KR100323508B1 - A defrosting method for refrigerator - Google Patents

Abstract

The present invention relates to a method for defrosting a refrigerator for removing frost generated at an evaporator installed in a refrigerator at an appropriate time point.

The defrosting operation time, which is closely related to the actual amount of defrosting, is compared with the maximum defrosting time and the minimum defrosting time already set in the system, and accordingly, the driving integration time of the compressor is appropriately changed within a certain range, and accordingly, the next defrosting time is This determination allows not only defrosting operation to be performed at an appropriate time, but also to reduce power consumption of the refrigerator and to maintain the temperature in the refrigerator uniformly, thereby providing an effect of keeping food fresher.

Description

A defrosting method for refrigerator

The present invention relates to a defrosting method of a refrigerator for removing frost generated in an evaporator installed in a refrigerator at an appropriate time point. In particular, the defrosting time is compared with a value already set in the system and the driving integration time of the compressor is appropriately changed according to the comparison result. The present invention relates to a defrosting method of a refrigerator capable of reducing power consumption and maintaining a uniform temperature in a refrigerator as the next defrosting time is determined.

In general, the refrigerator is used when the food is stored for a long time while preventing the corruption of the food is usually controlled within the temperature range of 0 ~ 10 ℃. The refrigerator has a great influence on the freshness of the food according to the temperature change therein. Therefore, in order to keep food fresh longer, it is necessary to maintain the temperature in the refrigerator uniformly and to remove frost at an appropriate time so that heat exchange proceeds smoothly.

Looking at the defrosting method of the refrigerator according to the prior art as follows.

In the operation cycle of the refrigerator, a drive cycle in which the compressor is driven for refrigerating and refrigerating and a defrost cycle in which a defrost time is determined according to the drive cycle are sequentially performed. That is, when the driving integration time of the compressor reaches a predetermined time, the frost generated in the evaporator is removed by stopping the cooling fan and operating the defrost heater. Thereafter, when the temperature sensor installed in the evaporator detects a predetermined temperature or more, the operation of the defrost heater is completed, and after waiting for a predetermined time for the defrost water to be discharged, it returns to the operation of the refrigerator again.

However, since the amount of implantation varies according to factors such as the outside temperature, the number of door opening and closing, the time the door is opened, the operation rate of the compressor, the temperature of the evaporator, and the temperature of the refrigerator compartment, the evaporator is unnecessarily heated or defrosted at an appropriate time. There is a problem.

In particular, in the low-capacity operation of the refrigerator using a variable capacity compressor, the operation rate of the compressor is relatively larger than that of the conventional one, and thus, the number of defrosting becomes more than necessary when using the above defrosting method. That is, since the temperature of the evaporator is higher than in the conventional case, if the defrosting operation is determined only by the driving integration time of the compressor, energy efficiency is deteriorated. As a result, the power consumption of the refrigerator is increased and the temperature in the refrigerator during defrosting is increased. There is a problem that the freshness is lowered during food storage because it is elevated.

The present invention has been made to solve the above problems of the prior art, the object of which is to reduce the power consumption of the refrigerator by appropriately changing the defrosting operation time that is closely related to the actual amount of implantation within a certain range, The present invention provides a method of defrosting a refrigerator in which the temperature is kept uniform so that food can be stored more freshly.

1 is a flowchart illustrating a defrosting method of a refrigerator according to the present invention;

FIG. 2 is a diagram illustrating an operating cycle of the refrigerator shown in FIG. 1.

<Explanation of symbols on main parts of the drawings>

t _c1 : First driving integration time t _c2 : Second driving integration time

t _c3 : Third driving integration time t _c4 : Fourth driving integration time

t _d1 : First defrost time t _d2 : Second defrost time

t _d3 : Third defrost time t _d4 : Fourth defrost time

Tmax: Maximum defrost time Tmin: Minimum defrost time

According to a first aspect of the defrosting method of the refrigerator according to the present invention for solving the above problems, it is applied to a refrigerator operation state divided into a drive operation of the spare shaft for refrigeration and refrigeration and a defrost operation for removing the defrost of the evaporator. In the defrosting method of the refrigerator, a first process of performing a first defrosting operation cycle in which a driving operation and a defrosting operation are sequentially performed by a driving integration time T _c1 of an initially determined compressor, and defrosting through the first process _{Compute the} time T _d1 and compare it with the best control time and the minimum defrost time Tmax, Tmin already set in the system, and change the driving integration time T _c1 of the next compressor according to the comparison result. And a second process of determining the defrosting time T _d2 .

According to a second aspect of the present invention, in the second process, when the defrosting time T _d1 is greater than or equal to the maximum defrosting time Tmax, the driving integration time T _c1 is decreased by a predetermined amount so that the second defrosting operation is performed. The defrosting time T _d2 of the period is determined, and when the defrosting time T _d1 is less than or equal to the minimum defrosting time Tmin, the defrosting time of the second defrosting operation period is increased by increasing a predetermined amount of the driving integration time T _c1 . (T _d2 ) is determined, and when the defrost time (T _d1 ) is a value between the maximum and minimum defrost times (Tmax, Tmin), the second defrost operation cycle is determined to be the same as the first defrost operation cycle.

In addition, according to the third aspect of the present invention, the amount of change in which the driving integration time T _c1 is increased or decreased is set in consideration of the operating conditions of the refrigerator such as the operation rate of the compressor, the outside temperature, the outside humidity, and the door opening and closing state. do.

Hereinafter, an embodiment of a defrosting method of a refrigerator according to the present invention will be described with reference to the accompanying drawings.

1 is a flowchart illustrating a defrosting method of a refrigerator according to the present invention, and FIG. 2 is a view illustrating an operation cycle of the refrigerator according to FIG. 1.

Referring to FIGS. 1 and 2, first, in a first step, a driving operation and an evaporator which performs an on-off operation so that a compressor is driven for freezing and refrigerating by a first driving integration time t _c1 of a compressor that is previously determined. The first defrosting operation cycle T1 in which the defrosting operation to remove the frost generated in the sequential operation is sequentially performed (see S1). At this time, the driving integration time of the compressor is obtained when the compressor is turned on in a general on / off cycle. As a cumulative time, when the accumulated value reaches a predetermined time, the defrosting timing is determined.

Next, in the second step, when the first step S1 is completed, the first defrost time t _d1 is calculated. In the third step, the first defrost time t _d1 of the second step S2 is calculated. The system compares whether or not the maximum defrost time Tmax is already set in the system (see S2 and S3).

In the fourth step, when the comparison result of the third step S3 is YES, the first driving integration time t _c1 is reduced to reduce the driving time of the compressor so that the defrosting operation can be performed within an appropriate range. The second driving integration time t _c2 is determined by subtracting the change amount α from.

In the fifth step, as shown in FIG. 2A, the second defrost time t _d2 is determined by the second driving integration time t _c2 of the fourth step S4. The next second defrosting operation cycle is performed by the second driving integration time t _c2 and the second defrost time t _d2 (see S5).

When the comparison result of the third step S3 is no, it is compared whether the first defrost time t _d1 is less than or equal to the minimum defrost time Tmin in the sixth step. Therefore, in the seventh step, when the comparison result of the sixth step S6 is YES, in order to increase the compressor driving time, the third driving integration time (a) is added to the first driving integration time. t _c3 ), and as shown in FIG. 2B, the third defrost time t _d3 is determined so that the third defrosting operation period T3 is performed (see S7).

Subsequently, in the eighth step, when the comparison result of the sixth step S6 is no, that is, the first defrost time t _d1 is a value between the maximum defrost time S and the minimum defrost time Tmin. In this case, a fourth driving integration time t _c4 , which is equal to the first driving integration time t _c1 , is determined, and likewise, as shown in FIG. 2C, the first defrost time t _d1 is determined. The fourth defrosting time t _d4 , which is equal to, is determined to perform the fourth defrosting operation period T4. (See S8. (t _d1 , t _d2 , t _d3 , t _d4 ) is a time from when the control unit (not shown) of the refrigerator decides to input the defrost to the end of the defrost, and usually the end of the defrost is the temperature attached to the evaporator. When the sensor reaches a predetermined temperature, defrost is stopped. In addition, the best defrost time (Tmax) and the minimum defrost time (Tmin) are tested. By calculating a suitable pre-defrost time range (Tmin Tmax ~) it can be determined through due.

The defrosting method of the refrigerator according to the present invention configured as described above compares the defrosting operation time closely related to the actual amount of defrosting with the maximum defrosting time and the minimum defrosting time already set in the system, and accordingly the driving integration time of the compressor according to the comparison result. The defrosting operation can be performed at an appropriate time by appropriately changing the temperature within a predetermined range so that the next defrosting time can be determined, as well as reducing the power consumption of the refrigerator and keeping the temperature in the refrigerator uniform so that the food is fresher. There is an effect that can be kept.

Claims (3)

In the defrosting method of the refrigerator applied to the refrigerator operation state divided into the driving operation of the compressor for freezing and refrigeration and the defrosting operation for removing the defrost of the evaporator, The defrosting time T _d1 is calculated through a first process of performing a first defrosting operation cycle in which a driving operation and a defrosting operation are sequentially performed by a driving integration time T _c1 of an initially determined compressor. The defrosting time T _d2 of the second defrosting operation period is determined by comparing the maximum control time and the minimum control time Tmax and Tmin already set in the system and changing the driving integration time T _c1 of the next compressor according to the comparison result. Defrosting method of a refrigerator, characterized in that comprises a second step of determining. The method of claim 1, In the second process, when the defrosting time T _d1 is greater than or equal to the maximum defrosting time Tmax, the defrosting time T _d2 of the second defrosting operation period is determined by decreasing the driving integration time T _c1 by a predetermined amount. When the defrosting time T _d1 is less than or equal to the minimum defrosting time Tmin, the driving integration time T _c1 is increased by a predetermined amount to determine the defrosting time T _d2 of the second defrosting operation cycle. When (T _d1 ) is a value between the maximum and minimum defrost time (Tmax, Tmin), the defrosting method of the refrigerator characterized in that the second defrosting operation cycle is determined to be equal to the first defrosting operation cycle. The method of claim 2, The amount of change in which the driving integration time (T _c1 ) is increased or decreased is set in consideration of the operating conditions of the refrigerator, such as the operation rate of the compressor, the outside temperature, the outside humidity, the door opening and closing conditions.