JPS6314032A - Control device for air conditioner - Google Patents

Abstract

PURPOSE:To make it possible to raise or lower or correct automatically the operation temperature of a cold blast prevention means by changing to control the ON/OFF temperatures of the cold blast prevention means of a fan motor in a room according to the outdoor temperature detected by an outdoor temperature sensor. CONSTITUTION:In a air conditioner which has fan motors 5 and 9 which send forced blast respectively to a coolant cycle and heat exchangers which constitute the coolant cycle in a room and out side of the room, cold blast prevention means 6A and 6B turn ON/OFF a fan motor 5 in the room according to the temperature of the heat exchanger in the room. Further, a control means 22 changes and controls the ON/OFF temperatures of the above-mentioned cold blast prevention means according to the outdoor temperature that is detected by a temperature sensor 27 for detecting outdoor temperature. As a result, it is made possible to raise, lower or correct automatically the operation temperature of the cold blast prevention means, and even if the blow-off temperature is low because of a low temperature day or in midnight, it is possible to run continuously the fan motor in the room.

Description

[Detailed description of the invention]

[Industrial Application Field] The present invention relates to a control device for an air conditioner, and particularly to a control device for an indoor fan motor for preventing cold air. [Prior Art] FIG. 3 is a block diagram of a conventional control system for preventing cold air in an air conditioner, as disclosed in, for example, Japanese Utility Model Publication No. 54-153440. In the figure, 1 is an indoor unit of the air conditioner, and 2 is an outdoor unit of the air conditioner. The indoor unit 2 includes a room temperature thermoswitch 3 having a cooling side contact 3a and a heating side contact 3b, a switch 4A,
4B and 4C, an indoor fan motor 5 connected to a commercial power source 7 via the switches 4A and 4C of the air conditioning selector 4 and the room temperature thermoswitch 3, and one end of the indoor fan motor 5. A cold air prevention thermoswitch 6 is connected between the heating side contacts dCb of the switch 4. In addition, in the air conditioning/heating selector switch 4, the contacts 4Aa, 4Ba, and 4Ca shown by white circles of each of the switches 4A to 4C are contacts on the cooling side,
Each contact point 4Ab is also indicated by a black circle. 4Bb and 4Cb are contacts on the heating side. The outdoor unit 2 also includes a compressor motor 8 and an outdoor fan motor 9 connected in parallel to a commercial power source 7 via the room temperature thermoswitch 3 and the switch 4A of the air conditioning/heating changeover switch 4, and the room temperature thermoswitch 3 and the air conditioning/heating switch 4. The solenoid pulp IO is connected to the commercial power source 7 via the switch 4B of the changeover switch 4. Next, the operation will be explained. When each of the switches 4A to 4C of the air conditioning/heating changeover switch 4 is switched to the heating side, the indoor fan motor 5 is connected to the power source 7 through the cold air prevention thermoswitch 6, the switches 4C and 4A, and the room temperature thermoswitch 3. Here, when the room temperature becomes low and the thermoswitch 3 switches from the contact 3a to the contact 3b side,
Electric power is supplied from a power source 7 to a compressor motor 8, a fan motor 9, and a solenoid valve 10 of the outdoor unit 2. As a result, the compressor and fan are driven, and the refrigerant cycle (not shown) enters the heating operation mode. Then, by driving the indoor fan motor 5,
Since the air in the room is circulated, by placing an indoor heat exchanger in this air path, warm air will be blown into the room. By the way, the temperature of the indoor heat exchanger does not rise immediately after the compressor is started. At this time, when the indoor fan motor is operated, cold air is blown out, which is not pleasant to the user's experience. To prevent this, a cold air prevention thermoswitch 6 is connected to the heating operation side circuit of the indoor fan motor 5. The temperature sensing part of this thermoswitch 6 is attached to the pipes of the indoor heat exchanger, etc., and when the temperature exceeds a certain level, the thermoswitch 6 closes. Therefore, the fan motor 5 is not energized until the heat exchanger is sufficiently warmed, and when the heat exchanger is sufficiently warmed, the fan motor 5 is energized and starts blowing out hot air. [Problems to be Solved by the Invention] In the conventional device, the temperature at which the cold air prevention thermoswitch 6 opens and closes is selected to be as low as possible, at which a person will not feel cold even when exposed to the blown air. However, if the outside temperature is low, you will feel warm even at an even lower temperature, and conversely, if the outside temperature is high, you will feel cold unless it is higher. Furthermore, in a variable capacity air conditioner, if the room temperature is set lower than the cold air prevention thermoswitch, the capacity will be throttled after a long period of time, and the heat exchanger will become cold and the operation will not be continuous but intermittent. There was a problem with this. This invention was made in order to solve the above-mentioned problems, and it is possible to automatically adjust the operating temperature of the cold air prevention thermoswitch to raise or lower it. An object of the present invention is to provide a control device for an air conditioner that enables continuous operation of an indoor fan motor. [Means for Solving the Problems] The air conditioner control device according to the present invention includes a cold air prevention means that turns on and off an indoor fan motor according to the temperature of a heat exchanger of an indoor unit, and a means that detects outside air temperature. The indoor fan motor has a detector and is provided with a control means for varying the cold air prevention temperature of the indoor fan motor in accordance with the outside air temperature detected by the outside air temperature sensor. [Operation] In this invention, the control means detects a change in outside air temperature, and when the outside air temperature falls below a set value, the control means lowers the cold air prevention temperature operating point (on/off temperature) of the indoor fan motor. Control changes to. This allows the indoor fan motor to operate while the indoor heat exchange temperature is relatively low, and prevents the indoor fan motor from operating intermittently even when the room temperature is set low. [Example] Hereinafter, an example of the present invention will be described with reference to the drawings. FIG. 1 shows a circuit diagram of a control device for preventing cold air in an air conditioner according to the present invention. In the figure, 20 is an indoor unit of the air conditioner, and 21 is an outdoor unit of the air conditioner. The indoor unit 20 has a room temperature thermoswitch 3. similar to the conventional one shown in FIG. In addition to the air conditioning/heating selector switch 4 consisting of switches 4A to 4C and the indoor fan motor 5, there are cold air prevention thermoswitches 6A and 6B with different operating temperatures, of which the operating temperature of the thermoswitch 6B is lower than that of the thermoswitch 6A. These thermo switches 6A and 6B are connected to the heating operation side circuit of the indoor fan motor 5, that is, the heating side contact 4Cb of the switch 4C.
Switching contact 2 of relay 26, which will be described later, is connected to the line connected to
6b and 26b, they are switched and connected separately. Further, the indoor unit 20 switches either the thermoswitch 6A or 6B to the indoor fan motor 5 depending on the outside temperature.
A control circuit 22 is provided which is connected to the heating operation line to control changes in the cold air prevention operating point. The control circuit 22 includes a transformer 23 that transforms the power supplied from the power source 7 through the room temperature thermoswitch 3 and the cooling/heating selector switch 4 into a predetermined voltage during heating operation, and a rectifier that converts the alternating current transformed by the transformer 23 into direct current. 2
4, a capacitor C for smoothing the rectified output, a voltage comparator 25 using this DC output as an operating power source, and a relay 26 controlled by the output of this comparator 25. At the non-inverting input terminal of 25,
A voltage obtained by dividing the DC output of the rectifier 24 with resistors R1 and R2 is applied as a reference voltage, and the voltage is applied to the inverting input terminal of the rectifier 24 based on a change in the resistance value of a temperature detection element 27 such as a thermistor that detects the outside temperature. The resulting voltage is applied. The temperature detection element 27 is installed in the outdoor unit 21, and is connected to the rectifier 2 of the control circuit 22 via a resistor R3.
4 is connected to the DC output end of resistor R3 and temperature sensing element 2.
The voltage generated at the connection point with 7 is input to the inverting input terminal of the comparator 25 as outside temperature information. The outdoor unit 21 also includes the outdoor temperature sensing element 2.
7, a compressor motor 8, an outdoor fan motor 9, and a solenoid valve 10 are provided. Next, the operation of this embodiment configured as described above will be explained. In FIG. 1, each switch 4 of the air conditioning/heating selector switch 4
Assuming that A to 4C are connected to the heating side contact, and when the operation starts and the room temperature thermoswitch 3 is switched to the heating side contact 3b, the indoor fan motor 5 is connected to the power source 7 through the cold air prevention thermoswitch 6A. ing. Here, if the temperature of the indoor heat exchanger is below the operating point of the thermoswitch 6A, the thermoswitch 6A is open, so
The indoor fan motor 5 is not energized. At this time, since the outdoor unit 21 is energized, the compressor motor 8
The fan motor 9 is operated, and the refrigerant cycle is operated for heating. As a result, when the indoor heat exchanger warms up and the cold air prevention thermo switch 6A closes, the indoor fan motor 5
will be activated and blow warm air into the room. On the other hand, when the outside temperature is low, such as at night, and the room temperature is set lower than the cold air prevention thermoswitch, the resistance value of the outside air temperature detection element 27 increases, so it is input to the inverting input terminal of the comparator 25 of the control circuit 22. Since the voltage value applied to the non-inverting input terminal is larger than the reference voltage applied to the non-inverting input terminal, the comparator 25
The output of is at the rLJ level, and current flows through the relay 26, energizing the relay 26. When the relay 26 is energized, its contacts 26a and 26b are switched to the meter contact side shown by the white circle in FIG. 1, and the cold air prevention thermoswitch 6B is connected to the power circuit of the indoor fan motor 5. Since the operating point of this thermoswitch 6B is lower than that of the thermoswitch 6A, the indoor fan motor 5 continues to operate and blows out air while the temperature of the indoor heat exchanger is relatively lower than the set temperature. can. This prevents the indoor fan from turning on and off when the room temperature is set low, eliminating room temperature fluctuations. Note that if you want to change the operating temperature of the cold air prevention thermoswitch to two or more types depending on the outside temperature, the control circuit 22
It is sufficient to prepare the same number of cold air prevention thermoswitches with different operating temperatures and switch them. FIG. 2 shows another embodiment of the air conditioner control device of the present invention. This embodiment differs from FIG. 1 in that each system control of the air conditioner is controlled by a microcomputer. In FIG. 2, the indoor unit 20 includes a microcomputer 28 that performs cold air prevention control, indoor temperature control, etc.
The microcomputer 28 is configured to receive outside temperature information detected by the outside air temperature detection element 27 and pipe information detected by the cold air prevention pipe detection element 29, as well as the microcomputer 28. The computer 28 has
Indoor thermostat relay 30 controlled by its calculation output
and indoor fan motor relay 31 are connected,
A contact 30a of the relay 30 is connected to a line connecting the indoor fan motor 5 and the outdoor unit 21 to the power supply 7, and a contact 31a of the relay 31 is connected in series to the circuit of the indoor fan motor 5. Further, 32 is a power transformer constituting the power supply of the microcomputer 28. This power transformer 32 is connected to the commercial power supply 7 via a power switch 33, and furthermore, a rectifier and smoothing circuit 34 is connected to the secondary side of the transformer 320.
is connected, and its DC output is sent to the microcomputer 28.
is being supplied to. The outdoor unit 21 is an inverter 8a of the compressor motor 8.
A microcomputer 35 is provided for controlling the outdoor fan motor 9 and the solenoid valve 10, and an outdoor fan motor relay 36 and a solenoid valve relay 37 are connected to the microcomputer 35. A contact 36a of the relay 36 is connected in series to the power circuit of the outdoor fan motor 9, and a contact 37a of the relay 37 is connected in series to the power circuit of the solenoid valve 10. Further, the microcomputers 28 and 35 are connected to an indoor/outdoor signal line 38. In the control system having the above configuration, it is assumed that the power switch 33 is turned on, the microcomputer 28 is initialized, and the system is in the heating operation mode. Here, if the room temperature is below the set value, the microcomputer 28 controls the indoor thermo relay 3.
0 is energized and the indoor fan motor 5 and the outdoor unit 21 are connected to the power source 7 by closing the contact 30a. As a result, the microcomputer 35 converts the inverter 8a
The compressor motor 8 is controlled at a speed according to the heat load via the compressor motor 8, and at the same time, the relays 36 and 37 are energized to drive the outdoor fan motor 9 and the solenoid valve 10, and the refrigerant cycle is operated for heating. At this time, when the indoor heat exchanger is cold and the microcomputer 28 determines that the detection signal level of the cold air prevention pipe detection element 29 that detects this temperature is below the set value, the relay 31 is deenergized. The state is maintained, and the indoor fan motor 5 is not operated as in the embodiment shown in FIG. 1 above. Then, when the indoor heat exchanger is heated by the heating operation of the refrigerant cycle and the temperature exceeds the first set value, the relay 31 is energized and the indoor fan motor 5 is driven by closing the contact 31a. Warm air is blown into the room. On the other hand, when the outside air temperature is low and the room temperature is set lower than the cold air prevention temperature, such as at night, the resistance value of the outside air temperature detection element 27 increases, so the microcomputer 28 that receives this detection signal The relay 31 is controlled to continue being energized while the temperature of the indoor heat exchanger is relatively lower than the set temperature, thereby causing the indoor fan motor 5 to continue operating from the low temperature. That is, in a variable capacity air conditioner equipped with an inverter, intermittent operation is prevented when the room temperature is set low, temperature fluctuations are eliminated, and sudden changes in sound due to intermittent fan operation are eliminated.

【Effect of the invention】

As described above, according to the present invention, when the outside air temperature is low, the indoor fan motor is operated while the indoor heat exchange temperature is relatively low, so that the rise in room temperature during heating operation can be accelerated. In particular, in a variable-capacity air conditioner equipped with an inverter, if the room temperature is set lower than the cold air prevention temperature, this will prevent the indoor fan from intermittent operation, eliminate room temperature fluctuations, and reduce noise caused by intermittent indoor fan operation. It can also eliminate sudden changes.

[Brief explanation of drawings]

Fig. 1 is a system block diagram showing one embodiment of an air conditioner control device according to the present invention, Fig. 2 is a system block diagram showing another embodiment according to the invention, and Fig. 3 is a conventional example. It is a block diagram. 3...Temperature thermos iso￥, 4...Air conditioning/heating selector switch, 5...Indoor fan motor, 6A, 6B...Cold air prevention thermo switch, 8...Compressor motor, 9...
・Outdoor fan motor, 20...Indoor unit, 21・
...Outdoor unit, 22...Control circuit, 27...Outdoor temperature detection element, 28.35...Microcomputer, 29...Indoor temperature detection element, 30.31...Relay. Note that the same reference numerals in the figures indicate the same or equivalent parts. Agent Masuo Daikun (and 2 others) 3.6-1-Swee/Chi 22.411M4...i-th beak η switch 27...w+IA button-element 6A, 6B...cold m stop thermometer Switch 20...indoor switch 4. Component 21...Outdoor unit 28.35...Microcomputer 29...Indoor detection element 30.31...Relay 3rd ffl

Claims (4)

[Claims] (1) In an air conditioner that has fan motors that perform forced ventilation of the refrigerant cycle and the indoor and outdoor heat exchangers that make up the cycle, cold air prevention is performed by turning the indoor fan motor on and off depending on the temperature of the indoor heat exchanger. a temperature detector for detecting outdoor temperature; and a control means for changing and controlling the on/off temperature of the cold air prevention means according to the outdoor temperature detected by the temperature sensor. Device. (2) The control device for an air conditioner according to claim 1, wherein the cold air prevention means is composed of a plurality of thermoswitches having different operating points. (3) Claim 2, characterized in that the cold air prevention thermoswitch is selectively connected to the power supply circuit of the indoor fan motor by a control means that operates according to the outside air temperature. Control device for the air conditioner described. (4) Claim 1, characterized in that the cold air prevention means and the control means are constituted by a microcomputer whose input information is the temperature of the indoor heat exchanger and the temperature of the outside air.
A control device for an air conditioner as described in Section 1.