KR20110007334A - Defrost method of refrigerator - Google Patents

Abstract

PURPOSE: A defrost method for a refrigerator is provided to efficiently defrost a storage by varying a defrost time according to the load of the storage. CONSTITUTION: The temperature decreasing time of an evaporator is integrated(S3). A defrost cycle is produced According to the integrated value(S7). Defrosting is performed according to the defrost cycle. The temperature decreasing rate of the evaporator is detected(S5). The defrost time is calculated according to the temperature decreasing rate of the evaporator in a defrost cycle computing step(S9).

Description

Fridge defrosting method {DEFROST METHOD OF REFRIGERATOR}

The present invention relates to a refrigerator defrosting method, and in particular, an integration step of integrating the time when the temperature of the evaporator falls, a calculating step of calculating a defrost cycle according to the accumulated value, and defrosting according to the calculated defrost cycle. Steps.

Conventional intercooling and direct-cooling combined refrigerators are those disclosed in Korea Patent Publication No. 2003-0057790.

A storage chamber in which kimchi is stored is formed in the interior of the main body 100 formed to have an upper opening, and a lid for opening and closing the storage chamber is hinged to the upper opening of the main body 100.

In addition, a control unit for controlling the kimchi refrigerator, a condenser (not shown), a compressor, and the like, which are components of a refrigeration cycle, are installed at a lower side of the storage compartment, and an evaporator configured as a refrigerant tube is formed around the inner wall of the storage compartment. It is installed to keep the inside of the storage room at a low temperature.

And, in order to ripen the kimchi stored in the storage chamber, a aging heater composed of hot wires is installed around the lower side of the inner wall of the storage chamber.

In addition, the front and rear inner walls of the storage chamber are formed with mutually ducts extending in a height direction for cooling and introducing outside air into the air, and one side wall of the duct repeatedly has a refrigerant pipe in which a refrigerant flows therein. Is installed.

On the other hand, the cooling fan is mounted on the duct pipe, the cooling fan sucks the outside air and flows through the duct, and the cold air cooled by the refrigerant pipe flows into the inside of the chamber.

In addition, the inner side wall of the duct is formed with a number of inflow holes for introducing the cold air introduced by the cooling fan to the inner side of the duct.

Preferably, the refrigerant pipe is connected to the control unit, and the refrigerant pipe installed around the reservoir and the refrigerant pipe installed on the inner wall of the duct are branched from the solenoid valve, and the solenoid valve selectively connects the refrigerant to each refrigerant pipe. Expose through.

At the same time, the cooling fan is operated so that the cool air cooled in the duct is introduced into the reservoir through the inlet hole so that rapid cooling can be achieved.

Referring to Figure 1, each of the reservoirs (R1, R2, R3, R4) is applied to the direct cooling means and indirect cooling means at the same time, each around the inner wall of the reservoir (R1, R2, R3, R4) The main refrigerant pipe is built in, and a duct is formed on the rear surface of the main refrigerant pipe.

In addition, auxiliary coolant pipes 22a, 22b, 22c, and 22d are installed in the duct, and cooling fans 24a, 24b, 24c, and 24d are mounted at predetermined positions of the duct, respectively, to store external cold air (R1, R2). , R3, R4).

First, the kimchi refrigerator 100, which is equipped with a plurality of direct cooling and intercooling separation chambers, is cooled through a main cooling device, that is, a main refrigerant pipe during normal operation at an output temperature.

At this time, if the user selects a specific reservoir among a plurality of reservoirs R1, R2, R3, and R4, and calculates the temperature of the reservoir, the fisherman calculates that the calculated temperature is auxiliary cooling (that is, the auxiliary refrigerant pipes 22a, 22b). , Cooling by 22c, 22d) is determined by comparing with the calculated output temperature stored in the data storage.

If it is determined that auxiliary cooling is necessary, the valve is opened by applying a valve opening control signal to the solenoid driving unit.

Simultaneously with the opening of the valve, the control unit applies a driving control signal to the cooling fan driving unit to drive the cooling fan 24a of the corresponding reservoir. As the cooling fan 24a is driven and the solenoid valve is opened, the outside air introduced into the first duct 20a and the second duct 20b is converted into cold air, passes through the inlet hole, and passes through the corresponding reservoir (eg, R1). Flows into.

Thus, the reservoir in the reservoir (eg R1) is rapidly cooled to the calculated temperature.

The controller determines whether or not a storage room for which a reserved temperature change time is calculated is present among the plurality of storages R1, R2, R3, and R4. The process returns to the step of determining whether the calculated temperature is a temperature at which auxiliary cooling is required.

However, in the conventional refrigerator having several compartments, since the operation time of the compressor is different for each load of each room, the defrosting of each room uniformly may be excessive or small. In addition, the refrigerator has a problem in that the instantaneous maximum power consumption increases with simultaneous output during defrosting.

The present invention has been made to solve the above-described problem, and an object of the present invention is to provide a refrigerator defrosting method capable of efficiently defrosting a storage and preventing excessive defrosting or defrosting.

The refrigerator defrosting method of the present invention for achieving the above object, an integration step of integrating the time that the temperature of the evaporator falls, a calculating step of calculating the defrost cycle according to the integrated value, and defrosting according to the calculated defrost cycle It includes a defrosting step.

By detecting the speed at which the temperature of the evaporator falls, the defrosting time may be calculated according to the temperature falling rate of the evaporator in the calculating step.

According to the refrigerator defrosting method of the present invention as described above, there are the following effects.

It is possible to efficiently defrost, including an integration step of integrating the time when the temperature of the evaporator falls, a calculation step of calculating a defrost cycle according to the accumulated value, and a defrost step of defrosting according to the calculated defrost cycle. This can be prevented from becoming excessive or small.

By detecting the speed at which the temperature of the evaporator falls, the defrosting time is calculated according to the temperature falling rate of the evaporator in the calculating step, and the defrosting time can be changed more effectively according to the load of the storage.

Hereinafter, a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

For reference, among the configurations of the present invention to be described below, the same configuration as the prior art will be referred to the above-described prior art, and a detailed description thereof will be omitted.

2 is a flowchart illustrating a method for defrosting a refrigerator in accordance with a preferred embodiment of the present invention.

As shown in FIG. 2, the refrigerator defrosting method of the present embodiment includes an integration step S3 of integrating a time when the temperature of the evaporator falls, a calculation step S7 of calculating a defrost cycle according to the integrated value, Defrosting step (S11) to defrost according to the calculated defrost cycle.

The temperature sensor installed in the evaporator detects whether the temperature of the evaporator drops.

It is determined whether the temperature difference of the evaporator is lower than the set value. (S1) The set value of the temperature difference is calculated through a statistical value or an average value of the temperature difference value when the temperature of the evaporator is lowered due to the operation of the compressor in the experiment.

If the temperature difference of the evaporator is smaller than the set value, it is returned to determine whether the temperature difference is greater than or equal to the set value (S1).

If the temperature difference of the evaporator is higher than the set value, the compressor is operated. Therefore, the time from which the temperature of the evaporator starts to fall until the temperature of the evaporator no longer decreases, i.e., the temperature of the evaporator, is accumulated.

In addition, if the temperature difference of the evaporator is more than the set value, it detects the speed at which the temperature of the evaporator falls.

Defrost cycle is calculated according to the temperature fall time value of the integrated evaporator.

The defrosting time is calculated according to the temperature lowering speed of the evaporator. (S9)

For example, if the evaporator slows down, this means that the load on the reservoir is high, so that the defrosting time is longer. .

In this way, the defrosting time is varied according to the temperature drop rate of the evaporator, so that the defrosting can be effectively performed even when the load of the storage is different or due to external factors.

It is determined whether the calculated defrost period has been reached (S11).

If the calculated defrost cycle has not been performed, the process returns to step S1 to determine whether or not the temperature difference of the evaporator is lower than the set value without defrosting.

If the calculated defrost cycle is reached, start defrosting and defrost for the calculated defrost time (S13).

Next, the accumulated temperature fall time and the temperature fall rate are reset (S15).

This completes one cycle and returns to step S1 to determine whether the falling temperature difference of the evaporator is greater than or equal to the set value so that this cycle is continuously circulated.

In this way, defrosting can be prevented from becoming excessive or small.

In addition, when there are several reservoirs in the refrigerator, a defrost cycle and a defrost time may be calculated for each reservoir by detecting a temperature drop time and a temperature drop rate of the evaporator cooling each reservoir. Due to this, the defrosting of each reservoir can be made appropriately.

As described above, although described with reference to a preferred embodiment of the present invention, those skilled in the art various modifications or variations of the present invention without departing from the spirit and scope of the invention described in the claims below Can be carried out.

As mentioned above, the refrigerator defrosting method which concerns on this invention is especially suitable for the refrigerator defrosting method for kimchi storage which stores vegetables, such as kimchi.

1 is a schematic diagram of a conventional kimchi refrigerator.

2 is a flowchart of a method for defrosting a refrigerator according to a preferred embodiment of the present invention.

Claims (2)

An integration step of integrating a time for the temperature of the evaporator to fall; Calculating a defrost cycle according to the integrated value; A refrigerator defrosting method comprising a defrosting step of defrosting according to the calculated defrosting cycle. The method of claim 1, The defrosting method of the refrigerator comprising detecting the speed at which the temperature of the evaporator falls, and calculating the defrost time according to the temperature falling rate of the evaporator in the calculating step.

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