KR900007067Y1 - Device for defrosting of refrigerator - Google Patents

Abstract

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Description

Defroster for refrigerator

1 is a schematic view showing a general configuration of a defrosting device.

2 shows the timer cam of FIG. 1;

3 is a schematic view showing an embodiment of the present invention.

4 shows a timer cam of FIG. 3;

5 is a graph showing the on-off period of each switch contact.

* Explanation of symbols for main parts of the drawings

A: Power contact B: Frozen contact

C: Defrost contact D: Valve contact

The present invention relates to a defroster for refrigerators.

When the refrigerant is endothermic through the evaporator of the refrigerator, moisture in the surrounding air or moisture contained in the stored food condenses around the evaporator to form frost.

Since this castle covers the surface of the evaporator, it causes the refrigeration efficiency to decrease, so it is necessary to remove it properly.

There are many types of defrosting devices that have been put into use in the refrigerator field, but the on-time timer type that automatically removes defrosting every 24 hours in the cold forced circulation refrigerator and the defrosting of the compressor when a certain time is reached Integral timers are usually used to start.

For example, as shown in FIG. 1, the timer motor 2 and the compressor 3 are connected in parallel to the rear end side of the freezing sensor 1 for measuring the temperature in the refrigerator, and the power supply is supplied to the front end of the freezing sensor 1. The contact point (A), the freezing contact point (B) and the defrost contact point (C) are installed to be interlocked with the cam 2 'of the timer motor 2, and the defrost heater 4 is directly connected to the defrost contact point C. It is configured to be connected to the power supply side via the defrost detector 5 together with the rear end side of the timer motor 2 described above.

In the conventional defroster, the timer motor 2 and the compressor 3 simultaneously operate in a state where the switch between the power contact A and the freezing contact B is on, and the freezing sensor 1 The compressor 3 is driven and stopped according to the temperature, which means that the running time of the compressor 3 is accumulated in the timer motor 2.

The cam 2 'of the timer motor 2 periodically selects and switches any one of the freezing contact B and the defrost contact C with the power contact A therebetween as shown in FIG. When the cam 2 'is rotated while the power contact A and the freezing contact B shown in the switch-on state, the power contact A contacts the defrosting contact C, and the freezing contact B )).

As a result, the power contact (A), the defrost contact (C), the defrost heater (4) and the defrost detector (5) become ferro, and the defrost heater (4) is melted and removed from the castle on the evaporator.

When the temperature of the evaporator rises when the frost is removed, the defrost detector 5 detects it and turns it off. Accordingly, the timer motor 2 is driven again to rotate the cam 2 'so that Return to the state is repeated.

In the above-mentioned conventional defroster, the defrost heater 4 has a long operation time because the compressed refrigerant is charged inside the evaporator during defrosting, resulting in waste of power.

In view of such drawbacks, the present invention blocks the refrigerant passage immediately before the start of defrosting and operates the compressor for a while to recover the refrigerant in the evaporator, thereby eliminating the defrosting for refrigerators that can shorten the operating time of the defrost heater (5). The purpose is to reduce the power consumption by providing a device, which will be described in detail with reference to FIGS.

The present invention adds a valve contact (D) between the freezing contact (B) and the defrost contact (C), as shown in FIG. 3, and directly connects the solenoid valve (6) to the valve contact (D). As shown in FIG. 5 and FIG. 5, the cycles at which the contacts B, C and D are turned on and off with the power contact A by the cam 2 ', respectively, before the refrigeration contact B turns off, (D) is turned on for the period T ₁ , and off with the freezing contact (B) and at the same time characterized in that the defrost contact (C) is on.

In the present invention described above, the solenoid valve 6 is interposed between the dryer and the capillary tube of a conventional refrigeration cycle.

According to the present invention, the solenoid valve 6 shuts off the refrigerant circulation passage as the valve contact D is turned on before the freezing contact point B is turned off. In this state, the compressor 3 cycles T. _Since the operation is continued for _one year, the refrigerant inside the evaporator is sucked and recovered by the compressor 3.

Therefore, the period T ₁ should be given as long as the refrigerant inside the evaporator can be completely recovered after the solenoid valve 6 is operated.

When the refrigerant in the evaporator is recovered during the period T ₁ , the refrigeration contact point (B) and the valve contact point (D) are turned off at the same time, and the defrost contact point (C) is turned on. Since the frost does not easily melt, the time T ₂ required for defrosting is greatly shortened.

As a result, the refrigerator to which the present invention is applied can reduce the power consumption.

The present invention described above illustrates an application to an integrated timer type defrosting device as an example, but any type of defrosting device having a structure that commands freezing-defrosting by a cam rotated by a timer motor is applicable to any type. can do.

Claims (1)

In a conventional refrigerator defroster configured to switch between the power supply contact point (A) and the freezing contact point (B) and the defrost contact point (C) by a cam of the timer motor, and switching on and off periodically, A valve contact (D) is added between B) and the defrost contact (C), and the valve contact (D) is connected directly to the solenoid valve (6) placed on the front side of the evaporator of a normal refrigeration cycle. The defrosting device for a refrigerator, characterized in that the switching on period T ₁ of D) is configured to be located before the off point of the freezing contact point (B).