JPH0154621B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION <Technical Field> The present invention relates to a control circuit for an air conditioner having a refrigerant compression cycle, and particularly to a control circuit for a variable capacity air conditioner controlled by an inverter.

<Prior art> A refrigerant compression cycle is provided in which an electric compressor, an outdoor heat exchanger, a pressure reducer, and an indoor heat exchanger are sequentially connected, and each of the outdoor heat exchanger and the indoor heat exchanger is provided with a blower. In air conditioners, there is an inverter control method that controls the frequency and voltage of the power supply to the electric compressor. It is. However, in an air conditioner that adopts this type of control method, a control section with a built-in microcomputer is provided on each of the indoor and outdoor sides, and each control section controls the indoor unit and the outdoor unit. There is. However, if a microcomputer is exposed to noise such as electrostatic noise, lightning surge, broadcast radio waves, spark from a car's spark plug, or spark from a welding machine, the microcomputer may go out of control. If a runaway phenomenon occurs in the outdoor control section, the outdoor unit becomes uncontrollable and cannot be stopped.

<Purpose> In view of the above-mentioned problems, the present invention has been developed to provide a system for preventing control even when an abnormality occurs in the outdoor control section and the control becomes uncontrollable.
The object of the present invention is to provide a control circuit that can reliably stop an outdoor unit by turning off the power using an indoor control section.

<Example> The present invention will be described in detail below after an overview of the control circuit of the illustrated example will be explained. In FIG. 1, 1 is a compressor, 2 is a compressor motor for driving this compressor 1, and these constitute an electric compressor. 3 is an outdoor heat exchanger, 4 is a pressure reducer such as a capillary tube, 5 is an indoor heat exchanger,
These are connected to the compressor 1 in a closed circuit to form a refrigerant compression cycle. 6 is an outdoor fan provided for the outdoor heat exchanger 3, and 7 is an indoor fan provided for the indoor heat exchanger 5. 8
is a general one-chip microcomputer (hereinafter referred to as microcomputer) that controls the outdoor fan 6. Reference numeral 9 denotes a microcomputer (hereinafter referred to as microcomputer) installed on the indoor unit side, which also controls the inverter control circuits of the indoor and outdoor units. The microcomputer 8 has input terminals IN1 to IN3 and output ports OUT1 to OUT5, and also has an internal program ROM, data RAM, and ALU.
It is driven by a reference clock oscillator 10.
11 is a thermistor for detecting outside temperature, 12 is A/D
A converter converts the temperature detected by the thermistor 11 into a digital value and sends it to the input port of the microcomputer 8.
Input to IN1. 13 is a thermistor for detecting the temperature of the outdoor heat exchanger, and 14 is an A/D converter, which converts the temperature detected by the thermistor 13 into a digital value and inputs it to the input port IN2 of the microcomputer 8.
15 is an indoor control section, and the microcomputer 9 has input ports INA~INB and output ports OUTA~
OUTC, internal ROM, RAM, ALU, and reference clock oscillator. 16 is a thermistor for detecting room temperature, and 17 is an A/D converter, which converts the temperature detected by the thermistor 16 into a digital value and inputs it to the input port INA of the microcomputer 9. 18 is a variable resistor for setting the room temperature, and 19 is an A/D converter that converts the room temperature set by the variable resistor 18 into a digital value and connects it to the input port of the microcomputer 9.
Enter into INB. Microcomputer 9 output port
OUTA controls the large current main switch 20 on the indoor unit side, and the output port OUTB outputs operation commands, frequency designation, etc. signals to the input port IN3 of the microcomputer 8 using a serial signal, and the output port outputs signals such as operation commands and frequency designations to the input port IN3 of the microcomputer 8. Control 8. Also, the output port OUT1 of the microcomputer 8 on the outdoor unit side is connected to the signal amplification circuit 2.
5 controls the main switch 21 for large current on the outdoor unit side, output ports OUT2 to OUT4 drive the inverter unit 23 via the signal amplification circuit 22, and output port OUT5 controls the outdoor fan 6. do. Note that the main switches 20 and 21 are connected in series. The indoor fan 7 is controlled by the output port OUTC of the microcomputer 9. Inverter section 23
has transistors Tr1 to Tr6, and this inverter section 23 constitutes the main part of the outdoor control section together with the microcomputer 8 and the like.

Next, the general operation will be explained. First, when an AC power source is connected to the power terminals 24 and 24' to drive the indoor control section 15, the output port of the microcomputer 9
Main switch 20 on the indoor unit side is turned on from OUTA
However, voltage is applied to the main switch 21 on the outdoor unit side. The main switch 21 receives a signal from the output port OUTB of the microcomputer 9 at the input port IN3 of the microcomputer 8, and if there is no problem with the conditions of the outdoor unit, outputs a signal from the output port OUT1, and sends the signal to the main switch 21 via the signal amplification circuit 25. Turn on.
After that, it passes through the power factor correction reactor L1 and then the rectifier D1.
~D4, the DC voltage is smoothed by the smoothing capacitor C1, and the DC voltage is supplied to the inverter unit 23. The resistor R1 is a high resistance discharge resistor. In the inverter unit 23 to which DC voltage is applied, the signals output from the output ports OUT2 to OUT4 of the microcomputer 8 are transmitted to the transistors via the signal amplification circuit 22.
Sends a signal to the bases of Tr1 to Tr6. This signal is so-called unequal pulse width modulation (unequal PWM), and when the transistors Tr1 to Tr6 are switched in order, a three-phase alternating current is generated at the output of the inverter section 23, which drives the compressor motor 2. Can be done. When the compressor electric motor 2 operates, the compressor 1 discharges refrigerant from the discharge port on the 1A side, and after being cooled and condensed in the outdoor heat exchanger 3 by the air blown by the outdoor fan 6, the pressure is reduced in the pressure reducer 4. The air is evaporated in the indoor heat exchanger 5 to perform a cooling effect, and the indoor fan 7 blows air to cool the indoor area. 1B becomes a suction port, and the refrigerant is compressed again by the compressor. When the air conditioner is operating normally, the stop mode is activated by sending a stop signal from the output port OUTB of the microcomputer 9 to the input port IN3 of the microcomputer 8 using a serial signal. 8 turns off the main switch 21 from the output port OUT1, and then sequentially outputs a signal to stop the outdoor fan 6 from the output port OUT5,
When the signals from output ports OUT2 to OUT4 are stopped and the operation mode of the outdoor unit is completely completed, the main switch 2 is turned off by the output port OUTA of the microcomputer 9.
0 and turn off all power supply to the outdoor unit.
I try to turn it off. However, microcontroller 8
If the nozzle inside is mixed in, there is a possibility that the microcomputer 8 will run out of control due to the noise.
In such a case, even if a stop signal is sent from the microcomputer 9 on the indoor side, the microcomputer 8 will not accept it, and therefore,
In the past, the outdoor unit would become uncontrollable and could not be stopped, but in the embodiment of the present invention, a main switch 20 is provided under the control of the microcomputer 9 on the indoor side, and this main switch 20 is used to switch the outdoor unit If it is connected in series with the main switch 21 on the side, it is possible to stop the outdoor unit even on the indoor side. In other words,
When the main switch 20 is turned off from the output port OUTA of the microcomputer 9, the power supply to the outdoor unit is cut off, making it possible to safely and reliably stop the outdoor unit. Furthermore, if the main switch 20 is turned off once and then turned on again, the microcomputer 8 on the outdoor side is reset from the runaway state and returns to normal operation.

Fig. 2 shows a flowchart of the microcomputer 9 on the indoor unit side, and Fig. 3 shows a flowchart of the microcomputer 8 on the outdoor unit side.
Explain the operation. The microcomputer 9 determines whether or not the machine is in operation in step S1, turns off the main switch 20 when the machine is stopped, and performs processing in accordance with the stop mode in step S2. Also, when the mode is set to operation, turn on the main switch 20 and proceed to step S3.
After performing processing in accordance with the operating mode, the operating information is transferred to the microcomputer 8 in the form of a serial signal in step S4. On the other hand, the microcomputer 8 is supplied with power and initialized when the main switch 20 is turned on, and then processes the reception of the serial signal from the microcomputer 9 in step S5, and performs various processes in the operation mode in step S6. is programmed to. Next, when the microcomputer 9 on the indoor unit side enters the stop mode, it is determined in step S7, the stop information is transferred to the microcomputer 8 by a serial signal in step S8, and then the main switch 20
Turn off. Upon receiving the stop information, the microcomputer 8 makes a decision in step S9 and immediately proceeds to step S10.
The main switch 21 is turned off as in step S11, and the capacitor C1 is discharged, and the operation is stopped.

Here, if the microcomputer 8 on the outdoor unit side causes a runaway phenomenon due to noise such as static electricity or lightning surge, it becomes unable to receive and process the stop information sent from the microcomputer 9 on the indoor unit side [step S5], and this microcomputer 8, the stop processing [step S10], the discharge processing [step S11], etc. are no longer performed. However, when the microcomputer 9 turns off the main switch 20 through step S2, all power is no longer supplied to the outdoor unit, thereby completely stopping the outdoor unit. Furthermore, when the power is turned on again for operation, the microcomputer 8 on the outdoor unit side is always initialized, so normal operation can be resumed. In addition, it is possible to prevent the outdoor unit from operating on its own due to lightning surges, etc.

<Effects> As is clear from the above description, the present invention provides a control circuit for an air conditioner that includes an indoor control section that controls an indoor unit and an outdoor control section that controls an outdoor unit that has an electric compressor. In the outdoor side control unit, an inverter unit that controls the frequency and voltage of a three-phase power supply to the electric compressor, and an outdoor side microcomputer that outputs a control signal to the inverter unit are provided, and the indoor side The control section is provided with an indoor microcomputer that outputs a command signal to the outdoor microcomputer, and an indoor unit main switch for large current that is controlled on and off by the indoor microcomputer. The side main switch is connected to supply power to the electric compressor, inverter section, and outdoor side microcomputer on the outdoor unit side through the indoor unit side main switch, and is connected to the indoor side microcomputer and to the outdoor side microcomputer in the stop mode. The device is equipped with a stop means that outputs a stop signal and also outputs a signal to turn off the main switch on the indoor unit side, so that even when an abnormality such as runaway occurs in the outdoor microcomputer, the indoor microcomputer turns off the main switch on the indoor unit side. It is possible to turn off the power supply to the outdoor unit.

Therefore, according to the present invention, the indoor unit side main switch is turned off by the indoor side control section when an abnormality occurs in the outdoor side control section. In such cases, the power supply to the outdoor unit can be cut off by turning off the main switch on the indoor unit side, and the outdoor unit can be reliably stopped, and the indoor microcomputer can be used to prevent the outdoor microcomputer from running out of control. It is possible to return to normal state,
In other words, it is possible to control the stoppage of the outdoor unit by the indoor control section, which is an excellent effect.

[Brief explanation of drawings]

The drawings illustrate one embodiment of the present invention, with FIG. 1 being a control circuit diagram and FIGS. 2 and 3 being flowcharts. 1: Compressor, 2: Compressor motor, 3: Outdoor heat exchanger, 4: Pressure reducer, 5: Indoor heat exchanger,
6: Outdoor fan, 7: Indoor fan, 8: One-chip microcomputer, 9: Microcomputer, 15: Indoor controller, 20: Main switch on the indoor unit side, 21: Main switch on the outdoor unit side, 23 : Inverter section.

Claims (1)

[Claims] 1. In a control circuit for an air conditioner that includes an indoor control section that controls an indoor unit and an outdoor control section that controls an outdoor unit that has an electric compressor, the outdoor control section has a control section that controls the electric compressor. an inverter unit that controls the frequency and voltage of a three-phase power supply, and an outdoor microcomputer that outputs a control signal to the inverter unit, and outputs a command signal to the indoor control unit and the outdoor microcomputer. and an indoor unit-side main switch for large current that is controlled on and off by the indoor microcomputer,
The indoor unit side main switch is connected to supply power to the outdoor unit side electric compressor, inverter section, and outdoor side microcomputer through the indoor unit side main switch. A stop means is provided that outputs a stop signal to the microcomputer and also outputs a signal to turn off the main switch on the indoor unit side, so that even if an abnormality such as runaway occurs in the outdoor microcomputer, the indoor microcomputer will stop the indoor unit. A control circuit for an air conditioner, characterized in that it is possible to cut off power supply to an outdoor unit by turning off a side main switch.