JP2010139158A - Outdoor unit for heat pump type air conditioner - Google Patents

Abstract

A main control circuit for an external noise in an outdoor unit of a heat pump air conditioner including a main control circuit for controlling a drive source and a refrigerant, and a communication circuit for communicating with the indoor unit or another outdoor unit. Or the outdoor unit of the heat pump type air conditioner which can improve the tolerance of a communication circuit is provided.
An outdoor unit includes a main microcomputer 71 that controls a gas engine and a refrigerant, a communication microcomputer 72 that performs communication between the outdoor unit and an indoor unit or another outdoor unit, a main microcomputer 71, and a communication microcomputer 72. The photocouplers 74 and 75 that transmit signals between the main microcomputer 71 and the communication microcomputer 72 while being electrically insulated from each other and the DC voltage obtained by AC / DC conversion of the AC commercial power supply are electrically insulated The main control power supply 66 for supplying power to the main microcomputer 71 and the communication power supply 67 for supplying power to the communication microcomputer 72 in a state where the DC voltage obtained by AC / DC conversion of the AC commercial power supply is electrically insulated are provided.
[Selection] Figure 3

Description

  The present invention relates to an outdoor unit of a heat pump type air conditioner.

  Conventionally, as a heat pump type air conditioner, for example, those described in Patent Documents 1 and 2 are known. In these air conditioners, a current loop type communication system is adopted as a countermeasure against noise (surge) for transmission and reception of digital signals between the outdoor unit and the indoor unit. A photocoupler and a plurality of resistors are arranged on the reception side and the transmission side on the communication line, respectively, and digital signals are transmitted and received by turning the photocoupler on and off, and insulation is ensured. In the current loop communication method, since communication is performed using a current signal of the current loop, for example, the current loop type communication method has a feature that the common mode noise (common mode noise) resistance is higher than that of the voltage transmission method.

On the other hand, a voltage drop occurs due to the photocoupler and line resistance of each terminal, so in the case of long distance transmission or multipoint connection with a large number of units, the current signal power source for the current loop (hereinafter also referred to as “loop power source”) It is necessary to increase the voltage. In Patent Documents 1 and 2, it is estimated that the total extension of the communication line between the outdoor unit and the indoor unit is about 100 m and a small number is assumed. In addition, since the loop power supply is a non-insulated power supply, the insulation withstand voltage of the loop power supply is very small while ensuring the insulation of the controller (communication circuit).
JP 2006-129276 A JP-A-8-271022

  By the way, in recent heat pump type air conditioners, multi-type air conditioning, increased capacity of outdoor units, support for large-scale properties, support for large-scale suburbs, etc. Long-distance correspondence that can permit the communication is required. In particular, it is possible to construct a network that connects outdoor units across the refrigerant system in order to eliminate the hassle of wiring work by dividing the communication line for each refrigerant system and to connect control equipment that controls the entire network. Required. In addition, the communication line is placed in a very severe situation in terms of electromagnetic environment as it is wired outdoors, so that more reliable communication is required.

  On the other hand, in the conventional current loop type communication system, for example, the loop power source arranged in the outdoor unit is a non-insulated power source, so that, for example, a common mode The common mode surge superimposed on the communication line due to surge or induced lightning may be lost to the loop power supply, causing problems in the controller (communication circuit) and its power supply circuit.

  In addition, if a current loop type communication system is used for multipoint connection with a large number of units, all the communication becomes unusable due to power off or failure of any one device, especially for outdoor units and indoor units individually. In a large-scale heat pump type air conditioner having a power source, communication reliability may be reduced accordingly.

  Furthermore, with long-distance transmission and multipoint connection with a large number of units, the voltage of the loop power supply becomes very high, and it is necessary to improve the breakdown voltage of the communication line.

  Furthermore, in the case of a network that connects a plurality of outdoor units, any one of the outdoor units that supply loop power must be selected.

  In addition, in the case of a heat pump type air conditioner (that is, a gas heat pump type air conditioner) that drives a compressor related to refrigerant circulation with a gas engine, the outdoor unit connects the ground of the control circuit to the housing frame because of the necessity of engine control. It is common to employ a system ground configuration that drops to the ground. On the other hand, in the indoor unit, although there is an EMC earth for preventing electromagnetic interference, a non-grounding system is basically adopted for a ground system such as a circuit board. Therefore, a high-energy surge induced and superimposed on the communication line will escape from the housing frame to the ground via the outdoor unit, and the insulation withstand voltage on the outdoor unit side may still be insufficient.

  As described above, in the configuration in which the controller of the outdoor unit also serves as communication control, ignition noise of the engine installed in the outdoor unit, inverter noise of the motors, surges entering from the commercial power supply, etc. are propagated from the controller to the communication line. There is a problem of noise that is superimposed or induced. On the other hand, since the wiring of a communication line straddles between buildings, there also exists a problem that it is easy to receive the influence of a lightning surge. That is, even if the communication method itself is balanced transmission communication, the circuit system is grounded, and therefore, it is affected including common mode noise. In addition, the communication network is susceptible to construction effects other than the above-described external noise. For example, when a misconnection with the power supply line or a ground fault of the communication line occurs, the main control circuit and the communication circuit are common circuits. At the same time, problems may occur.

  An object of the present invention is an outdoor unit of a heat pump type air conditioner that includes a main control circuit that controls a drive source and a refrigerant, and a communication circuit that performs communication between the indoor unit or another outdoor unit. An object of the present invention is to provide an outdoor unit of a heat pump type air conditioner that can improve resistance of a main control circuit or a communication circuit.

  In order to solve the above problems, the invention according to claim 1 is directed to a driving source, a compressor driven by the driving source to suck in the refrigerant and compressing and discharging the sucked refrigerant, and a refrigerant during cooling operation. Outdoor unit having an outdoor unit heat exchanger functioning as a refrigerant evaporator and functioning as a refrigerant evaporator during heating operation, provided in the indoor unit as a refrigerant evaporator during cooling operation and during heating operation A main control circuit for controlling the drive source and the refrigerant in the outdoor unit of the heat pump type air conditioner in which the refrigerant is circulated through the refrigerant circuit to the indoor unit heat exchanger functioning as a refrigerant condenser and the outdoor unit heat exchanger; A communication circuit that performs communication between the outdoor unit and the indoor unit or another outdoor unit, and the main control circuit and the communication circuit that are connected to and electrically insulated from the main control circuit and the communication circuit. A transmission circuit for transmitting signals between the communication circuits, a power supply circuit for generating a DC power supply by AC / DC conversion of an AC commercial power supply, and an electrically insulated state connected to the power supply circuit and the main control circuit A first power source for supplying power from the power circuit to the main control circuit; and a second power source connected to the power circuit and the communication circuit and electrically supplied from the power circuit to the communication circuit. The main point is that it has a power source.

  According to a second aspect of the present invention, in the outdoor unit of the heat pump air conditioner according to the first aspect, the transmission circuit includes one of the main control circuit and the communication circuit and the other on the input side and the output side. The gist of the present invention is that it is a photocoupler or an insulating transformer.

  According to each of the above configurations, a signal is transmitted between the main control circuit and the communication circuit while being electrically insulated by the transmission circuit. The main control circuit is supplied with power from the power circuit in a state of being electrically insulated by the first power source, and the communication circuit is electrically insulated by the second power source. Power is supplied from the power supply circuit. As described above, since the main control circuit and the communication circuit are independently made in a state where the power supply is electrically insulated from the power supply circuit, the main control circuit or the communication circuit is insulated against external noise. Resistance can be improved.

  The invention according to claim 3 is the outdoor unit of the heat pump type air conditioner according to claim 1 or 2, wherein the communication board on which the communication circuit is mounted, and the main control board on which the main control circuit is mounted And the transmission circuit is mounted on the communication board.

  According to this configuration, for example, an external noise such as a lightning surge that has entered the outdoor unit (communication circuit) through a communication line with the indoor unit or another outdoor unit causes dielectric breakdown in the transmission circuit (for example, a photocoupler). However, it can be dealt with by repairing or replacing the communication board on which the transmission circuit is mounted, and the number of maintenance steps can be reduced.

  In the present invention, in an outdoor unit of a heat pump air conditioner that includes a main control circuit that controls a drive source and a refrigerant, and a communication circuit that performs communication between the indoor unit or another outdoor unit, main control against external noise The outdoor unit of the heat pump type air conditioner which can improve the tolerance of a circuit or a communication circuit can be provided.

  DESCRIPTION OF EXEMPLARY EMBODIMENTS Hereinafter, an embodiment of the invention will be described with reference to the drawings.

  FIG. 1 is a circuit diagram of a refrigerant system showing a gas heat pump type air conditioner according to this embodiment. As shown in FIG. 1, the gas heat pump type air conditioner includes an outdoor unit 10 and one or a plurality of indoor units 30.

  A compressor 12 installed in the outdoor unit 10 and driven by a gas engine 11 as a drive source sucks refrigerant and compresses the sucked refrigerant, and the refrigerant is connected to a four-way valve 14 connected via a refrigerant pipe 13a. Send out. An oil separator 26 is provided in the refrigerant pipe 13a.

  The four-way valve 14 is connected to the outdoor unit heat exchanger 15 through the refrigerant pipe 13b, is connected to the sub heat exchanger 16 through the refrigerant pipe 13c, and is further connected to the on-off valve 17 through the refrigerant pipe 13d. Has been. The four-way valve 14 is connected to an accumulator 18 through a refrigerant pipe 13e, and the accumulator 18 is connected to the compressor 12 through a refrigerant pipe 13f.

  The outdoor unit heat exchanger 15 functions as a refrigerant condenser during the cooling operation and functions as a refrigerant evaporator during the heating operation, and is connected to the supercooling heat exchanger 19 via the refrigerant pipe 13g. Has been. In addition, a check valve 21 that allows the refrigerant to flow to the supercooling heat exchanger 19 side is disposed in the refrigerant pipe 13g, and a flow rate adjustment valve 22a is disposed in parallel with the check valve 21. . Further, the sub heat exchanger 16 functions as a refrigerant evaporator during heating operation, and is connected to the supercooling heat exchanger 19 via a refrigerant pipe 13h. And the flow control valve 22b is arrange | positioned at the refrigerant | coolant piping 13h. The supercooling heat exchanger 19 is connected to the on-off valve 20 via the refrigerant pipe 13i.

  An indoor unit heat exchanger 31 installed in the indoor unit 30 is connected to the on-off valve 17 through a refrigerant pipe 32a and is connected to the on-off valve 20 through a refrigerant pipe 32b. And the electronic expansion valve 33 is arrange | positioned at the refrigerant | coolant piping 32b. The indoor unit heat exchanger 31 functions as a refrigerant evaporator during the cooling operation and functions as a refrigerant condenser during the heating operation.

  The refrigerant pipes 13a to 13i, 32a, and 32b form a flow path until the refrigerant discharged from the compressor 12 is sucked into the compressor 12, and the refrigerant is supplied to the outdoor unit heat exchanger 15 and the indoor unit heat exchanger 31. The refrigerant circuit L that circulates the refrigerant is configured.

  Here, the flow of the refrigerant will be described. In FIG. 1, the refrigerant flow during the cooling operation and the heating operation is indicated by solid arrows and broken arrows.

  During the cooling operation, the refrigerant that has exited the compressor 12 passes through the oil separator 26 and the four-way valve 14 and is then guided to the outdoor unit heat exchanger 15. Here, the heat is deprived of heat by the outside air to condense and liquefy, and is further supercooled by the supercooling heat exchanger 19. After that, the refrigerant that has been decompressed by the electronic expansion valve 33 of the indoor unit 30 through the refrigerant pipe 32b takes the indoor heat in the indoor unit heat exchanger 31 and vaporizes. Thereafter, the refrigerant returns to the compressor 12 through the refrigerant pipe 32a, the four-way valve 14 and the accumulator 18.

  On the other hand, during the heating operation, the refrigerant that has exited the compressor 12 passes through the oil separator 26 and the four-way valve 14 and is then guided to the indoor unit heat exchanger 31 (indoor unit 30). Here, the refrigerant releases heat into the room and condenses and liquefies. Thereafter, the refrigerant depressurized by the electronic expansion valve 33 of the indoor unit 30 passes through the refrigerant pipe 32b, is depressurized by the flow rate adjusting valves 22a and 22b of the outdoor unit 10, and the refrigerant that has passed through the flow rate adjusting valve 22a is the outdoor unit. The refrigerant that has passed through the flow rate adjusting valve 22b is guided to the heat exchanger 15 to the sub heat exchanger 16, respectively. The refrigerant absorbs and vaporizes heat from the outside air in the outdoor unit heat exchanger 15, and absorbs and vaporizes heat from the engine exhaust heat in the sub heat exchanger 16. Thereafter, the refrigerant passing through the outdoor unit heat exchanger 15 and passing through the four-way valve 14 joins with the refrigerant passing through the sub heat exchanger 16, and returns to the compressor 12 via the accumulator 18.

  As shown in FIG. 1, a control unit 40 is mounted on the outdoor unit 10. The control unit 40 includes a power supply board 41, and a main control board 42 and a communication board 43 that are individually supplied with power through the power supply board 41. A digital signal as a signal is transmitted (transmitted / received) between the main control board 42 and the communication board 43.

  The main control board 42 drives and controls the compressor 12, drives and controls a pair of fans 44 and 45 that blow outside air to the outdoor unit heat exchanger 15, and further circulates the coolant to the gas engine 11. The drive of the pump 46 is controlled. The fans 44 and 45 and the coolant pump 46 constitute an electric auxiliary machine (auxiliary device) of the outdoor unit 10. Alternatively, the main control board 42 drives and controls an igniter power supply 47 (see FIG. 2) related to ignition of the gas engine 11 and controls a gas electromagnetic valve 48 (see FIG. 2) related to fuel gas supply. On the other hand, the communication board 43 performs communication between the outdoor unit 10 and the indoor unit 30 or another outdoor unit across the refrigerant system according to a predetermined transmission method (for example, serial baseband transmission).

  Here, the main control board 42 acquires information such as refrigerant (temperature information) in the outdoor unit 10 through various sensors provided in the outdoor unit 10. Further, the main control board 42 transmits a request signal to the indoor unit 30 or other outdoor units through the communication board 43, and information such as refrigerant (temperature information, etc.) acquired by various sensors disposed in the indoor unit 30 or the like. ) With a digital signal, and these are received via the communication board 43. The main control board 42 drives and controls the compressor 12 and the like disposed in the outdoor unit 10 based on these pieces of information. Alternatively, the main control board 42 transmits a command signal to the indoor unit 30 or another outdoor unit through the communication board 43, and drives and controls the electronic expansion valve 33 and the like disposed in the indoor unit 30 and the like.

  Next, the electrical configuration of the control unit 40 will be described. FIG. 2 is an electric circuit diagram showing the control unit 40. As shown in the figure, the control unit 40 includes a DC brushless motor drive board (a DC electrical power source AC (for example, 200V)) that is electrically connected via three AC electric wires 51a, 51b, 51c. Hereinafter, it is referred to as “DCBL substrate 52”. Note that a breaker 53 and an EMC substrate 54 constituting a noise filter are electrically connected to the AC wires 51a to 51c.

  The DCBL substrate 52 is electrically connected to the AC electric wires 51a to 51c in the three-phase diode bridge 55. The three-phase diode bridge 55 has six diodes and rectifies the AC voltage of the AC commercial power supply AC. The three-phase diode bridge 55 is electrically connected to an inverter 57 via a positive DC wire 56a and a negative DC wire 56b, respectively, and both DC wires 56a and 56b are connected to a smoothing electrolytic capacitor 58. Is electrically connected. Therefore, the inverter 57 is supplied with the DC voltage generated by the smoothing by the electrolytic capacitor 58 (that is, the DC voltage (DC power source) AC / DC converted by the three-phase diode bridge 55 and the electrolytic capacitor 58). Yes. The three-phase diode bridge 55 and the electrolytic capacitor 58 constitute a power supply circuit.

  The inverter 57 has six switching elements, and is electrically connected to DC brushless motors 44a, 45a, and 46a that are synchronous motors via three AC electric wires 60a, 60b, and 60c. These DC brushless motors 44 a, 45 a, 46 a constitute a drive source for the fans 44, 45 and the coolant pump 46, and change the rotational speed by being PWM driven by switching control of the inverter 57. In FIG. 2, the DC brushless motors 44 a to 46 a and the inverter 57 are drawn by one for convenience, but three DC brushless motors 44 a to 46 a and the coolant pump 46 are provided. The inverter 57 is subjected to switching control by a control circuit 59 provided on the DCBL substrate 52.

  The power supply board 41 is electrically connected to the DC electric wires 56a and 56b at connection points P and N between the inverter 57 and the electrolytic capacitor 58, and the positive potential V + of the DC electric wire 56a and the negative side of the DC electric wire 56b. Potential V− is input. The power supply board 41 includes a plurality of flyback power supplies. The DC voltage obtained by DC / DC conversion of the DC voltage between the connection points P and N is supplied to the main control board 42, the communication board 43 and the control circuit 59. Supply individually. Alternatively, the power supply board 41 individually supplies a DC voltage obtained by DC / DC conversion of the DC voltage between the connection points P and N to the igniter power supply 47 and the gas solenoid valve 48 based on a command signal from the main control board 42. To do.

  The DC electric wires 56a and 56b are electrically connected to the power generation converter 61 at the connection points P and N. The power generation converter 61 is supplied with a DC voltage obtained by DC / DC conversion of the DC voltage between the connection points P and N by the power supply substrate 41. This power generation converter 61 has six switching elements like the inverter 57, and is connected to a generator (not shown) composed of a synchronous motor driven by the gas engine 11 and three AC wires. Electrically connected. The power generation converter 61 is driven and controlled by the main control board 42 or an appropriate control circuit, and regeneratively controls the generator to generate a DC voltage (DC power), and the DC voltage is applied to both connection points P and N. Regenerative output. The DC voltage generated by the power generation is set to a voltage (for example, 320 V) obtained by raising the DC voltage (for example, 312 V) between the connection points P and N generated from the AC commercial power supply AC (200 V). The DC voltage regenerated and output at both connection points P and N is charged in the charging device. The electric power charged in the charging device is used for driving a starter motor related to the start of the gas engine 11, for example.

  Next, the electrical configuration of the power supply board 41, the main control board 42, and the communication board 43 will be further described with reference to FIG. As shown in the figure, the power supply board 41 includes a main control power supply 66 as a flyback first power supply and a communication power supply 67 as a second power supply.

  The main control power supply 66 has a high-frequency transformer T1. One end of the primary coil L11 of the high-frequency transformer T1 is electrically connected to the connection point P, and the other end of the primary coil L11 is electrically connected to the drain of the transistor Q1 formed of an N-channel MOSFET. The source of the transistor Q1 is electrically connected to the connection point N. In addition, an oscillation unit OSC1 including a self-excited oscillation unit or an oscillator is electrically connected to the gate of the transistor Q1, for example. The transistor Q1 performs switching (on / off) operation with a duty ratio corresponding to the signal frequency generated by the oscillation unit OSC1. On the other hand, one end of the secondary coil L12 of the high-frequency transformer T1 is electrically connected to the anode of the diode D1. The other end of the secondary coil L12 is electrically connected to GND1, and the cathode of the diode D1 is electrically connected to the high voltage side terminal VH1. The high voltage side terminals VH1 and GND1 are electrically connected via a smoothing electrolytic capacitor C1. The main control power supply 66 supplies a DC voltage V1 (for example, 12V) obtained by stepping down a DC voltage between the connection points P and N in accordance with a signal frequency (duty ratio) of the oscillating unit OSC1 between the high voltage side terminals VH1 and GND1. Output to. Needless to say, the DC voltage V1 is generated in a state of being electrically insulated from the connection points P and N (AC commercial power supply AC).

  Similarly, the communication power supply 67 has a high-frequency transformer T2. One end of the primary coil L21 of the high-frequency transformer T2 is electrically connected to the connection point P, and the other end of the primary coil L21 is electrically connected to the drain of the transistor Q2 made of an N-channel MOSFET. The source of the transistor Q2 is electrically connected to the connection point N. The gate of the transistor Q2 is electrically connected to an oscillating unit OSC2 made of, for example, a self-excited oscillating unit or an oscillator. The transistor Q2 performs a switching (on / off) operation at a duty ratio corresponding to the signal frequency generated by the oscillation unit OSC2. On the other hand, one end of the secondary coil L22 of the high-frequency transformer T2 is electrically connected to the anode of the diode D2. The other end of the secondary coil L22 is electrically connected to the ground GND2 of the outdoor unit 10 (housing frame) electrically insulated from the GND1, and the cathode of the diode D2 is connected to the high voltage side terminal VH1. Is electrically connected to the high voltage side terminal VH2 which is electrically insulated from the terminal. The high voltage side terminal VH2 and the ground GND2 are electrically connected via a smoothing electrolytic capacitor C2. The communication power supply 67 is configured to apply a DC voltage V2 (for example, 16V) obtained by stepping down a DC voltage between the connection points P and N according to a signal frequency (duty ratio) of the oscillation unit OSC2 between the high-voltage side terminal VH2 and the ground GND2. Output to. Needless to say, the DC voltage V2 is generated in a state of being electrically insulated from the connection points P and N (AC commercial power supply AC).

  On the main control board 42, a main microcomputer 71 is mounted as a main control circuit for controlling various controls of the gas engine 11 and the refrigerant. The main microcomputer 71 is electrically connected to the high voltage side terminals VH1 and GND1 of the main control power supply 66, and is supplied with the DC voltage V1.

  The communication board 43 is mounted with a communication microcomputer 72 as a communication circuit that controls various types of communication described above, and is driven and controlled by the communication microcomputer 72 to communicate with the indoor unit 30 (or other outdoor unit). A communication driver 73 that performs signal transmission between them is mounted. The communication microcomputer 72 is electrically connected to the high voltage side terminal VH2 and the ground GND2 of the communication power supply 67, and is supplied with the DC voltage V2.

  In addition, photocouplers 74 and 75 as a pair of transmission circuits are mounted on the communication board 43. In one photocoupler 74, the collector of the NPN phototransistor 74a constituting the light receiving element is electrically connected to the main microcomputer 71, and the collector is connected to the high voltage side terminal VH1 via the resistor R11. Electrically connected. The emitter of the phototransistor 74a is electrically connected to the GND1. On the other hand, in the photocoupler 74, the anode of the light emitting diode 74b is electrically connected to the high voltage side terminal VH2 via the resistor R12, and the cathode of the light emitting diode 74b is electrically connected to the communication microcomputer 72. . Accordingly, the light emitting diode 74b emits light when the cathode potential is switched by the digital signal transmitted from the communication microcomputer 72. The light emitted from the light emitting diode 74b generates a current in the phototransistor 74a, thereby switching the collector potential. The main microcomputer 71 turns on or off the light-emitting diode 74b based on this potential change, that is, receives a digital signal transmitted from the communication microcomputer 72. As described above, the transmission of the digital signal from the communication microcomputer 72 to the main microcomputer 71 is performed by optical communication via the photocoupler 74 in an electrically insulated state.

  Similarly, in the other photocoupler 75, the collector of the NPN type phototransistor 75a constituting the light receiving element is electrically connected to the communication microcomputer 72, and the collector is connected to the high voltage side terminal VH2 via the resistor R21. Is electrically connected. The emitter of the phototransistor 75a is electrically connected to the ground GND2. On the other hand, in the photocoupler 75, the anode of the light emitting diode 75b is electrically connected to the high voltage side terminal VH1 via the resistor R22, and the cathode of the light emitting diode 75b is electrically connected to the main microcomputer 71. . Therefore, the light emitting diode 75b emits light when the potential of the cathode is switched by the digital signal transmitted from the main microcomputer 71. The light emitted from the light emitting diode 75b causes the phototransistor 75a to generate a current, thereby switching the collector potential. The communication microcomputer 72 turns on or off the light emitting diode 75b based on the switching of the potential, that is, receives the digital signal transmitted from the main microcomputer 71. As described above, transmission of the digital signal from the main microcomputer 71 to the communication microcomputer 72 is performed by optical communication via the photocoupler 75 in an electrically insulated state.

  As described above, the main microcomputer 71 and the communication microcomputer 72 are supplied with the independent DC voltages V1 and V2 that are electrically insulated from the connection points P and N (AC commercial power supply AC), respectively. The digital signal is also transmitted between the communication controller 71 and the communication microcomputer 72 through the photocouplers 74 and 75 in an electrically insulated state.

  As described above in detail, according to the present embodiment, the following effects can be obtained.

  (1) In this embodiment, a digital signal is transmitted between the main microcomputer 71 and the communication microcomputer 72 while being electrically insulated by the photocouplers 74 and 75. The main microcomputer 71 is supplied with the DC voltage V <b> 1 while being electrically insulated from the connection points P and N (AC commercial power supply AC) by the main control power supply 66. The communication microcomputer 72 is supplied with a DC voltage V2 in a state of being electrically insulated from the connection points P and N (AC commercial power supply AC) by a communication power supply 67. As described above, the main microcomputer 71 and the communication microcomputer 72 are independently supplied with their respective power supplies electrically insulated from the connection points P and N. Therefore, for example, a lightning surge entering from the AC commercial power supply AC, The insulation resistance (noise resistance) of the communication microcomputer 72 against external noise such as a power supply surge can be improved.

  Further, since each ground (GND1 or ground GND2) of the main microcomputer 71 and the communication microcomputer 72 is separated, for example, ignition noise and DC of the gas engine 11 entering the main microcomputer 71 (main control board 42) through the power supply line, for example. It is possible to reduce the influence of inverter noise such as the brushless motors 44a to 46a on the communication microcomputer 72 (communication board 43, communication line). Since common mode noise on the communication line can be suppressed, more stable communication can be realized.

  (2) In the present embodiment, the photocouplers 74 and 75 are mounted on the communication board 43. Accordingly, the photocoupler 74, for example, due to external noise such as lightning surge that has entered the outdoor unit 10 (communication microcomputer 72) through the communication line with the indoor unit 30 or another outdoor unit, or a ground fault or erroneous connection of the communication line. Even if dielectric breakdown occurs in 75, it can be dealt with by repairing or replacing the communication board 43 on which the photocouplers 74 and 75 are mounted, and the number of maintenance steps can be reduced.

  (3) In this embodiment, the communication system of the outdoor unit 10 is preferably insulated by the photocouplers 74 and 75, so that the insulation resistance of the entire communication network can be improved and common mode noise is cut off. At the same time, it is possible to suppress the occurrence of malfunction or failure of communication. In addition, even if a ground fault or erroneous connection of the communication line occurs, the possibility that the main microcomputer 71 and the communication microcomputer 72 will fail at the same time can be reduced.

  (4) In this embodiment, it is possible to prevent the entire network from becoming inoperable due to the power-off or failure of the indoor unit 30 or other outdoor units.

  In addition, you may change the said embodiment as follows.

  In the embodiment, the light receiving elements of the photocouplers 74 and 75 may be thyristors or triacs.

  In the embodiment, an insulating transformer may be employed instead of the photocouplers 74 and 75 as the transmission circuit.

  In the above-described embodiment, the target of drive control by the main microcomputer 71 (main control board 42) may be, for example, a blower fan motor or a wind direction changing motor installed in the indoor unit 30.

  In the embodiment, the generator and the power generation converter 61 related to the regeneration control may be omitted.

  In the embodiment, the AC commercial power AC may be a single phase.

  -You may apply this invention to the air conditioning apparatus of an electric heat pump or a kerosene heat pump.

The circuit diagram which shows the refrigerant | coolant system | strain of one Embodiment of this invention. The circuit diagram which shows the electric system of the embodiment. The circuit diagram which shows the electric system of the embodiment.

Explanation of symbols

  L ... Refrigerant circuit, AC ... AC commercial power supply, 10 ... Outdoor unit, 11 ... Gas engine (drive source), 12 ... Compressor, 15 ... Outdoor unit heat exchanger, 30 ... Indoor unit, 31 ... Indoor unit heat exchanger, 42 ... main control board, 43 ... communication board, 55 ... three-phase diode bridge (power supply circuit), 58 ... electrolytic capacitor (power supply circuit), 66 ... main control power supply (first power supply), 67 ... communication power supply (first) 2 power supplies), 71 ... main microcomputer (main control circuit), 72 ... communication microcomputer (communication circuit), 74, 75 ... photocoupler (transmission circuit).

Claims (3)

A drive source, a compressor driven by the drive source to suck in refrigerant and compress and discharge the sucked refrigerant, and an outdoor functioning as a refrigerant condenser during cooling operation and functioning as a refrigerant evaporator during heating operation An outdoor unit having an outdoor heat exchanger, which is provided in the indoor unit and functions as a refrigerant evaporator during cooling operation and functions as a refrigerant condenser during heating operation, and the outdoor unit heat exchange In the outdoor unit of the heat pump air conditioner in which the refrigerant is circulated through the refrigerant circuit in the chamber,
A main control circuit for controlling the drive source and the refrigerant;
A communication circuit for performing communication between the outdoor unit and the indoor unit or another outdoor unit;
A transmission circuit connected to the main control circuit and the communication circuit and transmitting a signal between the main control circuit and the communication circuit in an electrically insulated state;
A power supply circuit that generates AC power by AC / DC conversion of AC commercial power;
A first power supply connected to the power supply circuit and the main control circuit and electrically supplied from the power supply circuit to the main control circuit in an electrically insulated state;
An outdoor unit for a heat pump air conditioner, comprising: a second power source connected to the power supply circuit and the communication circuit and supplying power from the power supply circuit to the communication circuit in an electrically insulated state . In the outdoor unit of the heat pump type air conditioner according to claim 1,
The outdoor unit of a heat pump type air conditioner, wherein the transmission circuit is a photocoupler or an insulating transformer in which either one of the main control circuit and the communication circuit and the other are an input side and an output side. In the outdoor unit of the heat pump type air conditioner according to claim 1 or 2,
A communication board on which the communication circuit is mounted;
A main control board on which the main control circuit is mounted,
The outdoor unit of a heat pump type air conditioner, wherein the transmission circuit is mounted on the communication board.

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