JP2005233538A - Air conditioner - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To improve the maintainability of an air conditioner having a self-diagnosing function. <P>SOLUTION: A remote control switch enables switching between a normal mode and a service mode. When a push button is operated in the service mode, it requests the output of an error code based on the results of self-diagnosis (steps 200, 202, 210). The microcomputer of an indoor unit comprises the self-diagnosing function. When it receives signals according to the operation of the push button in the service mode, it transmits an error code based on the results of the self-diagnosis (steps 220, 222, 226). When receiving the error code, the remote control switch displays an image showing the received error code (steps 212, 214) and facilitates the confirmation of the results of the self-diagnosis. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to an air conditioner that achieves air conditioning in an air-conditioned room using a refrigeration cycle.

  In an air conditioner (hereinafter referred to as an air conditioner) for air conditioning in an air-conditioned room, for example, a refrigerant is placed between a heat exchanger of an indoor unit installed in the air-conditioned room and a compressor of an outdoor unit installed outdoors. A circulating refrigeration cycle is formed. In the indoor unit, air in the air-conditioned room is sucked and the air sucked through the heat exchanger is blown out into the air-conditioned room. When this air passes through the heat exchanger, the temperature is adjusted by heat exchange with the refrigerant circulated through the refrigeration cycle, and the air is blown into the air-conditioned room.

  In such an air conditioner, operation / stop and various settings are performed by operating a remote control switch, and operation is performed according to the operation of the remote control switch. Moreover, as a remote control switch, a wireless system that transmits an operation state using infrared rays or the like is common.

  On the other hand, in an air conditioner, a remote control switch capable of bidirectional communication with an indoor unit may be used. Between such a remote control switch and an indoor unit, for example, the outside air temperature detected by the outdoor unit is taken into the indoor unit, and the outside air temperature or the like is transmitted from the indoor unit to the remote control switch and displayed on the remote control switch. Proposals have been made (see, for example, Patent Document 1).

  In addition, since bidirectional communication is possible between the remote control switch and the indoor unit, for example, an air conditioner that integrates power consumption etc. in the indoor unit and transmits the integration result to the remote control switch for display is proposed. (For example, refer to Patent Document 2).

  By the way, in the air conditioner, the microcomputer (microcomputer) provided in the indoor unit performs self-diagnosis as to whether various sensors, compressors, etc. are operating properly, stores the diagnosis results, and performs maintenance and the like. In some cases, a serviceman displays a stored self-diagnosis result by performing a predetermined switch operation on an indoor unit or connecting a predetermined jig.

  This makes it possible to accurately determine the location of the failure, thus enabling efficient maintenance.

  However, there is a concealment type housing air conditioner such as a ceiling-embedded air conditioner, and such an air conditioner has a problem that the self-diagnosis result cannot be easily confirmed. In addition, even with a wall-mounted air conditioner that attaches an indoor unit to a wall surface, the indoor unit may be mounted at a relatively high position, or the work space required around the indoor unit may not be secured due to furniture or the like. .

Moreover, even if the failure part is an outdoor unit, the work must first be performed on the indoor unit, and it is not always possible to ensure efficient maintenance.
JP 2003-148791 A Japanese Patent No. 3454195

  This invention is made | formed in view of the said fact, and aims at proposing the air conditioner which can ensure more efficient workability | operativity at the time of a maintenance.

  In order to achieve the above object, the present invention is an air conditioner that enables air-conditioning of a room to be air-conditioned by a refrigeration cycle in accordance with an operation of a remote control switch and performs self-diagnosis of parts or functions. Communication means for enabling two-way communication with the remote control switch, communication control means for transmitting a self-diagnosis result when an output of the self-diagnosis result is requested via the communication means, and the remote control switch Display means for displaying an image according to the self-diagnosis result transmitted from the communication means.

  According to the present invention, the air-conditioned room is air-conditioned by performing the air-conditioning operation based on the operating conditions set by operating the remote control switch. It also has a self-diagnosis function, and detects and stores the presence or absence of a component failure or the presence or absence of a functional failure.

  Further, bidirectional communication is possible with the remote control switch by the communication means, and when the self-diagnosis result is requested from the remote control switch, the self-diagnosis result is output by the communication means.

  When receiving the self-diagnosis result, the remote control switch displays an image corresponding to the received content on the display means.

  As a result, the self-diagnosis result can be accurately determined by the display on the remote control switch without touching the indoor unit or the like, so that the workability when performing maintenance or the like can be improved.

  Such a remote control switch applied to the present invention includes: a transmission unit that transmits a signal according to a switch operation; a reception unit that receives a signal transmitted from the communication unit; and a transmission unit that receives a signal transmitted from the communication unit. A remote control unit that transmits a signal requesting output of the self-diagnosis result and displays an image based on the self-diagnosis result received by the receiving unit as an error code on the display means may be used. .

  Further, as a remote control switch applied to the present invention, the self-diagnosis result of the self-diagnosis result is obtained by a normal mode and a switch operation for transmitting a signal for setting an operation / stop of air conditioning operation and an air conditioning condition according to the switch operation to the remote control switch. It is preferable that switching means for switching the service mode for requesting output is included.

  As this switching means, a remote control switch may be provided with a dedicated switching switch, or may be switched by simultaneous operation of a plurality of preset keys, thereby unnecessarily entering the service mode. It is possible to reliably prevent the switching.

  As described above, according to the present invention, since the self-diagnosis result can be easily displayed using the remote control switch for performing the driving operation, the workability at the time of maintenance can be remarkably improved. An effect is obtained.

  Hereinafter, an embodiment of the present invention will be described with reference to the drawings. FIG. 1 shows an air conditioner (hereinafter referred to as “air conditioner 10”) applied to the present embodiment. The air conditioner 10 includes an indoor unit 12 installed in an air-conditioned room and an outdoor unit 14 installed outdoors.

  In addition, as an air conditioner to which this invention is applied, the thing connected to the solar power generation device which converts the electric power generated with solar energy into the electric power of a predetermined voltage, and outputs it may be connected. At this time, the operation of the photovoltaic power generation apparatus is controlled by a microcomputer provided in the outdoor unit 14, and the generated power is supplied to the outdoor unit 14 or the indoor unit 12 and the outdoor unit 14, and air conditioning operation or the like is performed using this power. It may be.

  As shown in FIG. 2, the indoor unit 12 and the outdoor unit 14 are connected to each other by a thick refrigerant pipe 16A and a thin refrigerant pipe 16B. The indoor unit 12 is provided with a heat exchanger 18, and each of the refrigerant pipes 16 </ b> A and 16 </ b> B is connected to the heat exchanger 18.

  The outdoor unit 14 is provided with valves 20A and 20B, the refrigerant pipe 16A is connected to the valve 20A, and the refrigerant pipe 16B is connected to the valve 20B. A four-way valve 24 is connected to the valve 20A via a muffler 22A.

  The outdoor unit 14 is provided with a compressor 26 and a heat exchanger 28, and each of the accumulator 30 and the muffler 22B connected to the compressor 26 is connected to the four-way valve 24, and the heat exchanger. One end of 28 is connected to the four-way valve 24.

  Furthermore, the other end of the heat exchanger 28 is connected to the valve 20 </ b> B via the capillary tube 32, the strainer 34, the electric expansion valve 36 and the modulator 38.

  Thereby, in the air conditioner 10, a refrigeration cycle for circulating the refrigerant is formed between the indoor unit 12 and the outdoor unit 14. In addition, this refrigeration cycle shows an example and does not limit the structure of an air conditioner.

  The air conditioner 10 can be operated in the heating mode or in the cooling mode including the dry mode (dehumidification mode) by switching the four-way valve 24. In addition, in FIG. 2, the flow of the refrigerant | coolant in air_conditioning | cooling mode and heating mode is shown by the arrow.

  As shown in FIG. 1, the indoor unit 12 is provided with a suction port 42 at the upper part and the front side of the casing 12A, and is provided with a blow-out port 44 at the lower part of the casing 12A. The indoor unit 12 is provided with a cross flow fan inside the casing 12 </ b> A. When the cross flow fan is operated, air in the air-conditioned room is sucked from the suction port 42. The sucked air passes through the heat exchanger 18 and is blown into the air-conditioned room. At this time, heat exchange is performed between the air passing through the heat exchanger 18 and the refrigerant circulated through the heat exchanger 18 by the refrigeration cycle, so that the temperature-controlled air is blown into the air-conditioned room. The air-conditioned room is air-conditioned.

  As such an air conditioner 10, a ventilation unit may be provided in the indoor unit 12, and the ventilation unit may discharge air in the air-conditioned room or introduce fresh outside air into the air-conditioned room. In the following, air conditioning operation such as automatic mode, cooling mode, dehumidification mode, cooling mode, ventilation mode using ventilation unit, ventilation mode such as intake mode, exhaust mode, and air using air purification filter or UV sterilization unit A description will be given on the assumption that the air purifying operation in the air purifying mode for removing various fine particles floating therein is possible. At this time, conventionally known arbitrary configurations can be used for the ventilation operation and the air cleaning operation, and detailed description thereof will be omitted below.

  FIG. 3 shows a schematic configuration of the control unit 60 provided in the indoor unit 12. The control unit 60 is provided with a control board 66 together with a power supply board 62 and a power relay board 64. The power supply board 62 includes a motor power supply 68, a control circuit power supply 70, and a serial power supply 72, and is supplied with electric power for operating the air conditioner 10.

  The power supply board 62 is provided with a drive circuit 74, and the fan motor 40 that operates the cross flow fan is connected to the drive circuit 74.

  The control board 66 is provided with a microcomputer (microcomputer 80) for controlling the operation of the air conditioner 10 together with the serial circuit 76 and the drive circuit 78. Power for operation is supplied from the control circuit power supply 70 to the control board 66. The

  The microcomputer 80 provided on the control board 66 outputs a control signal of the fan motor 40 that drives the cross flow fan to the drive circuit 74 of the power supply board 62. As a result, the drive circuit 74 supplies the electric power supplied from the motor power supply 68 to the fan motor 40 based on the control signal input from the microcomputer 80 and drives it. At this time, the microcomputer 80 controls the amount of conditioned air blown from the outlet 44 of the indoor unit 12 by controlling the output voltage from the drive circuit 74 to change between, for example, 12V to 36V. .

  A power relay board 64 is connected to the drive circuit 78 of the control board 66. The power relay board 64 is provided with a power relay 82 and a thermal fuse, and the drive circuit 78 operates the power relay 82 based on a signal from the microcomputer 80. As a result, the contact 82A for supplying power from the indoor unit 12 to the outdoor unit 14 is opened and closed.

  In the air conditioner 10, when the contact 82A of the power relay 82 is closed, electric power is supplied to the outdoor unit 14, and the outdoor unit 14 becomes operable.

  The indoor unit 12 is provided with upper and lower flaps and left and right flaps at the air outlet 44, and the direction of blowing the conditioned air can be controlled by the upper and lower flaps and the left and right flaps. Flap motors 84A and 84B for driving the flaps are connected. The drive circuit 78 drives the flap motors 84A and 84B based on the control signal from the microcomputer 80.

  In the air conditioner 10, the conditioned air can be blown in a desired (arbitrary) direction by driving the flap motors 84A and 84B. That is, the microcomputer 80 controls the driving of the flap motors 84A and 84B together with the fan motor 40, thereby controlling the blowing direction together with the air volume of the conditioned air so that the air-conditioned room is in a desired air-conditioned state. .

  The drive circuit 78 is connected to a fan motor 46 that drives a ventilation fan, and the microcomputer 80 controls the drive of the fan motor 46 to perform intake and ventilation of the air-conditioned room. That is, the microcomputer 80 drives the fan motor 46 when an operation in the ventilation mode, the intake mode, or the exhaust mode is instructed.

  The serial circuit 76 is connected to the serial power supply 72 of the power supply board 62 and is connected to the outdoor unit 14 together with the serial power supply 72. The microcomputer 80 controls the operation of the outdoor unit 14 by performing serial communication with a microcomputer (not shown) provided in the outdoor unit 14 via the serial circuit 76.

  At this time, the microcomputer 80 controls the switching of the four-way valve 24 based on the operation mode (heating mode and dehumidification mode or cooling mode) of the air conditioner 10 and sets the operation frequency of the compressor 26 based on the necessary air conditioning capability. Control and so on.

  Further, the microcomputer 80 receives various information from the microcomputer of the outdoor unit 14 by serial communication.

  On the other hand, a display substrate 86 is provided in the indoor unit 12. The display board 86 is provided with a transmission / reception circuit 90 together with the display LED 88, and the display board 86 is connected to the microcomputer 80.

  The air conditioner 10 can be operated / stopped and various operating conditions can be set by operating a remote control switch 50 (see FIG. 1). The transmission / reception circuit 90 communicates with the remote control switch 50 by a wireless method using, for example, infrared rays. At this time, the transmission / reception circuit 90 receives the operation signal transmitted from the remote control switch 50 and outputs it to the microcomputer 80.

  As a result, the air conditioner 10 can control the air conditioning operation according to the operation of the remote control switch 50. At this time, the microcomputer 80 lights the display LED 88 in accordance with the operating state of the air conditioner 10, and the operation / stop of the air conditioner 10, the operation mode, etc. are clearly indicated from the lighting state of the display LED 88.

  Further, when the remote control switch 50 is provided with a room temperature sensor, when the room temperature detected by the room temperature sensor is transmitted from the remote control switch 50, the microcomputer 80 controls the air conditioning operation based on the room temperature. It has become.

  Further, the microcomputer 80 can transmit various types of information to the remote control switch 50 using the transmission / reception circuit 90.

  The indoor unit 12 is provided with various sensors that detect the operating state of the indoor unit 12, and these sensors are connected to the microcomputer 80 of the control board 66. Based on the detection result, the air conditioning capacity is controlled.

  Such a control board 66 is provided with an operation changeover switch 96 and a service LED 98. The operation changeover switch 96 is used for switching between normal operation and test operation when performing maintenance or the like, and the contact of the power switch 96A is opened and closed by operating the operation changeover switch 96.

  That is, the operation changeover switch 96 can be switched to “normal operation”, “test operation”, or “stop” that opens the contact of the power switch 96A to cut off the supply of power to the indoor unit 12. No. 10 is operated in the “normal operation” position.

  Note that the service LED 98 is turned on by the service person when performing maintenance or the like, so that the microcomputer 80 controls the lighting and lighting state according to the self-diagnosis result. It is easy to check the failure and failure history.

  FIG. 4 shows a schematic configuration of the remote control switch 100 that enables bidirectional transmission / reception with the microcomputer 80 using the transmission / reception circuit 90 (see FIG. 3).

  The remote control switch 50 is provided with a transmission unit 58A and a reception unit 58B together with an operation unit 54 and a display unit 56, as well as a remote control unit 52 that controls the operation of the remote control switch 50 itself. In the remote control unit 52, various key operations (button operations) provided on the operation unit 54 are performed, whereby information corresponding to the operation state is displayed on the display unit 56 and transmitted from the transmission unit 58A.

  In addition, when the remote control unit 52 receives predetermined information via the receiving unit 58B, the remote control unit 52 performs display based on the received information on the display unit 56. The remote control switch 100 is provided with a temperature sensor 59B together with a timer 59A for measuring time, and the remote control unit 52 uses the temperature detected by the temperature sensor 59B as the room temperature in the air-conditioned room at a predetermined timing. Transmit to the indoor unit 12.

  On the other hand, FIGS. 5A and 5B show an example of a remote control switch 50 provided in the air conditioner 10. As shown in FIG. 5A, the remote control switch 50 is provided with an operation cover 102, and FIG. 5B shows a state in which the operation cover 102 is opened.

  The remote control switch 50 is provided with a liquid crystal display (hereinafter referred to as a display 104) that forms a display unit 56, and various displays such as a room temperature and an operation mode are displayed on the display 104. In the display area 106 at the bottom of the display 104, various displays according to the operation of the remote control switch 50 are made.

  5B shows a state in which main icons on the display 104 are displayed, and FIG. 5A shows a state in which the cooling operation is set in the automatic mode and the room temperature. In both FIG. 5A and FIG. 5B, the display area 106 is not displayed.

  As shown in FIGS. 5A and 5B, the remote control switch 50 is provided with a run / stop button 108 as an operation button (operation key) forming the operation unit 54. The operation / stop of the air conditioner 10 can be instructed by operating the stop button 108.

  Further, the remote control switch 50 is provided with a ventilation button 110 and a dehumidifying button 112. By operating the ventilation button 110, the operation in the ventilation mode can be set, and the dehumidifying button 112 is operated. Thus, the dehumidifying mode can be set and operated. In addition, for example, “standard dehumidification”, “strong dehumidification”, “soft dehumidification” and “laundry” can be set in the dehumidification mode, and dehumidification modes are switched in order by depressing the dehumidification button 112. .

  As shown in FIG. 5A, the remote control switch 50 is provided with a simple timer button 114, a UV emptying button 116, a button 118, and an up button 120A and a down button 120B for temperature setting on the operation cover 102. These operations can be performed with the operation cover 102 closed.

  In the remote control switch 50, when the up button 120A to the down button 120B is operated, the set temperature corresponding to the operation of the up button 120A to the down button 120B is displayed in the display area 106 of the display 104. At this time, the set temperature is raised by operating the up button 120A, and the set temperature is lowered by operating the down button 120B. In the automatic mode, an up setting or a down setting with respect to a preset standard temperature is displayed.

  The simple timer button 114 can select and set the operation time of the air conditioner 10 to “1 hour”, “2 hours”, “3 hours”, or “5 hours”. Further, the operation in the emptying mode can be set by operating the UV emptying button 116. In the air cleaning mode, the compressor 26 is stopped, and the blower 44 is opened while the fan motor 40 of the cross flow fan is driven at a low speed (for example, about 600 rpm), and the air that has passed through the air cleaning filter is blown out with a slight wind. I am doing so.

  The remote control switch 50 requests the microcomputer 80 (see FIG. 3) of the indoor unit 12 to output the air-conditioning state in the air-conditioned room when the button 118 is operated. The microcomputer 80 of the indoor unit 12 detects the air-conditioning state in the air-conditioned room using various sensors, and transmits the air-conditioning state from the transmission / reception circuit 90 as required.

  In addition, when the remote control switch 50 receives the air conditioning state information transmitted from the indoor unit 12, the remote control switch 50 displays the received content in the display area 106 of the display 104. Thereby, the air-conditioning state in the air-conditioned room can be accurately and easily confirmed on the remote control switch 50.

  On the other hand, as shown in FIG. 5 (B), the remote control switch 50 includes an operation switching button 128 for switching the operation mode, a ventilation switching button 130 for switching the ventilation mode, and an air volume switching. An air volume button 132 to perform, a wind direction button 134 for switching the direction of the blown wind in the vertical direction, and a wind direction button 136 for switching the direction of the blown wind in the horizontal direction are provided.

  In the air conditioner 10, the operation mode is switched to the automatic mode, the cooling mode, the heating mode, the air purification mode, and the dehumidification mode by operating the operation switching button 128, and the ventilation mode is changed by operating the ventilation switching button 130. Switch between ventilation mode, intake mode and exhaust mode. The selected mode is displayed on the display 104 (display area 106) of the remote control switch 50.

  In the remote control switch 50, the air volume of the blown air can be set automatically or in a plurality of stages by operating the air volume button 132, and the wind direction in the vertical direction is automatically adjusted by swinging the wind direction or along the vertical direction by operating the wind direction button 134. Thus, the wind direction in the left-right direction can be set to any one of a plurality of levels set automatically, swing, or along the left-right direction by operating the wind direction button 136.

  The air conditioner 10 can be set so that the air-conditioned room is in a desired air-conditioning state by operating these various buttons. When the air volume button 132 and the air direction buttons 134 and 136 are operated, the air volume and the air direction are displayed in the display area 106 of the display 104.

  The air conditioner 10 also has a timer operation function, and the remote control switch 50 is provided with an on timer button 140 and a turn off timer button 142 together with a clock button 138 used for setting the current time. The current time set by the clock button 138 is displayed in the display area 106 of the display 102. Further, the remote control switch 50 is provided with a cancel button 144 for canceling the timer setting and a daily button 146 for selecting whether to set only once or daily.

  The on timer button 140 sets the air conditioning operation start time of the air conditioner 10, and the turn-off timer button 142 sets the operation stop time of the air conditioner 10. The remote controller 50 displays the set time in the display area 106 of the display 104. In addition, the on timer button 140 and the turn off timer button 142 have functions of an up key and a down key for a set time, so that if the set time is a preset interval (for example, every 10 minutes), it is arbitrary. It can be set at the time.

  By the way, in the air conditioner 10, the microcomputer 80 provided in the indoor unit 12 has a self-diagnosis function, and can detect whether or not a failure has occurred in various components provided in the indoor unit 12. In addition, a microcomputer (not shown) provided in the outdoor unit 14 enables self-diagnosis as to whether or not a failure or the like has occurred in the components provided in the outdoor unit 14.

  Moreover, the microcomputer 80 provided in the indoor unit 12 reads the self-diagnosis result in the outdoor unit 14 by serial communication and stores it as a failure or a failure history. Note that the self-diagnosis function and the storage function can apply a conventionally known configuration, and detailed description thereof is omitted in this embodiment.

  Thereby, when a predetermined part of the casing 12A of the indoor unit 12 is opened and a switch operation is performed, the microcomputer 80 provided in the indoor unit 12 displays the service LED according to the stored failure history and failure location. Lights up or blinks.

  On the other hand, as shown in FIG. 6, the remote control switch 50 is provided with a battery box cover 150 on the back side, and the battery box cover 150 is slid to open to serve as a power source for operating the remote control switch 50. The battery box 154 containing the dry battery 152 is opened.

  Accordingly, the exhausted dry battery 152 can be replaced with the remote control switch 50.

  Further, the remote control switch 50 is provided with a service switch 158 together with the sensor switch 156 on the upper side of the battery box 154 (upper side in the drawing of FIG. 6). The sensor switch 156 can switch between detection of the room temperature during the air conditioning operation using the temperature sensor 59B (see FIG. 4) of the remote control switch 50 or the temperature sensor provided in the indoor unit 12. It has become. That is, whether or not to transmit the room temperature from the remote control switch 50 can be set by the sensor switch 156.

  In the remote control switch 50, the service switch 158 is operated to set whether to use the remote control switch 50 for normal operation of the air conditioner 10 or for maintenance.

  That is, as shown in FIG. 4, the service switch 158 is connected to the remote control unit 52, and the remote control switch 50 is set to the service mode when the service switch 158 is operated and transmitted to the indoor unit 12. A signal indicating that the service mode is set is added to the signal to be transmitted.

  The microcomputer 80 of the indoor unit 12 can recognize that the remote control switch 50 is in the service mode by this signal.

  Further, when the microcomputer 80 receives a signal indicating that the button 118 has been operated with the remote control switch 50 set in the service mode, the microcomputer 80 outputs a self-diagnosis result to the remote control switch 50 with a preset code.

  The remote control switch 50 waits to receive a signal transmitted from the indoor unit 12 by operating the button 118. At this time, when a self-diagnosis result is received from the indoor unit 12, the received self-diagnosis result is displayed in the display area 106 of the display 104 with a preset code.

  Thus, the air conditioner 10 can display the self-diagnosis result on the display 104 (display area 106) of the remote control switch 50 without touching the indoor unit 12 and performing work on the indoor unit 12.

  In the air conditioner 10 configured as described above, the air conditioner operation is started / stopped by operating the remote control switch 50. Also, when operating conditions such as wind direction and air volume, and setting conditions such as set temperature (air conditioning conditions) are changed during air conditioning operation or during air conditioning operation, based on the changed operating conditions and setting conditions, etc. Perform air conditioning operation.

  In the air conditioner 10, an automatic mode, a cooling mode, a dehumidifying mode, or a heating mode is set, so that the compressor 26 is driven to perform an air conditioning operation in the air-conditioned room. Further, in the air conditioner 10, when a ventilation mode such as an air cleaning mode, an intake mode, or an exhaust mode is set, the operation in the set ventilation mode is started.

  At this time, in the air conditioner 10, the combined operation is performed by setting the air conditioning operation using the refrigerant and the operation in the ventilation mode together.

  By the way, in the air conditioner 10, bidirectional communication is possible between the microcomputer 80 provided in the indoor unit 12 and the remote control switch 50. The remote control switch 50 is provided with a button 118 that uses this bidirectional communication. By operating the button 118, it is possible to check the air conditioning state in the air-conditioned room.

  That is, when the button 118 is operated, the remote control switch 50 requests the microcomputer 80 of the indoor unit 12 to output information on the air conditioning state.

The microcomputer 80 of the air conditioner 10 detects the humidity and the like in the air-conditioned room using various sensors. Further, when a ventilation operation function is provided, the carbon dioxide (CO ₂ ) concentration can be detected. The outdoor unit 14 of the air conditioner 10 detects the outdoor temperature (outside air temperature) where the outdoor unit 14 is installed, and this outside air temperature is input to the microcomputer 80 of the indoor unit 12 by serial communication.

  Here, when the button 118 of the remote control switch 50 is operated, the microcomputer 80 of the indoor unit 12 transmits operating information such as outside air temperature, humidity, and carbon dioxide concentration, which is information on the air conditioning state. When receiving the driving information transmitted from the indoor unit 12, the remote control switch 50 displays the driving information in the display area 106 on the display 104.

  On the other hand, in addition to the normal mode for operating the air conditioner 10, the remote control switch 50 is set with a service mode used during maintenance of the air conditioner 10. A service switch 158 appears by opening the battery box cover 150 on the back side of the remote control switch 50. When the service switch 158 is turned on, the remote control switch 50 switches to the service mode.

  The remote control switch 50 adds a signal indicating the service mode to the transmission signal by switching to the service mode.

  The microcomputer 80 of the indoor unit 12 recognizes that it has switched to the service mode by adding a signal indicating the service mode to the transmission signal of the remote control switch 50. In addition, the signal of arbitrary structures can be used for this additional signal.

  The microcomputer 80 transmits an error code based on the self-diagnosis result to the remote control switch 50 when a signal indicating the service mode is added to the signal transmitted when the button 118 is operated.

  When receiving the error code, the remote control switch 50 displays an image corresponding to the received error code in the display area 106 of the display 104.

  That is, the microcomputer 80 provided in the air conditioner 10 performs a self-diagnosis to detect a failure or abnormality of a component. When a failure or abnormality is detected, the microcomputer 80 stores the error code and stores it as an error code. It is sent on demand.

  The air conditioner 10 detects a failure or abnormality of a room temperature sensor provided in the indoor unit 12, a coil temperature sensor that detects the temperature of the heat exchanger 18, a humidity sensor, an OTP, a DC motor, or the like. In the air conditioner 10, a compressor sensor for detecting the temperature of the compressor 26 provided in the outdoor unit 12, a coil sensor for detecting the temperature of the heat exchanger 28, an outside air sensor, a current sensor, a suction sensor, an FET sensor, an HIC sensor Self-diagnosis such as abnormalities and failures.

  The microcomputer 80 stores these self-diagnosis results and transmits an error code set in accordance with the detected abnormality or failure when a request for output of the self-diagnosis results is made.

  Here, bidirectional communication between the remote control switch 50 and the microcomputer 80 will be described with reference to FIGS. 7A and 7B. 7A shows the flow of processing in the remote control unit 52 of the remote control switch 50, and FIG. 7B shows the flow of processing in the microcomputer 80 of the indoor unit 12. Further, the button 118 is effective only when the air conditioner 10 is in operation. That is, in the air conditioner 10, when the operation is stopped, the microcomputer 80 enters a standby state to save power, and the operation information can be transmitted by entering any one of the operation states.

  In the flowchart of FIG. 7A, it is confirmed in the first step 200 whether or not the button 118 has been operated. If the button 118 is operated, an affirmative determination is made in step 200 and the operation of the button 118 is performed. The process based on is started.

  At this time, first, in step 202, it is confirmed whether or not the service mode is set. If it is in the normal mode, a negative determination is made in step 202, the process proceeds to step 204, and a signal requesting driving information is transmitted. .

  Thereafter, in step 206, it is confirmed whether or not the information for the request has been received. If received, an affirmative determination is made in step 206 and the process proceeds to step 208. The received driving information is displayed in the display area 106 of the display 104. To do.

  When the service switch 158 is operated to switch to the service mode, an affirmative determination is made in step 202 and the process proceeds to step 210 to request transmission of an error code, that is, a self-diagnosis result.

  Thereafter, in step 212, it is confirmed whether or not an error code has been received. If an error code is received, an affirmative determination is made in step 212 and the process proceeds to step 214. The received error code is displayed in the display area 106 of the display 104. To be displayed.

  On the other hand, as shown in FIG. 7B, the microcomputer 80 confirms whether or not the signal transmitted from the remote control switch 50 is received based on the operation of the button 118 in the first step 220 and makes an affirmative determination. As a result, the process proceeds to step 222. In this step 222, it is confirmed whether or not the remote control switch 50 is set to the service mode. That is, it is confirmed whether or not a signal indicating the service mode is added to the received signal.

  Here, when the remote control switch 50 is not set to the service mode, a negative determination is made in step 222, the process proceeds to step 224, and driving information is transmitted.

  On the other hand, when the remote control switch 50 is set to the service mode, an affirmative determination is made in step 222, the process proceeds to step 226, and an error code is transmitted based on the stored self-diagnosis result.

  Thus, when the remote control switch 50 is set to the service mode, an error code is displayed on the display 104 (display area 106) of the remote control switch 50.

  FIG. 8 shows an example of a change in display in the display area 106 provided on the display 104 of the remote control switch 50 when the button 118 is operated. In FIG. 8, the step numbers in FIG. 7A are also shown.

  In FIG. 8, the display of the display area 106 during operation in the heating mode is shown as an example, and the remote controller 50 used for the air conditioner 10 normally displays an image 160 indicating the operation mode and the current time in the display area 106. ing.

  Here, when the button 118 is operated, the display in the display area 106 first displays an image 162 indicating that reception has started, and thereafter, in order of the images 164, 166, and 168, at predetermined time intervals. By switching, a moving image tone display is made. That is, by moving to step 206 or step 212 in the flowchart of FIG. 7A, the images 162 to 168 are displayed in order.

  Thereafter, when the signal transmitted from the microcomputer 80 cannot be received even after a predetermined time elapses, for example, when the display of the image 168 is finished (“No” in step 206 or step 212 in FIG. 7), the image 170 is displayed. Is displayed, and the image 160 which is a normal display image is returned to the display.

  On the other hand, when a signal (information) transmitted from the microcomputer 80 is received during the display of the images 162 to 168 (affirmative determination in step 206 or step 212 in FIG. 7), the received information corresponds to the received information. Display.

  Here, when the remote control switch 50 is not set to the service mode and is in the normal mode, as the operation information transmitted from the microcomputer 80, for example, an image 172 showing the outside air temperature and an image showing the humidity in the air-conditioned room. 174 etc. are displayed for each predetermined time (for example, about 3 seconds) (step 208 in FIG. 7).

  When the air conditioner 10 has a ventilation function, the operation state of the ventilation function may be continuously displayed. When the carbon dioxide concentration in the air-conditioned room is detected, the detected carbon dioxide concentration is displayed. The corresponding display may be continued.

  On the other hand, when the remote control switch 50 is set to the service mode and an error code based on the self-diagnosis result is received from the microcomputer 80 while the images 176 to 168 are being displayed (within a predetermined time), the error code corresponding to the error code is received. The image is displayed in the display area 106 of the display 104.

  FIG. 9 shows an image 176 displayed in the display area 106 as an example of error code display. In this image 176, the error code is indicated by a preset 2-digit hexadecimal number together with a character string indicating the error code. When there are a plurality of abnormalities, the corresponding error codes are sequentially displayed for a predetermined time ( (For example, several seconds).

  As described above, when the air conditioner 10 performs self-diagnosis, the self-diagnosis result can be displayed on the display 104 of the remote control switch 50, so that there is an abnormal part without touching the indoor unit 12 of the air conditioner 10. For example, the abnormal part can be recognized accurately.

  Therefore, a location necessary for maintenance or the like can be accurately identified and the work for the corresponding location can be performed smoothly, so that maintainability can be significantly improved.

  That is, in the present embodiment, the wall-mounted type air conditioner 10 in which the indoor unit 12 is attached to the wall surface of the air-conditioned room is described as an example. However, even in the wall-mounted type, the microcomputer 80 does not touch the indoor unit 12. The self-diagnosis result can be read out. Thereby, for example, when an abnormality occurs in the outdoor unit 14, the work on the outdoor unit 14 can be started without performing the work on the indoor unit 12.

  In addition, the air conditioner has a housing type in which the indoor unit is mounted concealed on the ceiling or the wall surface. With such an air conditioner, the operation until the self-diagnosis result from the indoor unit is generated in the service LED 98 or the like is not easy. It takes time and effort even for that kind of work.

  On the other hand, in the present invention, the self-diagnosis result of the air conditioner can be easily read and the self-diagnosis result can be confirmed by using the remote control switch 50 or the like.

  Further, since the remote control switch 50 for operating the air conditioner 10 is used, it is not necessary to prepare a dedicated readout jig in advance for maintenance, and the preparation work is simplified as well as the workability at the time of maintenance. Can be

  In the present embodiment described above, the service switch 158 that switches between the normal mode and the service mode is provided so as to be hidden by the battery box cover 150 of the remote control switch 50. However, the position where the service switch 158 is provided is not limited to this. Instead, for example, the battery box 154 may be provided at an arbitrary position where it is not easily operated, such as being hidden by the dry battery 152.

  In the present embodiment, the service switch 158 dedicated to switching to the service mode has been described. However, the present invention is not limited to this. For example, any two or more preset from a plurality of buttons forming the operation unit 154 are provided. Are simultaneously operated (for example, a combination of buttons that are simultaneously operated during normal operation of the air conditioner 10 such as “wind direction button 134 and wind direction button 136”, “air volume button 132 and wind direction buttons 134, 136”, etc.). The normal mode may be switched to the service mode, which eliminates the need for a special switch that is not normally operated.

  In the present embodiment, the air conditioner 10 has been described as an example. However, the present invention can be applied to an air conditioner having an arbitrary configuration that has a self-diagnosis function and is operated by a remote control switch.

  In addition, as an air conditioner to which the present invention is applied, a solar power generation apparatus may be connected, and of course, so-called hot water that performs cooling, dehumidification, and the like by a refrigeration cycle and performs heating using hot water. An air conditioner may be used.

It is a principal part perspective view which shows schematic structure of the air conditioner applied to this Embodiment. It is a schematic block diagram which shows the refrigerating cycle of an air conditioner. It is a block diagram which shows schematic structure of the control part of an indoor unit. It is a block diagram which shows schematic structure of a remote control switch. (A) And (B) is the schematic which shows an example of a remote control switch, (A) shows the state which closed the operation cover, (B) has shown the state which opened the operation cover. It is the schematic which shows the principal part of the back surface side of a remote control switch. (A) is a flowchart which shows an example of the process in a remote control switch, (B) is a flowchart which shows an example of the process in the microcomputer of an indoor unit with respect to the process of (A). It is the schematic which shows an example of the change of the display image accompanying the operation of a button. It is the schematic which shows the example of a display of the error code with a remote control switch.

Explanation of symbols

10 Air conditioner (air conditioner)
DESCRIPTION OF SYMBOLS 12 Indoor unit 14 Outdoor unit 18 Heat exchanger 26 Compressor 50 Remote control switch 52 Remote control means 54 Operation part (operation means)
56 Display section (display means)
58A transmitter 58B receiver 60 controller 80 microcomputer (communication control means, self-diagnosis means)
90 Transmission / reception circuit (communication means)
104 Display (display means)
106 Display area (display means)
118 Tell me button 158 Service switch (switching means)

Claims (3)

In accordance with the operation of the remote control switch, the air-conditioned room can be air-conditioned by a refrigeration cycle and performs self-diagnosis of parts or functions,
Communication means for enabling bidirectional communication with the remote control switch by wireless communication;
Communication control means for transmitting a self-diagnosis result when output of the self-diagnosis result is requested via the communication means;
Display means provided on the remote control switch for displaying an image corresponding to the self-diagnosis result transmitted from the communication means;
The air conditioner characterized by including. The remote control switch is
A transmission unit for transmitting a signal according to the switch operation;
A receiving unit for receiving a signal transmitted from the communication means;
A remote control unit that transmits a signal requesting output of the self-diagnosis result from the transmission unit by a predetermined switch operation and displays an image based on the self-diagnosis result received by the reception unit as an error code on the display means When,
The air conditioner according to claim 1, comprising:   The remote control switch includes switching means for switching between a normal mode for transmitting a signal for setting an operation / stop of an air conditioning operation and an air conditioning condition according to a switch operation and a service mode for requesting the output of the self-diagnosis result by a switch operation. The air conditioner according to claim 2.

Images