KR0173563B1 - Defrost perception apparatus of a refrigerator - Google Patents

Abstract

The present invention relates to a frost detection device of a refrigerator which detects an amount of frost formed on a cooler of a refrigerator and indicates an optimal defrosting time. The present invention relates to a freezer fan for supplying cold air to a cooler EVA and a freezing chamber 11. (FF) and a refrigerator comprising a refrigerator compartment fan (RF) for supplying cold air to the refrigerator compartment (12), the first temperature sensing element (TH1) installed at an upper end of the refrigerator (VA) to detect an upper temperature of the refrigerator (TH1) ), A second temperature sensing element TH2 installed at a lower end of the cooler EVA to detect a lower temperature of the cooler, and the first temperature sensing element TH1 and a driving time of the refrigerating chamber fan RF. The microcomputer 20 detects the upper and lower temperatures of the cooler EVA input through the second temperature sensing device TH2, and compares the two temperatures to output a defrosting operation command when the temperature difference exceeds a predetermined temperature. It is included.

Description

Refrigerator Detecting Device

1 is a schematic configuration diagram of a refrigerator employing the present invention.

2 is a control circuit diagram according to the present invention.

(A) of FIG. 3 is the temperature of the cooler at the time of implantation.

(b) is a curve which shows the temperature of the cooler when it is not implanted.

4 is a flowchart for implementing a frost detection device of a refrigerator according to the present invention.

* Explanation of symbols for main parts of the drawings

11: freezer 12: cold storage room

M1, M2: Motor FF: Freezer Fan

RF: Refrigerator Fan EVA: Cooler

THR: Defrost heater TH1: First temperature sensing element

TH2: second temperature sensing device 20: microcomputer

CP: Compressor

The present invention relates to a frost detection device of a refrigerator to detect the temperature difference of the temperature sensor attached to the upper and lower parts of the refrigerator to determine the optimal defrosting time by determining the amount of frost formed on the cooler.

Conventionally, as soon as the compressor of a refrigerator operates (accumulates) a predetermined time (for example, 8 hours), it is to defrost.

However, the amount of implantation of the cooler is not necessarily proportional to the operation of the compressor. For example, when the operation rate of the compressor is the same, if the temperature of the food (load) put into the refrigerator is high, the amount of implantation is increased, on the contrary, if the temperature of the load is low, the amount of implantation is reduced.

Therefore, there is a problem such as defrosting even if there is no frost in the cooler or defrosting because the cooler shows an overheating phenomenon, which leads to a problem of lowering the freezing efficiency.

The present invention is invented to improve the above-mentioned problems of the prior art, an object of the present invention is to provide a frost detection device of the refrigerator to improve the freezing efficiency by accurately detecting the defrosting time of the cooler to be optimally defrosted It is in doing it.

A frost detection device of a refrigerator according to the present invention for realizing the above object includes a cooler, a freezer compartment fan for supplying cold air to a freezer compartment, and a refrigerating compartment fan for supplying cold air to a refrigerating compartment, at the top of the cooler. A first temperature sensing element installed at a lower end of the cooler to detect an upper temperature of the cooler, a second temperature sensing element installed at a lower end of the cooler, and a first temperature sensing element at a driving time of the refrigerator compartment fan; And a microcomputer that detects the upper and lower temperatures of the cooler input through the second temperature sensing element, and compares the two temperatures to output a defrosting operation command when a difference exceeds a predetermined temperature.

Hereinafter, with reference to the accompanying drawings a preferred embodiment of the frost detection apparatus of the refrigerator according to the present invention.

1 is a schematic configuration diagram of a refrigerator employing the present invention, in which a cooler EVA is provided on a side surface of the freezer compartment 11, and a first temperature sensing device TH is installed on an upper end of the matcher. The second temperature sensing device TH2 is installed at the lower end of the cooler EVA to detect upper and lower temperatures of the cooler EVA, respectively.

In addition, the motor M1 and the freezer compartment fan FF are provided at the upper part of the cooler EVA to inject the cold air generated by the cooler EVA to the freezer compartment, and a defrost heater THR is installed at the lower part of the cooler EVA. When defrosting to remove the frost formed on the heating door cooler (EVA).

In addition, a motor M2 and a freezing compartment fan RF are provided in the side duct of the freezing compartment 12 to inject cold air generated in the cooler EVA into the refrigerating compartment 12.

2 shows a control circuit diagram according to the present invention, in which an input port P1 of the one-chip microcomputer 20 incorporating a constant program according to the present invention and controlling the overall operation of the device is located at an upper temperature of the cooler EVA. A temperature sensing circuit composed of a first temperature sensing element TH1 and a resistor R1 for detecting a temperature is connected to sense a temperature of the upper portion of the cooler EVA, and thus resistance between the first temperature sensing element TH1 and a resistor R1. The voltage value of the distribution is input to the port P1 of the microcomputer 20 so that the microcomputer 20 can recognize the temperature of the upper portion of the cooler EVA.

In addition, a temperature sensing circuit composed of a second temperature sensing element TH2 and a resistor R2 for sensing a lower temperature of the cooling unit EVA is connected to an input port P2 of the microcomputer 20 to provide a cooling unit EVA. The temperature of the lower part is sensed and the voltage value of the resistance distribution between the second temperature sensing element TH2 and the resistor R2 is input to the port P2 of the microcomputer 20 so that the microcomputer 20 receives the cooler EVA. ) It can recognize the temperature of the lower part.

In addition, a compressor driving circuit including a buffer BF1, a relay RY1, a diode D1, and a compressor is connected to an output port P3 of the microcomputer 20, and the microcomputer 20 is connected to a port P3. When the low signal is outputted, the relay RY1 is turned on through the buffer BF1 to drive the compressor CP.

A heater driving circuit including a buffer BF2, a relay RY2, a diode D2, and a defrost heater THR is connected to an output port P4 of the microcomputer 20, and the microcomputer 20 is connected to a port P4. When the low signal is outputted, the relay RY2 is turned on through the buffer BF2 to drive the defrost heater THR.

In addition, a motor driving circuit including a buffer BF3, a relay RY3, a diode D3, and a motor M1 for a freezer compartment is connected to the output port P5 of the microcomputer 20, so that the microcomputer 20 is connected. When the low signal is output to the port P5, the relay RY3 is turned on through the buffer BF3 to drive the motor M1.

A motor driving circuit including a buffer BF4, a relay RY4, a diode D4 and a motor M2 for a refrigerator compartment fan is connected to an output port P6 of the microcomputer 20, and the microcomputer 20 is connected to a port ( When the low signal is output to P6), the relay RY4 is turned on through the buffer BF4 to drive the motor M2.

(A) of FIG. 3 is a curve which shows the temperature of the cooler EVA at the time of implantation, (b) is the curve which shows the temperature of the cooler EVA when not implantation, and T1 is the 1st temperature sensing element TH1. T2 is a curve indicating the lower temperature of the cooler EVA by the second temperature sensing element TH2. During the time t1 to t6 at which the compressor CP is driven, the cooler ( The temperature of the EVA is lowered, but the temperature of the cooler EVA is increased at the time t2 to t3 (t4 to t5) when the refrigerating fan RF is rotated (for the refrigerating of the refrigerator compartment temperature).

Here, the upper temperature (T1) and the lower temperature (T2) of the cooler (EVA) is different according to the on-off of the cooling fan (RF), especially when there is a large amount of implantation in the cooler (VA), as soon as (a) and when there is no implantation amount of the cooler (EVA), the difference will be a big difference when (b) of FIG. 3, because the implantation of the cooler (VA) proceeds from the bottom, because This is because the circulating cold air flows upward through the lower part of the cooler EVA.

Accordingly, the amount of implantation can be detected by measuring the temperature of the upper and lower portions of the cooler EVA.

The operation and effect of the present invention configured as described above will be described below with reference to the flowchart of FIG.

First, when the power supply (AC, VCC1: 5V, VCC2: 12V) is applied, the microcomputer 20 detects the state of the port P3 and detects whether the low signal for driving the compressor CP is being output (S1). step).

Here, if the compressor CP is in operation, it is detected whether the refrigerating compartment fan RF is driven at the refrigerating compartment set temperature (not shown) (step S2). When the refrigerating fan RF is driven at the time t2 to t3 (t4 to t5) of FIG. 3, when the low signal to the port P6 is output, the first temperature sensing element ( The upper and lower temperatures of the cooler EVA input through the TH1) and the second temperature sensing element TH2 are detected (steps S3 and S4).

The temperature difference between the upper and lower parts of the cooler EVA is calculated (step S5). If the temperature difference of the cooler EVA differs by more than a predetermined temperature (for example, 2 ° C) (step S6), a large amount of implantation is recognized by the cooler EVA, and a low signal is output to the port P4 to perform defrosting. (Step S8), if the temperature difference does not rise above a predetermined temperature in step S6, it is determined that the amount of implantation of the cooler EVA has not reached the standard amount of defrosting to perform defrosting and then performs normal operation. ).

As described above, the present invention can more accurately detect the amount of implantation of the cooler to grasp the exact defrosting time, thereby improving the refrigerating efficiency according to the optimum defrosting.

The above description is merely a description of an embodiment of the present invention, the present invention is capable of various changes and modifications within the scope of the configuration.

Claims (1)

A refrigerator comprising a cooler (EVA), a freezer compartment fan (FF) for supplying cold air to the freezer compartment (11), and a refrigerating compartment fan (RF) for supplying cold air to the refrigerating compartment (12), wherein an upper end of the cooler (EVA) A first temperature sensing element TH1 installed in the first temperature sensing element for detecting an upper temperature of the cooler; A second temperature sensing element TH2 installed at a lower end of the cooler EVA to detect a lower temperature of the cooler; And detecting upper and lower temperatures of the cooler EVA input through the first temperature sensing device TH1 and the second temperature sensing device TH2 at the time of driving the refrigerating chamber fan RF, and determining the two temperatures. Comparing the frost detection apparatus of the refrigerator, characterized in that it comprises a micom (20) for outputting a defrosting operation command when the difference over a predetermined temperature.