JP2019109025A - Air conditioner - Google Patents

Abstract

To provide an air conditioner which prevents reduction of detection accuracy of a sensor while continuously rotating a sensor unit in one direction.SOLUTION: An air conditioner includes: a sensor unit including one or multiple detection units for detecting a temperature of an air conditioned space and a rotation part having the detection unit; a driving device which rotates the rotation part in one direction; and a control device which controls rotation of the rotation part through the driving device. The control device adjusts a rotation speed of the rotation part according to a position of a temperature detection range of the detection unit.SELECTED DRAWING: Figure 10

Description

  The present invention relates to an air conditioner provided with a sensor that detects the temperature of a space to be air conditioned.

  In recent years, more comfort has been required for household air conditioners. Therefore, various types of air conditioners have been proposed that include a sensor that acquires the temperature of the air-conditioned space such as the room as, for example, a thermal image or temperature data. For example, Patent Document 1 proposes a thermal image sensor in which the amount of activity of a person in a room is measured as a thermal image. Specifically, in Patent Document 1, "an infrared light receiving unit provided with a plurality of infrared light receiving elements that respectively receive infrared light, a lens that causes the infrared light receiving unit to emit infrared light, the infrared light receiving unit, and the lens And a rotating unit configured to rotationally drive around a part of the lens.

JP, 2016-217886, A

  Generally, a general sensor for acquiring the temperature of the air conditioning target space is configured to acquire the temperature of the air conditioning target space by reversing at a predetermined angle. When reversing the sensor by a predetermined angle, the scanning range is affected by the backlash or link openness of the drive gear that drives the sensor. That is, the scanning range is shifted between the forward pass and the return pass, and the accuracy of the background subtraction method is reduced in the image processing of the acquired thermal image data and the like.

  By the way, the content that each rotor of an infrared detector continues rotating in the same direction is described in patent document 1. FIG. However, Patent Document 1 does not describe a specific structure in the case where each rotor of the infrared detector continues to rotate in the same direction, and even how to change the rotational speed is disclosed. Absent. That is, Patent Document 1 does not specifically examine the wiring layout and the shape of the infrared detector itself which are required when the rotors of the infrared detector continue to rotate in the same direction. Therefore, the wiring that supplies power to the sensor and the length of the wiring that receives a signal from the sensor restrict the range in which the sensor can rotate, but Patent Document 1 does not disclose such a point at all.

  Even if it is possible to keep rotating in the same direction, in Patent Document 1, the rotational speed is not changed depending on whether the scanning range of the sensor is facing the air conditioning target space or not. . Therefore, in Patent Document 1, a time lag occurs while the sensor is rotating. That is, it takes time for the scanning range of the sensor to face the air conditioning target space. The occurrence of a time lag also reduces the accuracy in image processing such as acquired thermal image data.

  The present invention has been made to solve the above problems, and it is an object of the present invention to provide an air conditioner in which the detection accuracy in the sensor unit is not reduced while continuously rotating the sensor unit in one direction. The purpose is.

  An air conditioner according to the present invention includes a sensor unit including a detecting unit for detecting a temperature of a space to be air-conditioned and a rotating unit having the detecting unit, and a driving device configured to rotate the rotating unit in one direction. And a control device that controls the rotation of the rotating unit via the drive device, and the control device adjusts the rotational speed of the rotating unit according to the position of the temperature detection range of the detection unit. It is a thing.

  In the air conditioning apparatus according to the present invention, since the rotating portion of the sensor unit is rotated in one direction, the influence of backlash of the driving device and the openness of the link is reduced. Further, in the air conditioning apparatus according to the present invention, the rotational speed of the rotating unit of the sensor unit is adjusted, so that the influence of the time lag can be suppressed. Therefore, according to the air conditioning apparatus of the present invention, it is possible to suppress a decrease in detection accuracy in the sensor unit.

It is a schematic block diagram which shows an example of a structure of the air conditioning apparatus which concerns on Embodiment 1 of this invention. It is a schematic circuit block diagram which shows an example of the refrigerant circuit structure of the air conditioning apparatus which concerns on Embodiment 1 of this invention. It is a block diagram which shows an example of a system configuration | structure of the air conditioning apparatus which concerns on Embodiment 1 of this invention. It is sectional drawing which expands and shows roughly the sensor part of the 1st unit of the air conditioning apparatus which concerns on Embodiment 1 of this invention. It is a bottom view which expands the sensor part of the 1st unit of the air harmony device concerning Embodiment 1 of the present invention, and is shown roughly. It is a schematic diagram explaining the temperature detection range at the time of initialization of the sensor part of the 1st unit of the air conditioning apparatus which concerns on Embodiment 1 of this invention. It is a schematic diagram which shows the structure of a slip ring typically. It is a graph which shows an example of the data which put in order the temperature data of the air-conditioning object space detected for 360 degree in time series. It is the graph which showed typically the mode of the air-conditioning object space seen from the position of the sensor part. It is a flowchart which shows the flow of the process at the time of controlling the sensor part of the air conditioning apparatus which concerns on Embodiment 1 of this invention. It is a schematic diagram explaining the temperature detection range after adjustment of the sensor part of the 1st unit of the air conditioning apparatus which concerns on Embodiment 1 of this invention. It is sectional drawing which expands and shows roughly the sensor part of the 1st unit of the air conditioning apparatus which concerns on Embodiment 2 of this invention. It is a bottom view which expands the sensor part of the 1st unit of the air harmony device concerning Embodiment 2 of the present invention, and roughly shows it. It is a flowchart which shows the flow of the process at the time of controlling the sensor part of the air conditioning apparatus which concerns on Embodiment 2 of this invention.

  Hereinafter, embodiments of the present invention will be described based on the drawings. In addition, in the following drawings including FIG. 1, the relationship of the magnitude | size of each structural member may differ from an actual thing. In addition, in the following drawings including FIG. 1, those given the same reference numerals are the same or correspond to this, and this is common to the whole text of the specification. Furthermore, the form of the component shown in the specification full text is an illustration to the last, and is not limited to these descriptions.

Embodiment 1
FIG. 1: is a schematic block diagram which shows an example of a structure of the air conditioning apparatus 100 which concerns on Embodiment 1 of this invention. FIG. 2 is a schematic circuit diagram showing an example of the refrigerant circuit configuration of the air conditioning apparatus 100. As shown in FIG. The air conditioner 100 will be described based on FIGS. 1 and 2. In FIG. 2, the flow of the refrigerant during the cooling operation performed by the air conditioning apparatus 100 is indicated by a solid arrow, and the flow of the refrigerant during the heating operation performed by the air conditioning apparatus 100 is indicated by a broken arrow.

<Configuration of Air Conditioner 100>
As shown in FIGS. 1 and 2, the air conditioning apparatus 100 includes a first unit 10 and a second unit 50. The air conditioning apparatus 100 is also configured to issue an operation instruction to the air conditioning apparatus 100 via the operation unit 150 that receives an input from the user. That is, in the air conditioning apparatus 100, the first unit 10 operates based on the operation information instructed via the operation unit 150, and the second unit 50 also operates according to the instruction.

(First unit 10)
The first unit 10 is installed in a space that supplies cold or heat to a space to be air-conditioned such as indoors, and has a function of cooling or heating the space to be air-conditioned by the cold or heat supplied from the second unit 50. The first unit 10 is used as an indoor unit, and has a housing 10a that forms an outer shell.
The space for supplying cold or heat to the air conditioning target space is another space or the like connected to the air conditioning target space through the air conditioning target space or the duct.

  The first unit 10 includes a first heat exchanger 11, a first electric component 12, a first blower fan 13a, upper and lower louvers 13c, and a sensor unit 14-1. The first heat exchanger 11 and the first electrical component 12 are mounted inside the housing 10a, and the upper and lower louvers 13c and the sensor unit 14-1 are mounted so as to be exposed to the outside of the housing 10a. The shape of the housing 10a is not limited to the shape shown in FIG.

  The first heat exchanger 11 is an element of the refrigerant circuit A included in the air conditioner 100, functions as a condenser during heating operation, and functions as an evaporator during cooling operation. The first heat exchanger 11 may be a fin and tube heat exchanger, a microchannel heat exchanger, a shell and tube heat exchanger, a heat pipe heat exchanger, a double pipe heat exchanger, or a plate heat exchange. It can be configured with a container or the like. Here, although the case where the 1st heat exchanger 11 is a heat exchanger which performs heat exchange with air and a refrigerant is illustrated, according to the object which heat-exchanges, the type of the 1st heat exchanger 11 is decided Just do it.

  The first electric component 12 has the sensor unit 14-1, the first blower fan 13a, and the upper and lower louvers 13c based on the instruction content from the user via the operation unit 150 and the information obtained by the sensor unit 14-1. It has a function as a control device that controls the In addition, as an instruction | indication content input from a user via the operation part 150, the operation mode of air-conditioning apparatus 100, temperature setting, humidity setting, air volume setting, wind direction setting, etc. can be considered. The first electric component 12 will be described in detail later.

The first blower fan 13a supplies air, which is a heat exchange fluid, to the first heat exchanger 11, and supplies the air having passed through the first heat exchanger 11 to the air conditioning target space. The first blower fan 13a can be configured of a propeller fan having a plurality of wings, a cross flow fan, or the like.
The upper and lower louvers 13 c are installed in the path of the air that has passed through the first heat exchanger 11, and variably adjust the wind direction in the vertical direction of the air blown out from the outlet of the first unit 10.

  The sensor unit 14-1 has a function of acquiring at least the temperature of the environmental information of the air conditioning target space. The temperature information acquired by the sensor unit 14-1 is sent to the first electrical component 12. The sensor unit 14-1 will be described in detail later.

(Second unit 50)
The second unit 50 is installed in a space separate from the air conditioning target space, and has a function of supplying cold or heat to the first unit 10. The second unit 50 is used as an outdoor unit, and has a housing 50a that forms an outer shell.
The space other than the air conditioning target space is a space such as a roof, an underground, a ceiling, a common space, or a parking lot.

  The second unit 50 includes a second heat exchanger 51, a second electric component 52, a compressor 53a, a flow path switching device 53b, a second blower fan 53c, and a pressure reducing device 53d. The second heat exchanger 51, the second electric component 52, the compressor 53a, the flow path switching device 53b, the second blower fan 53c, and the pressure reducing device 53d are mounted inside the housing 50a. The shape of the case 50a is not limited to the shape shown in FIG.

  The second heat exchanger 51 is an element of the refrigerant circuit A included in the air conditioner 100, functions as an evaporator during heating operation, and functions as a condenser during cooling operation. The second heat exchanger 51 is a fin-and-tube type heat exchanger, a microchannel heat exchanger, a shell-and-tube type heat exchanger, a heat pipe type heat exchanger, a double pipe type heat exchanger, or plate heat exchange. It can be configured with a container or the like. Here, although the case where the 2nd heat exchanger 51 is a heat exchanger which performs heat exchange with air and a refrigerant is illustrated, according to the object which heat-exchanges, the type of the 2nd heat exchanger 51 is decided Just do it.

  The second electric component 52 includes a compressor 53a, a flow path switching device 53b, and a second electric component 52 based on the instruction content from the user transmitted via the first electric component 12 and the information obtained by the sensor unit 14-1. It has a function as a control device which controls the 2 blowing fan 53c and the decompression device 53d.

  The compressor 53a compresses and discharges the refrigerant. The compressor 53a can be configured by a rotary compressor, a scroll compressor, or the like. When the second heat exchanger 51 functions as a condenser, the refrigerant discharged from the compressor 53 a is sent to the second heat exchanger 51. When the second heat exchanger 51 functions as an evaporator, the refrigerant discharged from the compressor 53 a is sent to the second heat exchanger 51 after passing through the first heat exchanger 11.

The flow path switching device 53b is provided on the discharge side of the compressor 53a, and switches the flow of the refrigerant in the heating operation and the cooling operation.
In addition, when circulating a refrigerant | coolant to one direction, the flow-path switching apparatus 53b is not an essential structure. Further, as the flow path switching device 53b, a four-way valve, or a combination of a two-way valve or a three-way valve can be considered.

  The second blower fan 53 c supplies air, which is a heat exchange fluid, to the second heat exchanger 51. Although the type of the second blower fan 53c is not particularly limited, the second blower fan 53c can be configured by a propeller fan or the like having a plurality of wings.

The pressure reducing device 53 d expands and reduces the pressure of the refrigerant having passed through the first heat exchanger 11 or the second heat exchanger 51. The pressure reducing device 53d may be configured by an electric expansion valve or the like capable of adjusting the flow rate of the refrigerant.
The pressure reducing device 53 d may be disposed not in the second unit 50 but in the first unit 10.

(Operation unit 150)
The operation unit 150 receives an instruction of operation information such as an operation mode of the air conditioner 100, temperature setting, humidity setting, air volume setting, and wind direction setting. The operation unit 150 is a remote controller attached to the air conditioner 100. In addition, a smartphone, a mobile phone, a PDA (Personal Digital Assistant), a personal computer, or a tablet may be used as the operation unit 150.

  The first unit 10 and the second unit 50 configured as described above are connected to each other by the refrigerant pipe 4 including the gas side communication pipe 4A and the liquid side communication pipe 4B, and the refrigerant circuit A is thus configured. . That is, the refrigerant circuit A is configured by connecting the compressor 53 a, the flow path switching device 53 b, the first heat exchanger 11, the pressure reducing device 53 d, and the second heat exchanger 51 by the refrigerant pipe 4.

<Air conditioning operation of air conditioner 100>
Next, the air conditioning operation of the air conditioning apparatus 100 will be described along with the flow of the refrigerant based on FIG. Here, the operation of the air conditioner 100 will be described by taking, as an example, the case where the heat exchange fluid that exchanges heat with the refrigerant in the first heat exchanger 11 and the second heat exchanger 51 is air.

First, the cooling operation performed by the air conditioning apparatus 100 will be described.
By driving the compressor 53a, the refrigerant in a gas state of high temperature and high pressure is discharged. Hereinafter, the refrigerant flows according to the solid arrow. The high temperature and high pressure gas refrigerant discharged from the compressor 53a flows into the second heat exchanger 51 functioning as a condenser via the flow path switching device 53b. In the second heat exchanger 51, heat exchange is performed between the inflowing high-temperature and high-pressure gas refrigerant and the air supplied by the second blower fan 53c, and the high-temperature and high-pressure gas refrigerant condenses to a high pressure. It becomes liquid refrigerant.

  The high-pressure liquid refrigerant sent from the second heat exchanger 51 is converted into a two-phase refrigerant of low-pressure gas refrigerant and liquid refrigerant by the pressure reducing device 53d. The two-phase refrigerant flows into the first heat exchanger 11 functioning as an evaporator. In the first heat exchanger 11, heat exchange is performed between the inflowing two-phase refrigerant and the air supplied by the first blower fan 13a, and the liquid refrigerant in the two-phase refrigerant evaporates. It becomes a low pressure gas refrigerant. The room is cooled by this heat exchange. The low-pressure gas refrigerant sent from the first heat exchanger 11 flows into the compressor 53a via the flow path switching device 53b, is compressed and becomes a high-temperature and high-pressure gas refrigerant, and is discharged again from the compressor 53a. Hereinafter, this cycle is repeated.

Next, the heating operation performed by the air conditioning apparatus 100 will be described.
By driving the compressor 53a, the refrigerant in the gas state of high temperature and high pressure is discharged from the compressor 53a. Hereinafter, the refrigerant flows according to the broken arrow. The high temperature and high pressure gas refrigerant discharged from the compressor 53a flows into the first heat exchanger 11 functioning as a condenser via the flow path switching device 53b. In the first heat exchanger 11, heat exchange is performed between the inflowing high temperature and high pressure gas refrigerant and the air supplied by the first blower fan 13a, and the high temperature and high pressure gas refrigerant is condensed to a high pressure. It becomes liquid refrigerant. This heat exchange heats the room.

  The high-pressure liquid refrigerant sent from the first heat exchanger 11 becomes a refrigerant in a two-phase state of a low-pressure gas refrigerant and a liquid refrigerant by the pressure reducing device 53d. The two-phase refrigerant flows into the second heat exchanger 51 functioning as an evaporator. In the second heat exchanger 51, heat exchange is performed between the inflowing two-phase refrigerant and the air supplied by the second blower fan 53c, and the liquid refrigerant in the two-phase refrigerant evaporates. It becomes a low pressure gas refrigerant. The low-pressure gas refrigerant sent from the second heat exchanger 51 flows into the compressor 53a via the flow path switching device 53b, is compressed and becomes a high-temperature and high-pressure gas refrigerant, and is discharged again from the compressor 53a. Hereinafter, this cycle is repeated.

  In the air conditioning apparatus 100, the cooling operation or the heating operation can be performed by switching the refrigerant flow path by controlling the flow path switching device 53b. When the flow path switching device 53 b is controlled as shown by the solid line in FIG. 2, the air conditioner 100 performs the cooling operation. On the other hand, when the flow path switching device 53b is controlled as shown by a broken line in FIG. 2, the air conditioning apparatus 100 performs a heating operation. However, the flow path switching device 53b is not essential, and the air conditioner 100 may perform either the cooling operation or the heating operation.

<System Configuration of Air Conditioner 100>
FIG. 3 is a block diagram showing an example of a system configuration of the air conditioning apparatus 100. As shown in FIG. The system configuration of the air conditioner 100 will be described based on FIG. 3. In FIG. 3, the first blower fan 13a, the left and right louvers 13b, and the upper and lower louvers 13c are referred to as the first actuator portion 13, and the compressor 53a, the flow switching device 53b, the second blower fan 53c, and the pressure reducing device 53d are second actuators. It shall be called a part 53.

  The left and right louvers 13b of the first actuator unit 13 are installed in the path of the air that has passed through the first heat exchanger 11, and variably adjust the wind direction in the left and right direction of the air blown out from the outlet of the first unit 10. It is a thing.

  The first electric component 12 has a first processing unit 12a and a first control unit 12b. The first processing unit 12 a performs arithmetic processing on the content of the instruction from the user via the operation unit 150 and the information obtained by the sensor unit 14-1. The first control unit 12 b controls the operation of the first actuator unit 13 and the sensor unit 14-1 based on the processing result of the first processing unit 12 a and the instruction content from the user via the operation unit 150.

  Further, the first electric component 12 has a function of transmitting and receiving information to and from the second electric component 52 in a wired or wireless manner. The first electric component 12 can be configured by hardware such as a circuit device that realizes the function, or can be configured by an arithmetic device such as a microcomputer and software executed thereon. You can also. Furthermore, by providing a communication device capable of connecting to the Internet or the cloud, the first electric component 12 is not provided to the first unit 10, but is connected to the Internet or an application on the cloud or the Internet or the cloud May be included in the

  The sensor unit 14-1 includes a communication device 14a, a drive device 14b, and a rotation unit 15. The communication device 14 a supplies power to the rotating unit 15 and performs signal communication on the information acquired by the rotating unit 15. That is, the communication device 14a has functions as a power supply unit and a signal unit. The driving device 14 b drives the rotating unit 15.

  The rotation unit 15 acquires, as a temperature data, temperature information of a space in which the first unit 10 is installed, and an imaging unit 15 b that acquires temperature information of the space in which the first unit 10 is installed as a thermal image. It has a detection unit 15a. Although FIG. 3 shows the case where both the imaging unit 15b and the temperature detection unit 15a are provided in the rotation unit 15, it is sufficient if at least one of the imaging unit 15b and the temperature detection unit 15a is provided. The imaging unit 15b and the temperature detection unit 15a are not particularly limited, and any type may be applied as the imaging unit 15b and the temperature detection unit 15a as long as it has the above-described function.

  The second electrical component 52 includes a second processing unit 52a and a second control unit 52b. The second processing unit 52 a performs arithmetic processing on the instruction content from the user transmitted through the first electrical component 12 and the information obtained by the sensor unit 14-1. The second control unit 52 b controls the second actuator unit 53 based on the processing result of the second processing unit 52 a.

  The information input to the second electrical component 52 may also include information from various sensors installed in the second unit 50. Various sensors include an outside air temperature sensor for measuring the outside air temperature, a temperature sensor for measuring the refrigerant temperature on the suction side of the compressor 53a, a temperature sensor for measuring the refrigerant temperature on the discharge side of the compressor 53a, and a second heat exchange There is a temperature sensor or the like that measures the temperature of the refrigerant at the refrigerant inlet and outlet of the unit 51. In addition, various sensors include a suction pressure sensor that measures the refrigerant pressure on the suction side of the compressor 53a, a discharge pressure sensor that measures the refrigerant pressure on the discharge side of the compressor 53a, and a refrigerant inlet / outlet of the second heat exchanger 51. There is a pressure sensor or the like that measures the pressure of the refrigerant.

The second electric component 52 can be configured by hardware such as a circuit device that realizes the function, or can be configured by an arithmetic device such as a microcomputer and software executed thereon .
The air conditioning apparatus 100 may be centrally controlled by any one of the first electrical component 12 and the second electrical component 52.

  FIG. 4 is an enlarged cross-sectional view schematically showing the sensor unit 14-1 of the first unit 10 of the air conditioning apparatus 100. As shown in FIG. FIG. 5 is a bottom view schematically showing the sensor unit 14-1 of the first unit 10 of the air conditioning apparatus 100 in an enlarged manner. FIG. 6 is a schematic view illustrating a temperature detection range at the time of initial setting of the sensor unit 14-1 of the first unit 10 of the air conditioning apparatus 100. The sensor unit 14-1 of the first unit 10 will be described based on FIGS. 4 to 6.

  Here, a stepping motor is used as the driving device 14b, and a case where the rotating portion 15 is rotated by the operation of the stepping motor will be described as an example. Moreover, the case where the rotation part 15 has only the temperature detection part 15a is demonstrated to an example. However, the rotation unit 15 may have only the imaging unit 15 b instead of the temperature detection unit 15 a.

  As shown in FIG. 4, the sensor unit 14-1 is installed such that the rotating unit 15 is exposed to the outside of the housing 10 a from the bottom of the housing 10 a. The rotation unit 15 is connected to the drive device 14 b and rotationally driven by the drive device 14 b. The driving device 14b is disposed inside the housing 10a. A communication device 14a is installed around the drive device 14b, and transmits power and signals sent from the first electric component 12 to the drive device 14b. When this state is viewed from the bottom, as shown in FIG. 5, only the rotating portion 15 is exposed to the outside of the housing 10 a and is visible.

  As shown in FIG. 6, a room where the first unit 10 is installed is referred to as an air conditioning target space R. As shown in FIG. 6, the wall on the window side of the air conditioning target space R in which the first unit 10 is installed is referred to as an installation wall W1. As shown in FIG. 6, the wall on the right side of the air-conditioning object space R seen from the first unit 10 is referred to as a right wall W2. As shown in FIG. 6, a wall on the back side of the air conditioning target space R seen from the first unit 10 is referred to as a back wall W3. As shown in FIG. 6, the left side wall of the air conditioning target space R viewed from the first unit 10 is referred to as a left wall W4. As shown in FIG. 6, the floor surface of the air conditioning target space R is referred to as a floor F.

  The 1st unit 10 which air-conditions air-conditioning object space R is installed in installation wall W1, for example. The sensor unit 14-1 is attached to the first unit 10. As shown in FIGS. 4 and 5, the temperature detection unit 15 a of the sensor unit 14-1 is built in the rotation unit 15 or installed on the surface of the rotation unit 15. Then, the temperature detection unit 15a rotates in one direction in accordance with the operation of the rotation unit 15, and acquires temperature data of the air-conditioned space R while changing the detection direction, that is, the scanning range.

  At the time of initial setting, for example, as shown in FIG. 6, the air conditioner 100 rotationally drives 360 degrees in one direction as shown by arrow A1, with the range of arrow R1 as the temperature detection range at temperature detecting portion 15a. Is set as When the temperature detection unit 15a is rotated by the drive device 14b in the initial setting state, the range of the arrow R1 shown in FIG. 6 changes with the rotation of the temperature detection unit 15a, and the temperature detection of the air conditioning target space R is performed. It will be done.

  In order to rotate the rotating unit 15 360 degrees in one direction, it is necessary to connect the communication device 14 a and the rotating unit 15 using a slip ring or a noncontact rotary connector. Here, the slip ring and the noncontact rotary connector will be briefly described. FIG. 7 is a schematic view schematically showing the configuration of the slip ring 200. As shown in FIG.

As shown in FIG. 7, the slip ring 200 includes a plurality of ring portions 201, a plurality of brush portions 202, an inner casing 206 accommodating the ring portions 201 and the brush portions 202, and an outer casing 205 accommodating the inner casing 206. Have.
The outer casing 205 constitutes the outer shell of the slip ring 200, and may be formed of metal or resin. The outer casing 205 is formed with a plurality of openings through which the wires 210 connected to the communication device 14a are inserted.

  The inner casing 206 is accommodated in the outer casing 205 while accommodating the ring portion 201 and the brush portion 202. Further, the inner casing 206 accommodates the ring portion 201 and the brush portion 202, and also connects the base end side shaft portion 15A and the rotation portion 15 which constitute the base end of the rotation portion 15 with the base end side shaft portion 15A. It accommodates a part of the shaft portion 15B. The inner casing 206 is made of resin or the like, and has a plurality of openings or slits through which the brush portion 202 can be inserted.

The ring portion 201 is made of metal and installed on the outer peripheral portion of the proximal shaft portion 15A.
The brush portion 202 is installed on the ring portion 201 installed on the outer peripheral portion of the proximal end side shaft portion 15A, and is connected to the wiring 210.
Although FIG. 7 illustrates the slip ring 200 of the type attached to the base end of the rotating portion 15, the present invention is not limited to this type, and the slip ring 200 may be attached to the middle of the rotating portion 15 as well. Good.

By interposing the slip ring 200, which is a rotary connector configured as described above, between the communication device 14a and the rotary unit 15, the rotary unit 15 can be continuously rotated 360 degrees in one direction.
In place of the slip ring 200, a noncontact rotary connector may be interposed between the communication device 14a and the rotary unit 15. The noncontact rotary connector transmits the power and signal from the communication device 14a to the rotary unit 15 by optical communication. When the noncontact rotary connector is used, the ring portion 201 and the brush portion 202, which are the configuration of the slip ring 200, become unnecessary, and the size is further reduced.

  Here, temperature detection of the air conditioning target space R at the time of initial setting of the first unit 10 will be described. FIG. 8 is a graph showing an example of data obtained by arranging the detected temperature data of the air conditioning target space R for 360 degrees in time series. FIG. 9 is a graph schematically showing the condition of the air conditioning target space R viewed from the position of the sensor unit. In FIG. 8, the upward dotted line from the sensor unit 14-1 is 0 degrees, and temperature data when the condition of the air conditioning target space R is detected counterclockwise is arranged for 360 degrees in time series. FIG. 9 is obtained by inverting the time series of the data acquired in FIG. 8 and applying the identification results of the installation wall W1, the right wall W2, the back wall W3, the left wall W4, and the floor F.

  When the cooling operation or the heating operation performed by the air conditioning apparatus 100 is stabilized, the temperature zone 2 detected by the sensor unit 14-1 becomes the temperature zone 1, the temperature zone 3 becomes the temperature zone 5, and the temperature zone 4 Is the temperature zone 6. That is, the temperature zone detected at the start of the operation of the air conditioner 100 and the temperature zone detected at the time when the operation of the air conditioner 100 is stabilized are different. From the change result of the temperature zone, it can be identified that the temperature zone 1 and the temperature zone 5 are temperature data detected from the installation wall W1, and it can be distinguished that the temperature zone 6 is temperature data detected from the floor F.

  Further, the right wall W2, the back wall W3 and the left wall W4 are allocated from the rotation direction of the sensor unit 14-1. Then, the difference between the back wall W3 and the right wall W2 and the left wall W4 is determined by the difference in the position of the temperature detection unit 15a that detects the temperature zone 6. That is, as shown in FIG. 6, when the first unit 10 is installed at a position close to the left wall W4, the time for detecting the left wall W4 becomes longer at the time of initial setting, so The right wall W2, the back wall W3 and the left wall W4 can be identified from the detection time. When the rotation direction of the sensor unit 14-1 is clockwise, the allocation of the right wall W2 and the left wall W4 is reversed.

  Thus, in the air conditioning apparatus 100, by analyzing the temperature data for 360 degrees, the estimation accuracy of the position of the wall and the floor of the air conditioning target space R is improved. Therefore, according to the air conditioning apparatus 100, the accuracy of airflow control using the walls and floor of the air conditioning target space R is improved, and the comfort of the air conditioning target space R such as a living space is also improved. Furthermore, according to the air conditioning apparatus 100, the accuracy of the air flow control is improved, so the reduction effect of the energy consumption can be obtained.

  Next, an example of rotation control of the sensor unit 14-1 will be described. FIG. 10 is a flowchart showing a flow of processing when controlling rotation of the sensor unit 14-1 of the air conditioning apparatus 100. As described above, the sensor unit 14-1 continues to rotate 360 degrees in one direction. That is, the sensor unit 14-1 acquires temperature data of the air conditioning target space R while rotating at the rotational speed set at the time of initial setting. In addition, if the imaging part 15b is installed, it will become possible to acquire the temperature data of the air-conditioning object space R as a thermal image.

  By the way, the sensor unit 14-1 continues to rotate 360 degrees in one direction, and the temperature detection range deviates from the air conditioning target space R at a constant timing. That is, the case where the temperature detection range of sensor part 14-1 turns to the direction of installation wall W1 arises. So, in the air conditioning apparatus 100, the rotational speed of the sensor part 14-1 is adjusted, and the rotational speed of the sensor part 14-1 is made changeable.

  When the air conditioning apparatus 100 starts operation, the sensor unit 14-1 starts to rotate at the initial set speed (step S101). At the same time, the sensor unit 14-1 acquires temperature data of the air conditioning target space R (step S102). Here, the first electrical component 12 determines whether the temperature detection range of the sensor unit 14-1 is directed to the air conditioning target space R (step S103). As a result, when the temperature detection range of the sensor unit 14-1 is directed to the air conditioning target space R (Step S103; Yes), the first electrical component 12 rotates the sensor unit 14-1 at a low speed (Step S104). ). On the other hand, when the temperature detection range of the sensor unit 14-1 does not face the air conditioning target space R (step S103; No), the first electrical component 12 rotates the sensor unit 14-1 at high speed (step S105) .

  That is, when the temperature detection range of the sensor unit 14-1 is directed to the air conditioning target space R, the accuracy of temperature detection is improved by rotating the sensor unit 14-1 at a low speed. On the other hand, when the temperature detection range of the sensor unit 14-1 does not face the air conditioning target space R, the time until the temperature detection range faces the air conditioning target space R by rotating the sensor unit 14-1 at high speed To shorten the By doing this, in the air conditioner 100, the time lag is reduced.

Here, the case where the rotational speed of the rotation part 15 was adjusted by changing the rotational speed of the sensor part 14-1 with the position of the temperature detection range was demonstrated. That is, in the air conditioning apparatus 100, the temperature detection accuracy is improved by adjusting the rotational speed of the sensor unit 14-1.
The low speed is a speed equal to or lower than the initial setting speed, and the high speed is a speed higher than the initial setting speed. However, the initial setting speed may be the same as the high speed in step S105. In this case, low speed is slower than the initial set speed.

Next, adjustment of the temperature detection range of the sensor unit 14-1 will be described. FIG. 11 is a schematic view illustrating the temperature detection range after adjustment of the sensor unit 14-1 of the first unit 10 of the air conditioning apparatus 100.
As shown in FIG. 6, at the time of installation of the first unit 10, there may be a difference between the direction of the initially set temperature detection range and the direction of the temperature detection range when actually installed. . That is, the first unit 10 is not necessarily installed at the center in the left-right direction of the installation wall W1, but often installed at a position close to the right wall W2 or a position close to the left wall W4.

  For example, in the case of FIG. 6, the first unit 10 is installed at a position near the left wall W4. In such a case, if temperature detection is performed in the state of being initialized, the time during which the left wall W4 is detected becomes long. Therefore, variation occurs in the range of the space to be air-conditioned R air-conditioned by the air conditioning apparatus 100. Therefore, the detection result shown in FIG. 9 is recorded, and the direction to be mainly detected as the air conditioning target space R is adjusted. That is, as shown in FIG. 10, the temperature detection range is shifted to the right wall W2 side as compared with the time of initial setting, and the time during which the right wall W2 and the left wall W4 are detected is not biased. Thus, in the air conditioning apparatus 100, by adjusting the temperature detection range of the sensor unit 14-1, the risk of generating a blind spot in the range of the air conditioning target space R that can be detected by the sensor unit 14-1 is reduced. doing.

  After adjustment as shown in FIG. 10, the heating operation is performed, and when the wind direction is automatically set, the directions of the upper and lower louvers 13c and the left and right louvers 13b are adjusted, and the air blown out from the first unit 10 is the right wall W2 and the left. It may be adjusted to be in the direction of the wall W4 or in the direction of the back wall W3. Further, after adjustment as shown in FIG. 10, in the cooling operation, when the wind direction is automatically set, the directions of the upper and lower louvers 13c and the left and right louvers 13b are adjusted, and the air blown out from the first unit 10 is on the floor F. The direction or the direction of the back wall W3 may be adjusted.

  As mentioned above, the air conditioning apparatus 100 has the rotation part 15 which rotates in one direction, and the 1st electrical component 12 which functions as a control apparatus rotates the rotation part 15 by the position of the temperature detection range of a detection part. It is supposed to adjust the speed. Therefore, according to the air conditioning apparatus 100, since the rotating portion 15 of the sensor unit 14-1 is rotated in one direction, the influence of the backlash of the driving device 14b and the openness of the link is reduced. Moreover, according to the air conditioning apparatus 100, since the rotational speed of the rotation part 15 of the sensor part 14-1 is adjusted, the influence of a time lag can be suppressed. As a result, according to the air conditioning apparatus 100, the accuracy of the background subtraction method is improved in image processing such as temperature data acquired by the sensor unit 14-1.

  In the air conditioner 100, when the temperature detection range of the detection unit faces the air conditioning target space R when the first electric component 12 faces the air conditioning target space R, and when the temperature detection range of the detection unit does not face the air conditioning target space R Then, the rotation speed of the rotation unit 15 is switched. Therefore, according to the air conditioning apparatus 100, for example, when the temperature detection range of the detection unit is directed to the air conditioning target space, the rotational speed can be low, and the accuracy of temperature detection of the air conditioning target space is improved.

  According to the air conditioning apparatus 100, since the first electric component 12 sets the temperature data detected by the sensor unit 14-1 as one integrated data for 360 degrees, the data for 360 degrees can be analyzed. The estimation accuracy of the position of the wall and the floor of the air conditioning target space R is improved. As a result, the accuracy of the airflow control using the wall or the floor is improved, and the comfort improvement of the air conditioning target space and the reduction effect of the energy consumption can be obtained.

  According to the air conditioning apparatus 100, since the rotary unit 15 and the drive device 14b are connected by the slip ring 200 or the noncontact rotary connector, the rotary unit 15 is rotated in one direction without adopting a complicated configuration. It will be possible to

  According to the air conditioning apparatus 100, since the detection unit is at least one of the imaging unit and the temperature detection unit, temperature detection of the air conditioning target space R can be performed without adopting a complicated configuration. .

Second Embodiment
FIG. 12 is an enlarged schematic cross-sectional view of the sensor unit 14-2 of the first unit 10 of the air conditioning apparatus according to Embodiment 2 of the present invention. FIG. 13 is an enlarged bottom view schematically showing a sensor unit 14-2 of the first unit 10 of the air conditioning apparatus according to Embodiment 2 of the present invention. The sensor unit 14-2 will be described based on FIGS. 12 and 13. In the second embodiment, differences from the first embodiment will be mainly described, and the same parts as the first embodiment will be assigned the same reference numerals and descriptions thereof will be omitted.

  The basic configuration of the sensor unit 14-2 is the same as the sensor unit 14-1 described in the first embodiment, except that the rotation unit 15 includes the temperature detection unit 15a and the imaging unit 15b. This differs from the sensor unit 14-1 described in the first embodiment. The temperature detection unit 15a and the imaging unit 15b are disposed at an interval of an angle obtained by 360 degrees (the total number of the temperature detection unit 15a and the imaging unit 15b). For example, when one temperature detection unit 15a and one imaging unit 15b are installed, the temperature detection unit 15a and the imaging unit 15b are installed at an interval of 360 degrees / 2 = 180 degrees. When the total number of the temperature detection unit 15a and the imaging unit 15b is three, the temperature detection unit 15a and the imaging unit 15b are installed at an interval of 360 degrees ÷ 3 = 120 degrees. That is, it is good to arrange at equal intervals.

  In this way, the temperature detection range and the temperature detection range by the imaging unit 15b can be equalized by the temperature detection unit 15a, and the temperature state of the air conditioning target space R can be detected more accurately. A plurality of imaging units 15b may be provided without providing the temperature detection unit 15a, or only a plurality of temperature detection units 15a may be provided without providing the imaging unit 15b. In the following description, the temperature detection unit 15a and the imaging unit 15b may be collectively referred to as a detection unit.

  When the total number of the temperature detection unit 15a and the imaging unit 15b is plural, the temperature data for 360 degrees may be collectively created for each temperature data acquired by each detection unit, or acquired by each detection unit. Temperature data may be added and created.

  Next, an example of control of the sensor unit 14-2 will be described. FIG. 14 is a flowchart showing a flow of processing when controlling the sensor unit 14-2 of the air conditioning apparatus according to Embodiment 2 of the present invention.

  When the air conditioner starts operating, the sensor unit 14-2 starts to rotate at the initial set speed (step S201). At the same time, the sensor unit 14-2 acquires temperature data of the air conditioning target space R by the temperature detection unit 15a (step S202). Here, the first electrical component 12 determines whether the temperature detection range of the temperature detection unit 15a is directed to the air conditioning target space R (step S203). As a result, when the temperature detection range of the temperature detection unit 15a faces the air conditioning target space R (Step S203; Yes), the first electrical component 12 rotates the sensor unit 14-2 at a low speed (Step S204) . On the other hand, when the temperature detection range of the temperature detection unit 15a does not face the air conditioning target space R (Step S203; No), the first electrical component 12 rotates the sensor unit 14-2 at high speed (Step S205).

  Next, the sensor unit 14-2 acquires temperature data of the air conditioning target space R by the imaging unit 15b (step S206). Here, the first electrical component 12 determines whether the temperature detection range of the imaging unit 15b is directed to the air conditioning target space R (step S207). As a result, when the temperature detection range of the imaging unit 15b faces the air conditioning target space R (Step S207; Yes), the first electric component 12 rotates the sensor unit 14-2 at a low speed (Step S208). On the other hand, when the temperature detection range of the imaging unit 15b does not face the air conditioning target space R (Step S207; No), the first electrical component 12 rotates the sensor unit 14-2 at high speed (Step S209).

  As described above, in the air conditioning apparatus according to Embodiment 2 of the present invention, the rotational speed of the sensor unit 14-2 is adjusted. That is, when the temperature detection range of each detection unit of the sensor unit 14-2 is directed to the air conditioning target space R, the accuracy of temperature detection is improved by rotating the sensor unit 14-2 at a low speed. ing. On the other hand, when the temperature detection range of each detection unit of the sensor unit 14-2 does not face the air conditioning target space R, the temperature detection range is adjusted to the air conditioning target space R by rotating the sensor unit 14-2 at high speed. I try to shorten the time to turn.

  Here, as in the first embodiment, the case where the rotation speed of the rotation unit 15 is adjusted by changing the rotation speed of the sensor unit 14-2 according to the position of the temperature detection range has been described. That is, in the air conditioning apparatus according to Embodiment 2 of the present invention, the temperature detection accuracy is improved by adjusting the rotational speed of the sensor unit 14-1.

  Although the embodiments of the present invention have been described by separating the case, the present invention is not limited to the contents described in the embodiments, and can be appropriately modified without departing from the scope of the present invention. Further, in the air conditioners according to Embodiment 1 of the present invention and Embodiment 2 of the present invention, a humidifier that humidifies the air conditioning target space R, a dehumidifier that dehumidifies the air conditioning target space R, or air conditioning It is assumed that a humidifying / dehumidifying device that humidifies / dehumidifies the target space R is included. Further, although the case where the first unit 10 is the wall hanging type has been described as an example, the first unit 10 may be a ceiling embedded type or a floor type.

  4 refrigerant piping, 4A gas side communication piping, 4B liquid side communication piping, 10 first unit, 10a case, 11 first heat exchanger, 12 first electric component, 12a first processing unit, 12b first control unit, 13 first actuator unit, 13a first blower fan, 13b left and right louvers, 13c upper and lower louvers, 14-1 sensor unit, 14-2 sensor unit, 14a communication device, 14b drive device, 15 rotating unit, 15A proximal end shaft unit , 15B connecting shaft portion, 15a temperature detecting portion, 15b imaging portion, 50 second unit, 50a case, 51 second heat exchanger, 52 second electric component, 52a second processing portion, 52b second control portion, 53 Second actuator unit, 53a compressor, 53b flow path switching device, 53c second blower fan, 53d pressure reducing device, 100 air conditioner, 150 operation unit, 200 slip ring, 201 ring portion, 202 brush portion, 205 outer casing, 206 inner casing, 210 wiring, A refrigerant circuit, F floor, R air conditioning target space, W1 installation wall, W2 right wall, W3 back wall, W4 left wall .

Claims (7)

A sensor unit provided with one or more detection units for detecting the temperature of the air conditioning target space and a rotation unit having the detection unit;
A driving device for rotating the rotating portion in one direction;
A control device that controls the rotation of the rotating unit via the drive device;
The controller is
An air conditioner, which adjusts the rotational speed of the rotating unit according to the position of the temperature detection range of the detecting unit. The controller is
The rotational speed of the rotating unit is switched between when the temperature detection range of the detection unit faces the air conditioning target space and when the temperature detection range of the detection unit does not face the air conditioning target space. The air conditioner as described in. The controller is
The air conditioning apparatus according to claim 1, wherein the temperature data detected by the sensor unit is one unit of 360 ° data. The rotating unit and the driving device are
The air conditioner according to any one of claims 1 to 3, which is connected by a slip ring or a noncontact rotary connector. The detection unit
The air conditioner according to any one of claims 1 to 4, which is at least one of an imaging unit and a temperature detection unit. Equipped with upper and lower louvers, left and right louvers, and a blower fan,
The controller is
The air conditioning apparatus according to any one of claims 1 to 5, wherein the upper and lower louvers, the left and right louvers, the blower fan, and the drive device are controlled based on temperature data detected by the sensor unit. The air conditioning apparatus according to any one of claims 1 to 6, wherein the air conditioning apparatus is used as an apparatus for heating, cooling, dehumidifying, or humidifying the space to be air-conditioned.

Images