JPWO2020089996A1 - Remote control terminal and air conditioning system - Google Patents

Abstract

The remote control terminal (7) according to the present invention is a remote control terminal of an air conditioner having an indoor unit (10) that blows air into a specific space. The indoor unit (10) includes an image sensor (5) that acquires a first image of a specific space. The remote control terminal (7) includes a communication unit, a display unit (73), and a control unit. The communication unit wirelessly communicates with the indoor unit. The control unit receives the first image from the indoor unit via the communication unit. The control unit has a function of creating a second image which is a three-dimensional image of a specific space based on the first image, and a second image of a three-dimensional airflow distribution (61a) of the specific space derived by simulation based on computational fluid dynamics. It has a function of displaying a composite image (51a) superimposed on the image on the display unit (73).

Description

The present invention relates to a remote control terminal of an air conditioner and an air conditioning system.

Conventionally, a remote control terminal for an air conditioner has been known. For example, Japanese Patent Application Laid-Open No. 2013-76493 (Patent Document 1) discloses an air-conditioning control terminal that displays an image showing an image of wind blown from an indoor unit on a touch panel. In the air conditioning control terminal, the wind direction of the indoor unit is changed based on the operation of touching and moving the image. According to the air conditioning control terminal, the wind direction of the air conditioner can be changed by intuitive operation.

Japanese Unexamined Patent Publication No. 2013-76493

In Patent Document 1, the air conditioner is controlled by using the information in the room where the indoor unit is installed. The arrangement of the room in which the indoor unit is installed may change even during the operation of the indoor unit, for example, when the user moves. As a result, the airflow distribution formed by the indoor unit can change. However, Patent Document 1 does not consider the change in the airflow distribution according to the change in the indoor arrangement during the operation of the indoor unit.

The present invention has been made to solve the above-mentioned problems, and an object of the present invention is to improve the comfort of an air conditioner.

The remote control terminal according to the present invention is a remote control terminal of an air conditioner having an indoor unit that blows air into a specific space. The indoor unit includes an image sensor that acquires a first image of a specific space. The remote control terminal includes a communication unit, a display unit, and a control unit. The communication unit wirelessly communicates with the indoor unit. The control unit receives the first image from the indoor unit via the communication unit. The control unit superimposes the function of creating a second image, which is a three-dimensional image of a specific space, based on the first image, and the three-dimensional airflow distribution of the specific space derived by simulation based on computational fluid dynamics on the second image. It has a function of displaying the composite image on the display unit.

According to the remote control terminal according to the present invention, the air conditioner displays a composite image in which the three-dimensional airflow distribution in a specific space derived by simulation based on computational fluid dynamics is superimposed on the first image. Comfort can be improved.

It is a perspective view which shows an example of the appearance of the indoor unit of the air-conditioning system which concerns on Embodiment 1, and is the figure which shows the state which a user is operating PDA which is an example of a remote control terminal. It is the schematic which shows an example of the circuit structure of the air conditioner which concerns on Embodiment 1. FIG. It is a figure which also shows the functional block diagram which shows an example of the structure of the air conditioner of FIG. 2, and the functional block diagram which shows an example of the structure of a PDA of FIG. It is a figure which shows the state that the bird's-eye view of the room before the operation of an air conditioner is displayed on the display part of a PDA. It is a figure which shows the state that the bird's-eye view of the room when a user is about to start the operation of an air conditioner is displayed on the display part of a PDA. It is a figure which shows the state that the bird's-eye view of the room after the operation of an air conditioner is started is displayed on the display part of a PDA. It is a figure which shows the mesh model corresponding to the state of the room shown in FIG. It is a figure which shows the mesh model corresponding to the state of the room shown in FIG. It is a figure which shows the mesh model corresponding to the state of the room shown in FIG. It is a figure which shows the indoor thermal image seen from the human body in a room. It is a figure which shows the AR thermal image seen from the infrared sensor of the indoor unit 10. It is a flowchart which shows the flow of the preset process performed in PDA prior to the operation of an air conditioner. It is a flowchart which shows the flow of the airflow control processing performed by the control part of PDA of FIG. It is a figure which compares Embodiment 1, the modification of Embodiment 1, and Comparative Examples 1 and 2. It is a figure which shows the instantaneous airflow display time for each of the first embodiment, the modified example of the first embodiment, and the comparative examples 1 and 2. It is a figure which shows the appearance which approximated the human body as a complex of a cylinder and a sphere. It is a figure which compares Embodiments 1 to 4. It is a figure which shows the instantaneous airflow display time for every 1st to 4th Embodiment.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. In principle, the same or corresponding parts in the drawings are designated by the same reference numerals and the description is not repeated.

Embodiment 1.
FIG. 1 is a perspective view showing an example of the appearance of the indoor unit 10 of the air conditioning system 100 according to the first embodiment, and a state in which a user is operating a PDA (Personal Digital Assistant) 7 which is an example of a remote control terminal. It is a figure which shows. The PDA7 is, for example, a smartphone.

As shown in FIG. 1, the indoor unit 10 is a wall-mounted indoor unit installed on a wall surface of the room. The indoor unit 10 is provided with a suction port 1 and an air outlet 2 in a housing forming an outer shell. The suction port 1 is provided to suck in the air in the room (specific space) which is the space to be air-conditioned. The air outlet 2 is provided to send out conditioned air from the air conditioner 1000 having the indoor unit 10 into the room. The blower fan 131 generates an air flow from the suction port 1 to the air outlet 2. The indoor unit 10 blows air into the room from the air outlet 2.

The air outlet 2 is provided with a vertical wind direction plate 3 and a left and right wind direction plate 4. The vertical wind direction plate 3 is rotatably provided in order to adjust the vertical delivery direction when the conditioned air is sent out. The left and right wind direction plates 4 are rotatably provided in order to adjust the horizontal delivery direction when the conditioned air is sent out.

The indoor unit 10 is provided with an infrared sensor 5. In the example shown in FIG. 1, the infrared sensor 5 is provided in the lower part on the left side when viewed from the indoor unit 10 side. The infrared sensor 5 scans the temperature in the room, detects infrared rays radiated from the surface of the object, and acquires the temperature information in the room as a thermal image.

The installation position of the infrared sensor 5 is not limited to the position shown in FIG. For example, the infrared sensor 5 may be installed at a position where it can acquire temperature information in the room. Further, the shape of the infrared sensor 5 is not limited to the shape shown in FIG. 1, and may be any shape as long as the temperature information in the room can be acquired.

The indoor unit 10 is equipped with an indoor communication unit 6 capable of WiFi (registered trademark) communication. The indoor unit 10 is capable of WiFi communication with the PDA 7.

FIG. 2 is a schematic view showing an example of the circuit configuration of the air conditioner 1000 according to the first embodiment. As shown in FIG. 2, the air conditioner 1000 includes an indoor unit 10 and an outdoor unit 20. In the air conditioner 1000, the indoor unit 10 and the outdoor unit 20 are connected by a refrigerant pipe. A refrigeration cycle is formed by the flow of the refrigerant through the refrigerant pipe. The air conditioner 1000 has a cooling mode and a heating mode as operation modes. In the example shown in FIG. 2, the circulation direction of the refrigerant in the cooling mode is shown by a solid line, and the circulation direction of the refrigerant in the heating mode is shown by a dotted line.

In the example of FIG. 2, one indoor unit 10 and one outdoor unit 20 are connected, but the number of indoor units 10 and outdoor units 20 is not limited to this example. For example, a plurality of indoor units 10 may be connected to one outdoor unit 20, or one or a plurality of indoor units 10 may be connected to a plurality of outdoor units 20.

The indoor unit 10 includes an expansion valve 11, an indoor heat exchanger 12, an indoor blower 13, and an indoor control device 30. The expansion valve 11, the indoor heat exchanger 12, the indoor blower 13, and the indoor control device 30 are housed in the housing of the indoor unit 10. The outdoor unit 20 includes a compressor 21, a refrigerant flow path switching device 22, an outdoor heat exchanger 23, an outdoor blower 24, and an outdoor control device 40.

The expansion valve 11 decompresses the refrigerant and expands it. The expansion valve 11 includes, for example, a valve such as an electronic expansion valve whose opening degree can be controlled.

The indoor heat exchanger 12 is the air in the air-conditioned space supplied by the indoor blower 13 including the blower fan 131 that generates the airflow from the suction port 1 to the air outlet 2 (hereinafter, appropriately referred to as “indoor air”). Heat exchange takes place between the air conditioner and the refrigerant. As a result, heating air or cooling air, which are conditioned air supplied to the indoor space, is generated.

In the cooling mode, the indoor heat exchanger 12 functions as an evaporator that evaporates the refrigerant and cools the indoor air by the heat of vaporization of the refrigerant. In the heating mode, the indoor heat exchanger 12 functions as a condenser that dissipates the heat of the refrigerant to the indoor air and condenses the refrigerant.

The indoor control device 30 includes software executed on, for example, a microcomputer or an arithmetic unit such as a CPU (Central Processing Unit), hardware such as a circuit device that realizes various functions, and the like. The indoor control device 30 controls the operation of the entire indoor unit 10 based on, for example, a user-operated setting for the PDA 7 or the remote controller (not shown) in FIG. 1, temperature information from the infrared sensor 5, and the like. The indoor control device 30 controls the driving of the infrared sensor 5 when the temperature information is acquired by the infrared sensor 5.

In the cooling mode, the refrigerant flow path switching device 22 is switched to the state shown by the solid line in FIG. The low-temperature and low-pressure refrigerant is compressed by the compressor 21 and discharged as a high-temperature and high-pressure gas refrigerant. The high-temperature and high-pressure gas refrigerant discharged from the compressor 21 flows into the outdoor heat exchanger 23 via the refrigerant flow path switching device 22. The high-temperature and high-pressure gas refrigerant that has flowed into the outdoor heat exchanger 23 exchanges heat with the outdoor air and condenses while radiating heat, becomes a high-pressure liquid refrigerant in a supercooled state, and flows out of the outdoor heat exchanger 23.

The high-pressure liquid refrigerant flowing out of the outdoor heat exchanger 23 is depressurized by the expansion valve 11 to become a low-temperature low-pressure gas-liquid two-phase refrigerant, which flows into the indoor heat exchanger 12. The low-temperature, low-pressure gas-liquid two-phase refrigerant that has flowed into the indoor heat exchanger 12 exchanges heat with the indoor air, absorbs heat and evaporates to cool the indoor air, and becomes a low-temperature, low-pressure gas refrigerant. Outflow from. The low-temperature low-pressure gas refrigerant flowing out of the indoor heat exchanger 12 passes through the refrigerant flow path switching device 22 and is sucked into the compressor 21.

In the heating mode, the refrigerant flow path switching device 22 is switched to the state shown by the dotted line in FIG. The low-temperature and low-pressure refrigerant is compressed by the compressor 21 and discharged as a high-temperature and high-pressure gas refrigerant. The high-temperature and high-pressure gas refrigerant discharged from the compressor 21 flows into the indoor heat exchanger 12 via the refrigerant flow path switching device 22. The high-temperature and high-pressure gas refrigerant that has flowed into the indoor heat exchanger 12 exchanges heat with the indoor air and condenses while radiating heat, becomes a high-pressure liquid refrigerant in a supercooled state, and flows out of the indoor heat exchanger 12.

The high-pressure liquid refrigerant flowing out of the indoor heat exchanger 12 is depressurized by the expansion valve 11 to become a low-temperature low-pressure gas-liquid two-phase refrigerant, which flows into the outdoor heat exchanger 23. The low-temperature, low-pressure gas-liquid two-phase refrigerant that has flowed into the outdoor heat exchanger 23 exchanges heat with the outdoor air to absorb and evaporate, and becomes a low-temperature, low-pressure gas refrigerant that flows out of the outdoor heat exchanger 23. The low-temperature low-pressure gas refrigerant flowing out of the outdoor heat exchanger 23 passes through the refrigerant flow path switching device 22 and is sucked into the compressor 21.

FIG. 3 is a diagram showing a functional block diagram showing an example of the configuration of the air conditioner 1000 of FIG. 2 and a functional block diagram showing an example of the configuration of the PDA 7 of FIG. As shown in FIG. 3, it includes an indoor control device 30. The indoor control device 30 includes an input circuit 31, an arithmetic processing unit 32, a storage device 33, and an output circuit 34.

The input circuit 31 is input with setting information from a remote controller (not shown), setting information from the PDA 7, temperature information from the infrared sensor 5, control information from the outdoor control device 40, and the like. The setting information from the PDA 7 is input via the indoor communication unit 6. The input circuit 31 outputs various input information to the arithmetic processing unit 32.

The arithmetic processing unit 32 uses the data stored in the storage device 33 to perform various processes based on the information received from the input circuit 31. For example, the arithmetic processing device 32 creates a thermal image showing the temperature state in the room based on the temperature information from the infrared sensor 5, and detects the position of the human body and the temperature of the human body existing in the room based on the thermal image. Perform processing etc.

The arithmetic processing unit 32 generates control information for each operating device provided in the indoor unit 10 and control information for the outdoor unit 20 so as to send out conditioned air according to the position of the human body and the temperature of the human body. Is output to the output circuit 34. The control information includes, for example, information for controlling the wind direction, information for controlling the air volume of the indoor blower 13, and information for controlling the opening degree of the expansion valve 11.

The storage device 33 stores programs and various data required for processing performed by the arithmetic processing unit 32. The storage device 33 can also store the data obtained by various processes by the arithmetic processing unit 32. For example, the storage device 33 stores a thermal image when there is no human body in the room. The thermal image is a reference thermal image (hereinafter, appropriately referred to as “reference thermal image”) used by the arithmetic processing unit 32 to detect the position of the human body in the room. The reference thermal image is created in advance by the arithmetic processing unit 32, for example, based on the temperature information when it can be determined that the human body does not exist in the room.

The output circuit 34 receives various control information from the arithmetic processing unit 32 and outputs it to the operating device provided in the corresponding indoor unit 10 or the outdoor unit 20. For example, when the control information for controlling the wind direction is received, the output circuit 34 outputs this control information to a drive device (not shown) for driving the vertical wind direction plate 3 and the left and right wind direction plates 4. When the control information for controlling the air volume is received, the output circuit 34 outputs this control information to a drive device (not shown) for driving the indoor blower 13. Further, when the control information for the outdoor unit 20 is received, the output circuit 34 outputs the control information to the outdoor control device 40 of the outdoor unit 20.

The temperature information acquired by the infrared sensor 5 is input to the arithmetic processing unit 32 from the input circuit 31. The arithmetic processing unit 32 creates thermal image information indicating the temperature distribution in the room based on the input temperature information. The thermal image information is transmitted from the indoor communication unit 6 to the PDA 7.

The PDA 7 includes a control unit 71, a terminal communication unit 72, a display unit 73, a visible camera 74, and a storage unit 75. The terminal communication unit 72 wirelessly communicates with the indoor communication unit 6 of the indoor unit 10. The visible camera 74 acquires an indoor image as three-dimensional floor plan information (indoor three-dimensional floor plan information) in the room where the indoor unit 10 is arranged. The display unit 73 includes a touch panel 731 that detects contact with the display unit 73.

A remote control application (software) that can remotely control the air conditioner 1000 while experiencing the air flow in the room is installed in the storage unit 75. The control unit 71 uses the remote control application installed in the storage unit 75 to capture an indoor image taken by the visible camera 74, a floor plan of the layout layout input to the PDA 7, and an infrared sensor mounted on the indoor unit 10. The thermal image information captured by 5 can be analyzed, and the 3D indoor layout information converted into a 3D image can be displayed on the display unit 73. The 3D indoor layout information is also used as a prototype of a 3D analysis mesh model used in a simulation (CFD calculation) based on computational fluid dynamics (CFD). The control unit 71 can perform CFD calculation to obtain the airflow distribution in the room, and display the airflow distribution on the display unit 73. The control unit 71 performs CFD calculation for each sampling time.

4 to 6 are views showing how a bird's-eye view of the room is displayed on the display unit 73 of the PDA 7. In FIG. 4, an indoor image 41a before the operation of the air conditioner 1000 is displayed. In FIG. 5, an indoor image 41b is displayed when the user (human body) 50 is about to start the operation of the air conditioner 1000. In FIG. 6, the indoor image 41c after the operation of the air conditioner 1000 is started is displayed. The indoor images 41a to 41c are, for example, CG (Computer Graphics).

As shown in FIG. 4, the lens unit of the visible camera 74 is arranged in front of the PDA 7 where the screen of the display unit 73 is arranged. The lens portion of the visible camera 74 may be arranged on the back surface of the PDA 7. In the room where the indoor unit 10 is installed, a door 42 is provided, and a sofa 43 and a shelf 44 are arranged. In FIG. 4, the door 42 is closed and no one is displayed in the room.

In FIG. 5, the arrangement in the room is changed so that the human body 50 sits on the sofa 43 and the door 42 is open. Further, a predetermined operating state (for example, the operation of the air conditioner 1000 at the end of the previous operation) is added to the three-dimensional layout image created based on the indoor three-dimensional layout information acquired before the operation of the air conditioner 1000. Three-dimensional airflow distribution (streamline) 60b in the room assumed when the operation of the air conditioner 1000 is started based on the state or the operating state assumed when the operation of the air conditioner 1000 is stable). Are displayed on top of each other.

In FIG. 6, the arrangement in the room is changed so that the human body 50 stands upright on the front right side of the sofa 43. The three-dimensional airflow distribution 60c in the room predicted by the PDA 7 during the operation of the air conditioner 1000 is displayed superimposed on the three-dimensional floor plan image. The airflow from the air outlet 2 of the indoor unit 10 flows toward the sofa 43, but the airflow changes so as to avoid the human body 50 in front of the sofa 43.

FIG. 7 is a diagram showing a mesh model corresponding to the state of the room shown in FIG. FIG. 7A is a plan view of the room from directly above (Z-axis direction). FIG. 7B is a plan view of the room from the side (Y-axis direction). The hatched areas near the center of FIG. 7 (a) and near the lower center of FIG. 7 (b) are hatches in which the human body 50 is seated on the sofa 43 and integrated with each other. According to the information in the floor plan, the hatching boundary H1a of the human body 50 and the hatching boundary H1b of the sofa 43 are identified. The region R1a surrounding the human body 50 is formed so as to be surrounded by a rectangular parallelepiped in which a minimum of two mesh regions are secured from the hatch boundary H1a. Similarly, when the region R1b surrounding the sofa 43 is formed so as to be surrounded by a rectangular parallelepiped in which a minimum of two meshes are secured from the hatch boundary H1b, the regions R1a and R1b are shown overlapping. The mesh model is formed by an orthogonal lattice fixed to the spatial coordinate system XYZ, and the number of meshes in the entire indoor area shown in FIG. 7 is about 90,000. The same applies to FIG. Further, the outer peripheral boundary of the entire mesh region is the basic wall surface boundary, but the door 42 or the portion where the window is opened is treated as the fluid outflow boundary.

8 and 9 are diagrams showing a mesh model corresponding to the state of the room shown in FIG. 8 (a) and 9 (a) are views of the room viewed from directly above. 8 (b) and 9 (b) are views of the room viewed from the side. The sofa 43 is shown in the hatched area near the center of FIG. 8A and near the center of the lower part of FIG. 8B, and the human body stands upright at a position close to the indoor unit 10 from the sofa 43. 50 is shown. Corresponds to the state of the room at a certain sampling timing in which the instantaneous airflow prediction of the air conditioner 1000 is performed. A region R2a surrounding the hatching boundary H2a of the human body 50 and a region R2b surrounding the hatching boundary H2b of the sofa 43 are shown.

In the following, the mesh model shown in FIG. 7 is a mesh model (first mesh model) corresponding to the state of the room at a certain sampling timing during operation of the air conditioner 1000, and the mesh model shown in FIG. 8 is shown in FIG. A mesh model (second mesh model) corresponding to the state of the room at the sampling time next to the sampling time of 7 is used.

In the instantaneous predicted airflow during operation of the air conditioner 1000, the indoor image of the infrared sensor 5 at the current sampling time and the indoor image of the infrared sensor 5 at the previous sampling time are compared using the image recognition system. In this comparison, changes in obstructed objects that have a non-negligible effect on the airflow, such as the position of the human body 50, the position of furniture such as the sofa 43 and shelves 44, and the opening and closing of the door 42, are checked. From the current mesh model, a partial region (airflow correction region) different from the mesh model at the previous sampling time is extracted.

For example, when comparing the mesh models of FIGS. 7 and 8, it is determined that the sofa 43 has not moved significantly because the hatching boundary H2b of the sofa 43 of FIG. 8 is within the area R1b surrounding the sofa 43 of FIG. However, the region R2b in FIG. 8 is not treated as an airflow correction region that requires recalculation. On the other hand, the hatching boundary H2a of the human body 50 in FIG. 8 is determined to have moved significantly because it protrudes from the region R1a surrounding the human body 50 in FIG. 7. The region R1a of FIG. 7 and the region R2a of FIG. 8 are treated as the airflow correction regions that need to be recalculated. That is, the recalculation area includes a mesh corresponding to the position (first position) of the human body 50 in the previous sampling time and a mesh corresponding to the position (second position) of the human body 50 in the current sampling time.

Alternatively, when it is determined that the region where the region R1a of FIG. 7 and the region R2a of FIG. 8 overlap is small and a narrow space or a distorted space that does not overlap between the region R1a and the region R2a is generated, FIG. And as shown in FIG. 9B, the region R3 of FIG. 9 surrounded by the hatching boundary H1a of the human body 50 of FIG. 7 and the hatching boundary H2a of the human body 50 of FIG. 8 with a minimum of two meshes secured. It is necessary to newly form it and treat it as an airflow correction area that needs to be recalculated.

Further, in the first embodiment, the airflow correction region required for recalculation is formed by a rectangular parallelepiped parallel to the outer peripheral wall surface of the indoor mesh space. When the extracted object is tilted, it may be formed as a rectangular parallelepiped tilted with respect to the outer peripheral wall surface.

When the hatching boundary H1x of the object X of interest changes beyond the fluid region R1x surrounding it from the previous sampling time to the current sampling time, it is determined that the object X has moved, and CFD with respect to the airflow correction region. Calculation (partial area CFD calculation) is performed. The threshold value can be appropriately set by an actual machine experiment or a simulation. In the first embodiment, the fluid region R1x is set by a rectangular parallelepiped having a mesh size of two or more larger than the hatch boundary H1x.

Further, in FIGS. 8 (a) and 8 (b), the CFD calculation is performed for the entire area of the mesh model by limiting the area for performing the CFD calculation to R2 (the number of meshes is about 10,000). The number of meshes to be recalculated has been reduced to 1/9 (1/2 X-axis length, 1/3 Y-axis length, and 2/3 Z-axis length) compared to the case where it is performed. can do. For regions other than region R2, the result of CFD calculation at the previous sampling time is used.

The control unit 71 of the PDA 7 displays a composite image in which the three-dimensional airflow distribution predicted using the result of the partial region CFD calculation is superimposed on the thermal image acquired from the infrared sensor 5 on the display unit 73. The composite image is, for example, an Augmented Reality (AR) image.

FIG. 10 is a diagram showing an indoor thermal image 51a seen from the human body 50 in the room. Based on the thermal image acquired from the infrared sensor 5, the thermal image of the indoor unit 10 side viewed from the human body 50 in the room is predicted, and a gradation showing the temperature distribution is applied. The image of the human body 50 and the three-dimensional airflow distribution 61a are superimposed on this thermal image. For example, the user can change the direction of the airflow formed by the indoor unit 10 by tracing the streamline indicating the airflow in a desired direction with respect to the touch panel 731 of FIG.

FIG. 11 is a diagram showing an AR thermal image 51b viewed from the infrared sensor 5 of the indoor unit 10. As shown in FIG. 11, in the AR thermal image 51b, in the thermal image acquired from the infrared sensor 5, the edge portion of the object detected by the edge detection process is highlighted by a white line. In the AR thermal image 51b, the image of the infrared sensor 5, the image of the human body 50 with the gradation showing the temperature distribution, and the three-dimensional airflow distribution 61b are superimposed on the thermal image.

FIG. 12 is a flowchart showing the flow of the preset processing performed in the PDA 7 prior to the operation of the air conditioner 1000. In the following, the step is simply referred to as S. As shown in FIG. 12, the PDA is initially set in S101. Specifically, the remote control application is downloaded from the manufacturer's site of the air conditioner 1000 to PDA7 and installed. Next, the model information of the air conditioner 1000 is input to the remote control application, and the airflow characteristic data of the model itself is acquired from the manufacturer. The airflow characteristic data of a single model is, for example, an experiment of the air conditioner 1000 regarding the relationship between the rotation speed of the blower fan 131 of the indoor unit 10, the angle of the vertical wind direction plate 3, and the airflow velocity distribution depending on the angle of the left and right wind direction plates 4. It is the calculation data including the data and the CFD calculation result. Airflow characteristic data for each model is acquired from cloud services and the like.

Following S101, in S102, the indoor floor plan information before the operation of the air conditioner 1000 is collected. Specifically, indoor photography with the visible camera 74 of the PDA7, reading of the three-dimensional floor plan layout, input of basic information, indoor photography with the infrared sensor 5 of the air conditioner 1000, and basic floor plan information for remote control applications. Input is done. The indoor three-dimensional floor plan information, which is difficult to distinguish by indoor photography by the infrared sensor 5, can be clearly identified by using the visible camera 74 of the PDA7 or the like. As a result, it is possible to create a three-dimensional or two-dimensional indoor layout diagram and a CFD mesh model more accurately than when using only the thermal image from the infrared sensor 5. By the processing of S102, for example, the three-dimensional indoor layout as shown in FIG. 4 can be displayed on the display unit 73 of the PDA 7.

With reference to FIG. 12 again, in S103 following S102, the CFD calculation in the room before the operation of the air conditioner 1000 or the verification of the airflow prediction by the trial run of the air conditioner 1000 is performed, and the three-dimensional flow velocity distribution in the room is verified. Data is accumulated in the database so that the prediction can be made with a certain degree of accuracy. In S103, according to a general image recognition system, the positions of the door 42, the sofa 43, the shelf 44, and the human body 50, and the opening and closing of the door 42, etc. Is extracted. By the processing of S103, for example, the indoor airflow distribution shown in FIG. 5 can be displayed on the display unit 73 of the PDA 7.

With reference to FIG. 12 again, the completion of S103 ends the pre-setting performed before the operation of the air conditioner 1000. The processes of S102 and S103 may be performed by a cloud computer on the Internet.

The user sets the operation mode (cooling mode, heating mode, dehumidifying mode, etc.) and temperature using the touch panel 731 of the PDA7 or a remote controller (not shown), and activates the air conditioner 1000. When the air conditioner 1000 is started, the compressor 21 starts operation, and the refrigerant starts to circulate in the refrigerant circuit of the air conditioner 1000. Further, the indoor unit 10 is also controlled by the indoor control device 30 to start operation.

FIG. 13 is a flowchart showing the flow of the airflow control process performed by the control unit 71 of the PDA 7 of FIG. The process shown in FIG. 13 is called every sampling time by the main routine of the remote control application.

As shown in FIG. 13, the control unit 71 updates the previous airflow prediction data to the airflow prediction data calculated one sampling time before in S201, and proceeds to the process in S202. When the process shown in FIG. 13 is first performed after the start of operation of the air conditioner 1000, the airflow prediction data calculated in advance in S103 of FIG. 12 is used as the previous airflow prediction data.

The control unit 71 updates the indoor floor plan information in S202, and proceeds to the process in S203. Specifically, the indoor image taken by the infrared sensor 5 of the indoor unit 10 is acquired from the indoor unit 10, the indoor floor plan information is created, and the position of the human body and the temperature information of the human body are detected. For example, as shown in FIG. 11, the human body 50 standing upright at a position close to the indoor unit 10 from the sofa 43 can be identified from the image of the infrared sensor 5.

With reference to FIG. 13 again, the control unit 71 determines in S203 whether or not the mesh model needs to be updated. Specifically, using an image recognition system, a comparison between the indoor image of the infrared sensor 5 acquired at the previous sampling time and the indoor image of the infrared camera acquired at the current sampling time, or the mesh model of FIG. And the mesh model of FIG. 8 is compared. In the comparison, the control unit 71 checks for changes in the position of the human body 50, the position of furniture such as the sofa 43 and the shelf 44, and the position of the obstructed object that has a non-negligible effect on the airflow, such as opening and closing the door 42. Will be done. In the mesh model at the current sampling time, when the human body 50 moves by two or more mesh sizes from the previous sampling time and moves beyond the recalculation area surrounding the human body set at the time of the previous calculation, the control unit 71 moves. , Determines that the mesh model needs to be updated.

When it is necessary to update the mesh model (YES in S203), the control unit 71 updates the mesh model in S204 and proceeds to the process in S205. When it is not necessary to update the mesh model (NO in S203), the control unit 71 proceeds to S205.

The control unit 71 determines in S205 whether or not the airflow distribution needs to be recalculated. Specifically, the control unit 71 first performs the process shown in FIG. 13 after the start of operation of the air conditioner 1000, and when it is determined in S203 that the mesh model needs to be updated, the airflow distribution. It is determined that recalculation of is necessary.

When it is necessary to recalculate the airflow distribution (YES in S205), the control unit 71 makes an instantaneous calculation prediction of the airflow distribution in S206, saves the calculated airflow prediction data in the storage unit 75, and processes the airflow in S207. Proceed. When it is not necessary to recalculate the airflow distribution (NO in S205), the control unit 71 proceeds to S207. The control unit 71 displays the indoor three-dimensional flow velocity distribution on the display unit 73 of the PDA 7 in S207, and proceeds to the process in S208.

The control unit 71 determines in S208 whether or not there has been an airflow change operation. The user can change the airflow formed by the indoor unit 10 by performing an operation of tracing the airflow on the touch panel 731 while watching the airflow image of the display unit 73 of the PDA 7. When there is an airflow change operation (YES in S208), the control unit 71 transmits an airflow change command corresponding to the airflow change operation to the air conditioner 1000 in S209, and returns the process to the main routine. If there is no airflow change operation (NO in S208), the control unit 71 returns the process to the main routine.

The timing at which the airflow prediction referred to in the processes of FIGS. 12 and 13 is performed is before the operation of the air conditioner 1000 (S103 of FIG. 12 in the first embodiment), the previous sampling time, and the current sampling time (Sampling time of FIG. 12). In the first embodiment, it is divided into three stages of S206) in FIG. In the following, the airflow predictions performed before the operation of the air conditioner 1000, the previous sampling time, and the current sampling time are shown as the airflow prediction before the operation, the previous airflow prediction, and the current airflow prediction (instantaneous airflow prediction), respectively. And. In the first and second embodiments, the time required to display the airflow image on the display unit 73 of the PDA 7 (instantaneous airflow display time) during the airflow operation during the operation of the air conditioner 1000 is determined by using FIGS. 14 and 15. A modification is made between the modified examples of Form 1 and Comparative Examples 1 and 2.

FIG. 14 is a diagram comparing the first embodiment, the modified examples of the first embodiment, and the comparative examples 1 and 2. As shown in FIG. 14, Comparative Example 1 has a configuration in which none of the airflow prediction before operation, the previous airflow prediction, and the current airflow prediction is performed. In Comparative Example 2, the airflow prediction before the operation is not performed, and the cloud service performs the previous airflow prediction and the current airflow prediction by CFD calculation (CFD calculation in all areas) for the entire area of the mesh model. In the modified example of the first embodiment, the airflow prediction before the operation is not performed, and the PDA7 performs the previous airflow prediction and the current airflow prediction by the whole area CFD calculation. In any of the first embodiment, the modified example of the first embodiment, and the comparative examples 1 and 2, the indoor unit 10 plays a role of providing the thermal image acquired by the infrared sensor 5 to the PDA 7, and obtains the airflow prediction data. CFD calculation for calculation is not performed.

Regarding the specifications of PDA7, the OS (Operating System) is Android (registered trademark), the CPU has an octa-core of 2.35 GHz, the RAM (Random Access Memory) is 6 GB, and the resolution of the display unit 73 is 1980 × 1080. It is a pixel. The number of meshes in the indoor mesh model is about 90,000.

Regarding Comparative Example 2, as a cloud service, a computer manufactured by the manufacturer of the air conditioner 1000 is used via the cloud environment. The result of CFD calculation by the manufacturer's computer is transferred to PDA7 via LAN (Local Area Network) and WiFi communication and displayed on PDA7 on the display unit 73. Regarding the specifications of the manufacturer's computer, the OS is Windows 7 (registered trademark), the CPU is Core i7 (registered trademark), the RAM is 8 GB, and the resolution is 1980 × 1080 pixels.

FIG. 15 is a diagram showing an instantaneous airflow display time for each of the first embodiment, the modified example of the first embodiment, and the comparative examples 1 and 2. In Comparative Example 1, since the indoor airflow image cannot be displayed, the instantaneous airflow display time is not shown.

As shown in FIG. 15, in the first embodiment, the time required for displaying the airflow image is about 52 seconds. In the first modification of the first embodiment, the time required for displaying the airflow image is about 330 seconds. In Comparative Example 2, the time required for displaying the airflow image is about 430 seconds.

Even when a supercomputer is used as the manufacturer's computer in Comparative Example 2, the time required for displaying the airflow image is 100 seconds or more because the transfer time of the airflow prediction data is required. On the other hand, in the first embodiment, the previous airflow prediction data and the current airflow prediction data are calculated by PDA7. Therefore, it is not necessary to transfer the airflow prediction data from the external computer to the PDA7. Further, by recalculating only a relatively large change part in the mesh model such as the movement of the human body, the number of meshes to be recalculated can be reduced as compared with the whole area CFD calculation. Therefore, the load of CFD calculation in PDA7 can be reduced as compared with the whole area CFD calculation. As a result, the time for predicting the instantaneous airflow of the air conditioner 1000 can be shortened as compared with the case where the whole area CFD calculation is performed. For example, even when a supercomputer is used as the manufacturer's computer in Comparative Example 2, the time required for displaying the airflow image can be shortened by about 48 seconds as compared with Comparative Example 2 according to the first embodiment.

As described above, according to the air conditioning system according to the first embodiment, the airflow distribution in the room displayed on the display unit of the remote control terminal is updated in real time, so that the user can visually observe the airflow actually experienced. Can be confirmed. The airflow operability is improved, and it is possible to make delicate airflow settings according to each user's preference. Since the user can easily adjust the blowing strength of the air conditioner, the wind contact, etc. to a desired setting, the user's satisfaction with the air conditioner is improved. According to the air conditioning system according to the first embodiment, the comfort of the air conditioner can be improved.

Embodiment 2.
In the second embodiment, a case where the instantaneous airflow prediction in the remote control terminal is performed by a simple calculation for the airflow correction region instead of the partial region CFD calculation will be described. The airflow prediction before operation is the same as that of the first embodiment.

In the simple calculation, the basic shape of an object existing in a room such as a human body and furniture is approximated as a complex of a plurality of cylinders and spheres registered in a fluid analysis database. Ignoring the interaction between the solids that make up the approximated object, the fluid resistance of the object and the flow velocity distribution around the object are predicted using known physical information about fluid dynamics. Known physical information on fluid mechanics includes, for example, the fluid resistance coefficient, or the flow velocity distribution state around the object such as the forward flow, the separation point, the wake flow, and the influence of the inclination angle (“Mechanical Engineering Handbook α”. Basics ”published by the Japan Society of Mechanical Engineering, 2012, α4-pp.40-48, 5.4 wake, 5.5 peeling).

FIG. 16 is a diagram showing a state in which the human body is approximated as a complex of a cylinder and a sphere. In FIG. 16, the airflow distribution around the human body is predicted. As shown in FIG. 16, the head is approximated as a sphere, and the torso, two arms, and two legs are each replaced by a cylinder. The interaction of each component is ignored, and the airflow around the sphere and the airflow around the cylinder are independently predicted from the fluid analysis database. The independently predicted airflows are superimposed and predicted as the entire airflow around the human body.

In the second embodiment, the airflow prediction time can be shortened as compared with the first embodiment by performing the instantaneous airflow prediction by a simple calculation. The air conditioning system according to the second embodiment can also improve the comfort of the air conditioner.

Embodiment 3.
In the first and second embodiments, the case where the airflow prediction before the operation is performed by the remote control terminal has been described. In the third embodiment, a case where the airflow prediction before the operation is performed by the manufacturer computer on the cloud service will be described. Also in the third embodiment, the airflow prediction this time is performed by a simple calculation as in the second embodiment.

Also in the third embodiment, the airflow prediction time can be shortened as compared with the first embodiment by performing the instantaneous airflow prediction by a simple calculation. The air conditioning system according to the third embodiment can also improve the comfort of the air conditioner.

Embodiment 4.
In the fourth embodiment, the CFD calculation is not performed on the remote control terminal in any of the airflow prediction before operation, the previous airflow prediction, and the current airflow prediction, and the database provided by the manufacturer (CFD calculation result for each model). The case where the airflow is predicted with reference to the calculation result and the measured value of (including) and the simple calculation is performed on the remote control terminal for the airflow correction area will be described. In the fourth embodiment as in the second and third embodiments, a simple calculation using the fluid analysis database is performed in the instantaneous airflow prediction.

Also in the fourth embodiment, the airflow prediction time can be shortened as compared with the first embodiment by performing the current airflow prediction by a simple calculation. The air conditioning system according to the fourth embodiment can also improve the comfort of the air conditioner.

FIG. 17 is a diagram comparing the first to fourth embodiments. FIG. 18 is a diagram showing an instantaneous airflow display time for each of the first to fourth embodiments. With reference to FIG. 18, the instantaneous airflow display time of the second embodiment is shorter than the instantaneous airflow display time of the first embodiment by about 21 seconds. The instantaneous airflow display time of the third and fourth embodiments is shorter than the instantaneous airflow display time of the first embodiment by about 30 seconds.

In the second to fourth embodiments, the CFD calculation is not performed during the operation of the air conditioner, and the instantaneous airflow prediction is performed by a simple calculation using a fluid analysis database such as known physical information. According to the second to fourth embodiments, the time required for the instantaneous airflow prediction can be shortened as compared with the first embodiment.

If the simple calculation is repeated in the instantaneous airflow prediction, the error between the actual airflow distribution and the predicted airflow distribution can be accumulated in the previous airflow prediction data. In the second to fourth embodiments, in order to suppress the accumulation of the error, the entire area CFD is periodically calculated in the cloud service during the operation of the air conditioner, and the previous airflow prediction data is updated. By suppressing the accumulation of errors between the actual airflow distribution and the predicted airflow distribution, it is possible to suppress a decrease in the accuracy of the instantaneous airflow prediction.

In addition, the manufacturer of the air conditioner may have a database of airflow characteristics of the air conditioner alone. The airflow characteristic database is, for example, a database of where and how much wind speed is generated by the rotation speed and wind direction adjusting mechanism (upper and lower wind direction plates and left and right wind direction plates) of the blower fan for each model of the air conditioner. Further, in the first to fourth embodiments, since the user performs the airflow operation using the PDA, it is possible to infer the difference between the indoor airflow distribution prediction and the actual airflow state to some extent through the reaction of the user. As a result, it is possible to accumulate in the database the correspondence between the airflow characteristics peculiar to the room where the air conditioner is arranged and the satisfaction level based on the preference peculiar to the user. By repeating deep learning using the database as a teaching material, it is possible to improve the accuracy of instantaneous airflow prediction during operation of the air conditioner, and it is possible to provide an airflow more suitable for the user's preference.

In the first to fourth embodiments, the case where the airflow distribution by the instantaneous airflow prediction is displayed on the display unit of the PDA has been described. The airflow distribution based on the instantaneous airflow prediction may be displayed on the remote controller of the air conditioner.

It is also planned that the embodiments disclosed this time will be appropriately combined and implemented within a consistent range. It should be considered that the embodiments disclosed this time are exemplary in all respects and not restrictive. The scope of the present invention is shown by the claims rather than the above description, and it is intended to include all modifications within the meaning and scope equivalent to the claims.

1 Suction port, 2 Air outlet, 3 Vertical air direction plate, 4 Left and right air direction plate, 5 Infrared sensor, 6 Indoor communication unit, 10 Indoor unit, 11 Expansion valve, 12 Indoor heat exchanger, 13 Indoor blower, 20 Outdoor unit, 21 Compressor, 22 flow path switching device, 23 outdoor heat exchanger, 24 outdoor blower, 30 indoor control device, 31 input circuit, 32 arithmetic processing device, 33 storage device, 34 output circuit, 40 outdoor control device, 41a to 41c indoor Image, 42 doors, 43 sofas, 44 shelves, 50 human bodies, 51a indoor thermal image, 51b AR thermal image, 60c, 61a, 61b 3D air flow distribution, 71 control unit, 72 terminal communication unit, 73 display unit, 74 visible camera , 75 storage unit, 100 air conditioning system, 131 blower fan, 731 touch panel, 1000 air conditioner.

Claims (6)

A remote control terminal for an air conditioner that has an indoor unit that blows air into a specific space.
The indoor unit includes an imaging sensor that acquires a first image of the specific space.
The remote control terminal is
A communication unit that wirelessly communicates with the indoor unit,
Display and
A control unit that receives the first image from the indoor unit via the communication unit, and
With
The control unit has a function of creating a second image which is a three-dimensional image of the specific space based on the first image, and a three-dimensional airflow distribution of the specific space derived by simulation based on computational fluid dynamics. A remote control terminal having a function of displaying a composite image superimposed on a second image on the display unit. The display unit includes a touch panel that detects a user's contact with the display unit.
The control unit transmits a command for changing the ventilation setting of the indoor unit from the communication unit to the indoor unit in response to the user's contact with the three-dimensional airflow distribution displayed on the display unit. Remote control terminal described in. Equipped with a visible camera
The remote control according to claim 2, wherein the control unit creates a mesh model used in the simulation by using the third image of the specific space acquired by the visible camera in addition to the second image. Terminal. The control unit performs the simulation for each sampling time.
Create the first mesh model at the first sampling time,
A second mesh model is created at the second sampling time following the first sampling time, a partial region different from the first mesh model is extracted from the second mesh model, and the simulation is performed on the partial region. The remote control terminal according to claim 3, wherein the part corresponding to the partial region of the three-dimensional airflow distribution displayed on the display unit is updated. The imaging sensor includes an infrared sensor that acquires the first image as a thermal image.
The control unit identifies the first position of the human body in the first mesh model using the thermal image of the specific space acquired at the first sampling time, and the specific space acquired at the second sampling time. The remote control terminal according to claim 4, wherein the second position of the human body in the second mesh model is specified by using the thermal image of the above, and the region including the first position and the second position is extracted as the partial region. .. The remote control terminal according to any one of claims 1 to 5 and
An air conditioning system including the indoor unit.

Images