determination unit 37 shown in FIG. 4 by the calculation unit 31 (shown in FIG. 3). To. FIG. 13 is a flowchart showing an example of the processing procedure of the fourth specific step S35.

In the fourth specific step S35 of the present embodiment, first, it is determined whether or not there is an error in the installation position of the temperature sensor 11 (step S81). In step S81, the plan information stored in the plan information storage unit 34e (shown in FIG. 3) is used. The plan information of the present embodiment includes information regarding the installation of the temperature sensor 11 in each space 5 (in this example, the spaces 5a and 5b on the first floor and the spaces 5c and 5d on the second floor shown in FIG. 1). It has been. This information includes, for example, the position information in which the temperature sensor 11 is installed in each space 5.

In step S81, based on the above plan information, for example, the distance and positional relationship between an obstacle such as furniture and the temperature sensor 11 are obtained, and whether or not there is an error in the installation position of the temperature sensor 11 is determined. Judged. When it is determined in step S81 that the installation position of the temperature sensor 11 is incorrect (“Y” in step S81), a defect of the temperature sensor 11 is identified (step S82). In step S82, the temperature sensor 11 is stored as a defect location in the defect location storage unit 34d (shown in FIG. 3).

On the other hand, if it is determined in step S81 that there is no error in the installation position of the temperature sensor 11 (shown in FIG. 1) (“N” in step S81), the next step S83 is carried out.

Except for the above-mentioned malfunction of the temperature sensor 11 (shown in FIG. 1), the reason why one space 5 is not properly air-conditioned is, for example, for each duct 14a or 14b shown in FIG. It is considered that the air-conditioned air A2 is not sufficiently supplied due to the pressure loss due to crushing or the like occurring in the region from 25 to each damper 13. When such pressure loss occurs, the rotation speed of the fan 12 (in this example, the first fan 12a or the second fan 12b) increases. Therefore, in step S83, it is determined whether or not the rotation speed of the fan 12 is larger than a predetermined threshold value. The threshold value can be set in the same manner as in step S65.

In step S83, when the rotation speed of the fan 12 (in this example, the first fan 12a or the second fan 12b) is larger than the threshold value (“Y” in step S83), the duct 14 may be crushed or the like. Highly sex. In this case, it is identified that the duct 14 has a defect (step S84). In step S84, the fan 12 is stored as a defect location in the defect location storage unit 34d (shown in FIG. 3).

On the other hand, in step S83, when the rotation speed of the fan 12 is equal to or less than the threshold value (“N” in step S83), the pressure loss as described above does not occur, and the defect of the air conditioning system 8 cannot be identified. In this case, a series of processes in the fourth specific step S35 is completed. As described above, when the defect of the air conditioning system 8 cannot be identified, the determination history so far may be input to the defect location storage unit 34d (shown in FIG. 3).

Next, as shown in FIG. 8, in the defect specifying step S22 of the present embodiment, when it is determined in the process S31 that there is no air-conditioned defective space, the aged deterioration determination step S36 is carried out. In the aging deterioration determination step S36 of the present embodiment, for example, the presence or absence of aging deterioration of the air conditioner 9, the fan 12, or the duct 14 (in this example, all of them) constituting the air conditioning system 8 shown in FIG. 1 is determined. Will be done.

In the aging deterioration determination step S36, the presence or absence of aging deterioration is determined by executing the aging deterioration determination unit 40 of the determination unit 37 shown in FIG. 4 by the calculation unit 31 (shown in FIG. 1). FIG. 14 is a flowchart showing an example of the processing procedure of the aging deterioration determination step S36.

The aged deterioration of the air conditioner 9 is determined based on the air conditioning capacity. In the aging deterioration determination step S36 of the present embodiment, first, the air conditioning capacity of the air conditioner 9 (shown in FIG. 1) is calculated (step S91), and whether or not the air conditioning capacity is equal to or less than a predetermined threshold value is determined. It is determined (step S92). The calculation method of the air conditioning capacity is as described above. Further, the threshold value can be appropriately set, and for example, it can be set to the same threshold value as in step S52.

In step S92, when the air conditioning capacity is equal to or less than the threshold value (“Y” in step S92), it is determined that the air conditioner 9 has deteriorated over time (step S93). In step S93, the air conditioner 9 is stored in the defective part storage unit 34d (shown in FIG. 3) as a part of aged deterioration. On the other hand, in step S92, when the air conditioning capacity is larger than the threshold value (“N” in step S92), it is determined that the air conditioner 9 has not deteriorated over time. In this case, the next step S94 is carried out.

The aged deterioration of the fan 12 (in this example, the first fan 12a or the second fan 12b) and the duct 14 (in this example, the duct 14a or 14b) shown in FIG. 1 is based on the rotation speed of the fan 12 in the air conditioning history data. Judgment is based on. An example of aging deterioration of the fan 12 includes shaft shake of the fan 12. When the shaft shake of the fan 12 occurs, the rotation speed of the fan 12 becomes unstable. In order to determine the presence or absence of such axial shake of the fan 12, in step S94, it is determined whether or not the range between the upper limit value and the lower limit value of the rotation speed of the fan 12 is larger than a predetermined threshold value. To. The threshold value can be appropriately set based on the specifications of the fan 12.

In step S94, when the range of rotation speeds of the fan 12 (in this example, the first fan 12a or the second fan 12b) is larger than the threshold value (“Y” in step S94), the fan 12 has deteriorated over time. (Step S95). In step S95, the fan 12 is stored in the defective part storage unit 34d (shown in FIG. 3) as a part of aged deterioration. On the other hand, in step S94, when the range of the rotation speed of the fan 12 is equal to or less than the threshold value (“N” in step S94), it is determined that the fan 12 has not deteriorated over time. In this case, the next step S96 is carried out.

As an example of the aged deterioration of the duct 14 (in this example, the duct 14a or 14b) shown in FIG. 1, the duct 14 is crushed, the duct 14 is torn, and the like. For example, when the fan 12 is configured as a constant air volume fan as in the present embodiment, if the first duct 14a is crushed, pressure loss occurs and the rotation speed of the first fan 12a increases. Similarly, when the second duct 14b is crushed, the rotation speed of the second fan 12b increases. On the other hand, if the first duct 14a is torn, the air-conditioned air A2 leaks from the duct 14, so that it is determined that the air volume of the first fan 12a is larger than necessary, and the rotation speed of the first fan 12a. Becomes smaller. Similarly, if the second duct 14b is torn, the rotation speed of the second fan 12b becomes smaller.

When the fan 12 is not configured as a constant air volume fan, if the duct 14 is crushed, the rotation speed of the fan 12 decreases, contrary to the constant air volume fan. On the other hand, if the duct 14 is torn, the rotation speed of the fan 12 increases.

Therefore, in step S96, it is determined whether or not the rotation speed of the fan 12 (in this example, the first fan 12a and the second fan 12b) is out of the predetermined threshold range. The threshold value can be set as appropriate, and can be set, for example, by the same procedure as in step S54.

In step S96, when the rotation speed of the fan 12 is out of the predetermined threshold range (“Y” in step S96), it is determined that the duct 14 has deteriorated over time (crushed or torn). (Step S97). In step S97, the duct 14 is stored in the defective part storage unit 34d (shown in FIG. 3) as a part of aged deterioration. On the other hand, in step S96, when the rotation speed of the fan 12 is within a predetermined threshold range (“N” in step S96), the duct 14 has not deteriorated over time. In this case, a series of processes of the aging deterioration determination step S36 and the defect identification step S22 are completed.

Next, in the detection method of the present embodiment, as shown in FIG. 5, it is determined whether or not there is a defect in the air conditioning system 8 (step S3). In step S3, the defect location (including the aged deterioration portion) stored in the defect location storage unit 34d shown in FIG. 3 and the determination unit 37 of the program unit 35 are input to the work memory 33. .. Then, the determination unit 37 is executed by the calculation unit 31.

If it is determined in step S3 that the air conditioning system 8 has a defect (“Y” in step S3), repair or the like of the defective portion (including the aged deterioration portion) is carried out (process S4). Repair of the defective part is carried out, for example, by dispatching a contractor corresponding to the defective part to the building 2.

In the determination step S2, if the defect of the air conditioning system 8 cannot be identified and the determination history is stored in the defect location storage unit 34d, for example, an operator or the like analyzes the determination history and the defect location. Is desirable to be identified.

On the other hand, when it is determined in step S3 that there is no problem with the air conditioning system 8 (“N” in step S3), a series of processes of the detection method is completed. The detection method of the present embodiment may be started manually by, for example, a user, an operator, or the like, or may be automatically executed every arbitrary period.

As described above, the detection method (detection device 26) of the present embodiment takes in the air conditioning history data of the air conditioning system 8 and determines whether or not there is a defect in the air conditioning system 8 based on the relationship between the target temperature and the actual temperature. can do. Therefore, the detection method (detection device 26) of the present embodiment can detect a defect of the air conditioning system 8 at an early stage.

Further, in the detection method of the present embodiment, even if the malfunction of the air conditioning system 8 is not specified, the deterioration of the air conditioner 9 and the like over time can be determined, so that the malfunction of the air conditioning system 8 can be prevented.

As shown in FIG. 14, in the aged deterioration determination step S36 of the previous embodiments, it was determined whether or not the air conditioner 9, the fan 12, and the duct 14 shown in FIG. 1 have aged deterioration. The aspect is not limited, and for example, aged deterioration (clogging, etc.) of the filter 19 may be determined. As described above, when the filter 19 is clogged, the fan 12 (both the first fan 12a and the second fan 12b in this example) is used to maintain the ventilation speed required for the building 2. The number of rotations increases. Therefore, in the aging deterioration determination step S36, the presence or absence of aging deterioration of the filter 19 is determined by determining whether or not the rotation speed of the fan 12 in the air conditioning history data is larger than a predetermined threshold value. Can be done.

Although the particularly preferred embodiment of the present invention has been described in detail above, the present invention is not limited to the illustrated embodiment and can be modified into various embodiments.

S1 Process of importing air conditioning history data S2 Process of determining whether or not there is a problem with the air conditioning system

Claims (21)

Air air-conditioned by one heat source composed of one air conditioner is sent to multiple spaces in the building, causing a malfunction of the central air-conditioning type air-conditioning system for air-conditioning the multiple spaces. It ’s a way to detect
In the air conditioning system, the actual temperature of each of the plurality of spaces is measured by a temperature sensor, and the actual temperature is controlled so as to approach a target temperature set by the user.
The method includes a step of taking in past air conditioning history data including at least the target temperature and the actual temperature for each of the plurality of spaces at predetermined time intervals.
Including a step of determining whether or not there is a defect in the air conditioning system based on the relationship between the target temperature and the actual temperature of the air conditioning history data.
The relationship is a time change of the temperature difference between the target temperature and the actual temperature.
The determination process includes a process of specifying a space in which the temperature difference increases with the passage of time as a space with poor air conditioning.
Including a defect specifying step of identifying the location of the defect based on the combination of the air-conditioned defective spaces.
How to detect problems in the air conditioning system.
In the process of importing, the air conditioning history data is imported into a computer.
The method for detecting a defect in an air conditioning system according to claim 1, wherein the determination step is executed by the computer. The defect specifying step according to claim 1 or 2, wherein the defect specifying step includes a first specifying step for identifying a defect of the air conditioner when the combination of the air conditioning defective spaces is all the spaces in the building. How to detect problems in the air conditioning system. The air conditioning history data includes the temperature of the suction port and the temperature of the outlet of the air conditioner.
The first specific step includes a step of calculating the air conditioning capacity of the air conditioner based on the temperature of the suction port and the temperature of the outlet of the air conditioning history data.
The method for detecting a defect in an air conditioning system according to claim 3 , further comprising a step of identifying that the air conditioner has a defect when the air conditioning capacity is equal to or less than a predetermined threshold value . The air-conditioning system includes a first fan that sends air conditioned by the air conditioner to a first group composed of a part of the plurality of spaces, and the first of the plurality of spaces. The second group, which is composed of a space different from the space of the group, includes the second fan for sending the conditioned air.
In the defect identification step, when the combination of the air-conditioned defective spaces is all the spaces of the first group or all the spaces of the second group, the defect of the first fan or the second fan is caused. The method for detecting a defect in an air conditioning system according to any one of claims 1 to 4, which includes a second specific step to be specified . The air conditioning history data includes the rotation speeds of the first fan and the second fan, respectively.
In the second specific step, the relationship between the rotation speed of the first fan in the air conditioning history data and the temperature difference of the second group, or the rotation speed of the second fan in the air conditioning history data. The method for detecting a defect in an air conditioning system according to claim 5, wherein a defect of the first fan or the second fan is specified based on the relationship between the first group and the temperature difference . The air conditioning system includes a damper for adjusting the air volume of each of the plurality of spaces.
In the defect identification step, the combination of the air-conditioned defective spaces is not all the spaces of the first group and all the spaces of the second group, but the combination of the air-conditioned defective spaces is two or more spaces. The method for detecting a defect in an air conditioning system according to claim 5 or 6, further comprising a third specific step of identifying a defect in the damper or the temperature sensor . The third specific step identifies a defect of the damper or the temperature sensor based on the plan information including the information regarding the connection of the damper in the plurality of spaces and the information regarding the connection of the temperature sensor. 7. The method for detecting a defect in the air conditioning system according to 7. The air conditioning system according to any one of claims 1 to 8, wherein the defect specifying step includes a fourth specific step for identifying a defect of the temperature sensor when the combination of the air conditioning defective spaces is one space. Defect detection method. The method for detecting a defect in an air conditioning system according to claim 9 , wherein the fourth specific step identifies a defect in the temperature sensor based on plan information including information on installation of the temperature sensor . The air conditioning system includes a fan that sends air conditioned by the air conditioner to the plurality of spaces, and a duct that connects the fan and the space.
The method for detecting a defect in an air conditioning system according to claim 1, wherein the determination step includes an aging deterioration determination step for determining the presence or absence of aging deterioration of the air conditioner, the fan, or the duct . Air air-conditioned by one heat source composed of one air conditioner is sent to multiple spaces in the building, causing a malfunction of the central air-conditioning type air-conditioning system for air-conditioning the multiple spaces. A device that has an arithmetic processing device to detect
In the air conditioning system, the actual temperature of each of the plurality of spaces is measured by a temperature sensor, and the actual temperature is controlled so as to approach a target temperature set by the user.
The arithmetic processing device includes a history data acquisition unit that captures past air conditioning history data including at least the target temperature and the actual temperature for each of the plurality of spaces at predetermined time intervals.
Including a determination unit for determining whether or not there is a defect in the air conditioning system based on the relationship between the target temperature and the actual temperature in the air conditioning history data.
The relationship is a time change of the temperature difference between the target temperature and the actual temperature.
The determination unit includes a space identification unit that identifies a space in which the temperature difference increases with the passage of time as a space with poor air conditioning.
Includes a defect identification unit that identifies the location of the defect based on the combination of the air-conditioning defective spaces.
Defect detection device for air conditioning system. The air conditioning system according to claim 12, wherein the defect specifying unit includes a first specifying unit that identifies a defect of the air conditioner when the combination of the air conditioning defective spaces is all the spaces in the building. Defect detection device . The air conditioning history data includes the temperature of the suction port and the temperature of the outlet of the air conditioner.
The first specific unit calculates the air conditioning capacity of the air conditioner based on the temperature of the suction port and the temperature of the air outlet of the air conditioning history data, and the air conditioning capacity is equal to or less than a predetermined threshold value. The defect detection device for the air conditioning system according to claim 13, wherein the air conditioner is identified as having a defect in the case of . The air-conditioning system includes a first fan that sends air conditioned by the air conditioner to a first group composed of a part of the plurality of spaces, and the first of the plurality of spaces. The second group, which is composed of a space different from the space of the group, includes the second fan for sending the conditioned air.
When the combination of the air-conditioned defective spaces is all the spaces of the first group or all the spaces of the second group, the defect specifying unit causes a defect of the first fan or the second fan. The defect detection device for an air conditioning system according to any one of claims 12 to 14, which includes a second specific unit to be specified . The air conditioning history data includes the rotation speeds of the first fan and the second fan, respectively.
The second specific unit is the relationship between the rotation speed of the first fan of the air conditioning history data and the temperature difference of the second group, or the rotation speed of the second fan of the air conditioning history data. The defect detection device for an air conditioning system according to claim 15, which identifies a defect of the first fan or the second fan based on the relationship between the first group and the temperature difference . The air conditioning system includes a damper for adjusting the air volume of each of the plurality of spaces.
In the defect identification unit, the combination of the air-conditioned defective spaces is not all the spaces of the first group and all the spaces of the second group, but the combination of the air-conditioned defective spaces is two or more spaces. The defect detection device for an air conditioning system according to claim 15 or 16, wherein the defect detection device for the air conditioning system includes a third specific unit for identifying a defect of the damper or the temperature sensor . The third specific unit identifies a defect of the damper or the temperature sensor based on the plan information including the information regarding the connection of the damper in the plurality of spaces and the information regarding the connection of the temperature sensor. 17. The defect detection device for the air conditioning system according to 17. The air conditioning system according to any one of claims 12 to 18, wherein the defect specifying unit includes a fourth specific unit that identifies a defect of the temperature sensor when the combination of the air conditioning defective spaces is one space. Defect detection device. The defect detection device for an air conditioning system according to claim 19 , wherein the fourth specific unit identifies a defect of the temperature sensor based on plan information including information regarding installation of the temperature sensor . The air conditioning system includes a fan that sends air conditioned by the air conditioner to the plurality of spaces, and a duct that connects the fan and the space.
The defect detection device for an air conditioning system according to any one of claims 12 to 20, wherein the determination unit includes an aging deterioration determination unit for determining the presence or absence of aging deterioration of the air conditioner, the fan, or the duct .

Images