KR0152855B1 - Defrosting sensing device of cooling/heating airconditioner - Google Patents

Abstract

The present invention relates to a defrost detection device for a combined air / cooling air conditioner, comprising: an output sensing unit sensing an output voltage of four sides without a current transformer, and a microcomputer that recognizes a defrosting operation according to the output voltage of the output sensing unit; Conventional problems such as the installation of a current transformer on a printed circuit board (PCB) and the use of a power supply suitable for the current transformer are solved, and the defrosting operation can be detected regardless of the type of four sides and the manufacturing cost is reduced.

Description

Defrost detection device for air conditioning / cooling

1 is a configuration diagram of a defrost detection device of a conventional air conditioning combined heating / heating.

Figure 2 is a block diagram of a defrost detection device of the present invention air conditioning / heating combined.

3 is a waveform diagram of each part of FIG.

* Explanation of symbols for the main parts of the drawings

201: microcomputer 202: four sides control unit

203: four sides 204: output detection unit

205: operation switching unit

The present invention relates to a defrost detection device for a combined air / cooling air conditioner. In particular, the present invention relates to a cold / heating system capable of accurately detecting a defrost operation regardless of the type of a 4-way valve used for a combined air / cooling air conditioner. It is related with the defrost detection apparatus of the air-conditioning combined heating.

FIG. 1 is a block diagram of a defrost detection device of a conventional air conditioning / heating combined air conditioner that detects a defrost operation using a current transformer.

As shown therein, the conventional defrost detection device for a combined air / cooling air conditioner includes a current transformer 104-2 provided so as to detect a current in all four sides of the air conditioning / cooling combined air conditioner, and the current transformer 104-2. And a comparison unit 104-1 for comparing the secondary side currents with a predetermined reference value, and a microcomputer 101 for recognizing defrosting operation in accordance with the comparison result of the comparison unit 104-1. Reference numeral '102' denotes a four-sided control unit which receives a high signal from the output port P1 of the microcomputer 101 during the heating operation and supplies the power voltage AC to the four-sided 103. Is an operation switching unit for switching the heating operation to the defrost operation in accordance with the value of the pipe thermistor (TH).

Hereinafter, the operation on the above configuration will be described.

First, during the heating operation, the relay controller 105-1 of the operation switching unit 105 installed on the pipe thermistor TH side supplies the driving power through the rectifying unit 105-2 rectifying the power voltage AC. Receiving to turn on the relay (RY2) of the operation switching unit 105 provided on one side of the four sides 103, the power supply voltage (AC) is turned on in the four sides (103) via the relay (RY2) is turned on. The heating operation is performed by supplying.

When the value of the pipe thermistor TH reaches a predetermined value during the heating operation, the relay controller 105-1 of the operation switching unit 105 switches to the defrosting operation from the current heating operation. The relay RY2, which was turned on during the heating operation, is turned off to cut off the power supply voltage AC supplied to one side of the four sides 103, and thus the current transformer installed on the other side of the four sides 103 The secondary side current of 104-2) is different from that of heating operation.

At this time, the comparator 104-1, which is to receive the secondary side current of the current transformer 104-2, compares the secondary side current with a predetermined reference value to determine whether the secondary side current is a value corresponding to the defrost operation. If the value corresponds to the defrosting operation, a signal indicating this is input to the input port P2 of the microcomputer 101.

The microcomputer 101 then recognizes the defrosting operation.

As described above, a current transformer is used for the defrosting operation judgment. Since this current transformer cannot cope with all kinds of four sides equally, it is difficult to use a current transformer according to the four sides, and the manufacturing cost increases due to the use of the current transformer. In addition, the current transformer has a problem in that it is inconvenient to mount on a printed circuit board (PCB) and hassle to use a power supply voltage.

The present invention was devised to solve this conventional problem.

Accordingly, the object of the present invention is that the conventional problems are caused by using the current transformer, so that the conventional problems can be solved by not using the current transformer, in particular cold / cold to accurately detect the defrost operation regardless of the type of four sides It is to provide a defrost detection device for a combined air conditioning.

Defrost detection device of the air-conditioning combined air conditioner of the present invention according to the above object, as shown in Figure 2, the output detection unit 204 for detecting the output voltage of the four sides 203 without the current transformer, and the output detection unit The microcomputer 201 determines whether or not the defrosting operation is performed in accordance with the output waveform of 204. Reference numeral '202' denotes a four-sided control unit which receives a high signal from the output port P1 of the microcomputer 201 and supplies the power voltage AC to the four-sided side 203 during heating operation. Is an operation switching part for changing the heating operation to the defrost operation according to the value of the pipe thermistor (TH).

The output detector 204 half-wave rectifies the voltage drop unit 204-3 for dropping the output voltage of the four sides 203 and the output voltage of the voltage drop unit 204-3 during the defrosting operation. Outputs a half-wave rectifier 204-2, a photocoupler PT1 on / off according to the half-wave voltage of the half-wave rectifier 204-2, and a square wave pulse according to on / off of the photocoupler PT1. Is an output unit 204-1.

Hereinafter, the operation will be described in detail. However, detailed description of the same parts as in the prior art is omitted.

First, as the value of the pipe thermistor TH reaches a predetermined value during the heating operation, the four sides of the relay controller 205-1 in the relay controller 205-1 of the operation switching unit 205 for switching the current heating operation to the defrosting operation. When the relay RY2 connected to the side is turned off, the output voltage of the sine wave as shown in FIG. 3 (a) appears on the output side of the four sides 203.

In this way, the sinusoidal voltage shown on the output side of the four sides 203 is inputted to the output sensing unit 204, and is caused by the capacitor C2 and the resistor R4 of the voltage dropping unit 204-3 of the output sensing unit 204. The voltage is divided and the voltage is dropped, and then the rectifying diode D2 of the half-wave rectifying unit 204-2 becomes a half-wave voltage as shown in FIG. 3B and is input to the photocoupler PT1. The resistor R3 of the half-wave rectifier 204-2 is for limiting the current of the photocoupler PT1.

On the other hand, the photocoupler PT1 of the output sensing unit 204 repeats the on / off according to the half-wave voltage, so that the output unit 204-1 of the output sensing unit 204 is thus a photocoupler ( A square wave pulse as shown in FIG. 3 (c) shown as PT1) is repeatedly turned on and off is input to the input port P2 of the microcomputer 201.

When the square wave pulse is input to the input port P2 as described above, the microcomputer 201 determines that the defrosting operation is present.

For reference, FIG. 3D is a signal appearing at the input side of the output sensing unit 204 during normal heating operation, (e) is a signal appearing at the output side of the diode D1, and (f) is a microcomputer ( As a signal input to the input port P2 of 201, it can be seen that these signals are distinguished from the signals (a) to (c) which appear during defrosting operation, and the microcomputer 201 is shown in FIG. When the DC waveform is input, it is determined that the heating operation.

As described in detail above, the present invention does not use a current transformer to detect the defrosting operation, thereby solving conventional problems such as the installation of a current transformer on a printed circuit board and the use of a power source suitable for the current transformer. Defrost operation can be detected accurately without, and manufacturing cost is reduced.

Claims (3)

In the defrost detection device for an air conditioning / cooling combined air conditioner, a voltage drop unit for directly receiving and dropping an output sinusoidal voltage of four sides without using a current transformer, a half wave rectifier for half-wave rectifying the output voltage of the voltage drop unit, and an output of the half wave rectifier And a photo coupler that is turned on / off according to a voltage, an output unit that outputs square wave pulses according to the on / off of the photo coupler, and a microcomputer that determines whether a defrost operation is performed according to the output waveform of the output unit. Defrost detection device for combined air conditioning and cooling. The defrost detection device for a combined air / cooling air conditioner according to claim 1, wherein the voltage drop unit divides the output sinusoidal voltage of the four-sided side and drops the resistor R5, the capacitor C2, and the resistor R4. 2. The defrost detection apparatus for an air conditioner for dual cooling / heating according to claim 1, wherein the microcomputer is configured to determine that the output waveform of the output unit is a heating operation when the output waveform is a constant DC waveform and that the defrosting operation is performed when the square wave pulse is used.