KR100886168B1 - Method for controlling operation of food storage - Google Patents

Abstract

A control method of a food storage is provided to prevent freezing of defrosted water of a drain pan in the process of discharging the water out of the drain pan. A control method of a food storage includes a defrosting step(S3) of turning on first and second heaters for an evaporator and a drain pan, a first off step(S5) of turning off the first heater, a second off step(S7) of turning off the second heater after a set time from the turning off of the first heater, and a determination step(S1) of determining whether an integrated operation time of a compressor is over a critical time before a defrosting step so as to carry out the defrosting step if so.

Description

Method for Controlling Operation of Food Storage

The present invention relates to a storage control method, and in particular, a defrost step of turning on the first heater disposed in close proximity to the evaporator and a second heater installed in the drain pan, and a first off step of turning off the first heater and the The present invention relates to a storage control method including a second off step of turning off the second heater after a predetermined time after the first heater is turned off, and at the same time minimizing the internal temperature rise of the storage.

Conventional refrigerators are those disclosed in Korean Laid-Open Publication No. 1999-0017206.

Generally, a refrigerator is divided into a freezing compartment 1 and a refrigerating compartment 2 in which a predetermined storage space is formed, as shown in FIG. 1, and a machine room 3 of a predetermined space is located at a lower rear end of the refrigerating compartment 2. The machine room 3 is provided with a compressor 4, a refrigerant pipe, an evaporation plate 5, and the like, and a rear side of the freezing chamber 1 is provided with an evaporator 6 and various blowing fans.

In the refrigerator as described above, the refrigerant compressed at a high temperature and high pressure in the compressor 4 forms a refrigeration cycle, while circulating the refrigerant pipe to form heat exchange with the hot air in the evaporator 6, and the low temperature cold air generated through the heat exchange. By lowering the temperature of the refrigerating chamber 2 and the freezing chamber 1 while forcibly circulating the cold air flow path formed in the refrigerator by the pressure of the blowing fan, the freshness of the food stored in the refrigerator is maintained.

In addition, the cold air heat-exchanged with the stored material while circulating the cold air flow path as described above contains a large amount of moisture absorbed from the stored material, and converts the hot air into the surroundings of the evaporator 6 through the cold air flow path in the store. The cycle of heat exchange with the refrigerant of the evaporator 6 is repeated.

However, in the process of mixing hot air and cold air on the surface of the evaporator 6 as described above, a large amount of moisture contained in the hot air is adsorbed on the surface of the evaporator 6 due to the mutual temperature difference. Since the cooling efficiency of the evaporator 6 is sharply reduced, a defrost heater 7 for defrosting the defrost is installed in the lower part of the evaporator 6 in order to prevent this.

In addition, when the defrost is defrosted by the defrost heater (7), the evaporation plate (5) is collected in the water tank (9) installed in the lower portion of the defrost heater (7) and provided in the machine room (3) through the drain hose (8). And the defrost water is evaporated into the air by the defrosting device of the evaporating dish 5.

However, the conventional refrigerator as described above has a problem in that the size of the evaporating dish 5 becomes excessive, thus occupying a large space in the machine room, and it is inconvenient to install other components.

In order to solve this problem, it has been proposed that the heating means for evaporating the defrost water into the evaporation plate (5) is installed.

The heating means installed in the defrost heater and the evaporating dish 5 is stopped at the same time and there is a problem in that the evaporating dish 5 is not sufficiently heated or the evaporator 6 is excessively heated.

The present invention has been made to solve the above-mentioned problems, and the defrost step of turning on the first heater disposed in close proximity to the evaporator and the second heater installed in the drain pan and the first off step of turning off the first heater; Including a second off step of turning off the second heater after a predetermined time after the first heater is turned off, it is possible to effectively defrost and at the same time minimize the rise of the internal temperature of the reservoir, draining from the drain pan It is an object of the present invention to provide a storage control method of preventing defrosting of the drain pan from freezing again in the process.

The storage control method of the present invention for achieving the above object, the defrost step of turning on the first heater disposed in close proximity to the evaporator and the second heater installed in the drain pan and the first off step of turning off the first heater And a second off step of turning off the second heater after a predetermined time after the first heater is turned off.

According to this configuration, it is possible to effectively perform defrosting and at the same time to minimize the increase in the internal temperature of the reservoir.

Before the defrosting step, including a determining step of determining whether the accumulated operating time of the compressor has exceeded the limit time, if the limit time is exceeded, the defrosting step is executed, there is an advantage that can be effective defrosting.

After the second off step, including the operation step of operating the compressor, the internal temperature of the refrigerator can be more effectively maintained.

According to the storage control method of the present invention as described above, has the following advantages.

The defrosting step of turning on the first heater disposed in close proximity to the evaporator and the second heater installed in the drain pan, the first off step of turning off the first heater, and the predetermined time after the first heater is turned off, Including a second off step of turning off the heater, it is possible to effectively perform defrosting and at the same time minimize the rise of the internal temperature of the reservoir, and to prevent the defrost water of the drain pan from freezing again during the drain pan drain. Can be.

Before the defrosting step, including a determining step of determining whether the accumulated operating time of the compressor has exceeded the limit time, if the limit time is exceeded, the defrosting step is executed, there is an advantage that can be effective defrosting.

After the second off step, including the operation step of operating the compressor, the internal temperature of the refrigerator can be more effectively maintained.

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 of a storage control method according to a preferred embodiment of the present invention.

As shown in FIG. 2, the reservoir control method of the present embodiment includes a defrosting step S3 of turning on a first heater disposed in proximity to an evaporator and a second heater installed in a drain pan, and turning off the first heater. And a second off step S7 for turning off the second heater after a predetermined time after the first off step S5 and the first heater are turned off.

It is determined whether the accumulated operating time of the compressor has exceeded a predetermined limit time through experiments or the like. (S1)

If the operation time does not exceed the limit time, the flow ends.

If the operation time exceeds the limit time, the defrosting step S3 is executed. Here, while defrosting, the defrost water is drained through the drain pan.

The first heater disposed close to the evaporator and defrosted is turned on, and the second heater disposed in the drain pan collecting the defrost water disposed below the evaporator is turned on. The first heater and the second heater melt the ice attached to the drain pan and the evaporator.

The first heater and the second heater may be simultaneously turned on or the second heater may be turned on after a predetermined time elapses after the first heater is turned on first.

On the other hand, the compressor is turned off in the defrosting step (S3).

The first heater turns off the first heater when the temperature detected by the temperature sensor installed in the evaporator is higher than the first heater OFF temperature. (S5) Unlike the above, the first heater is operated after a predetermined time. It can also be stopped.

The second heater is turned off after a predetermined time (about 5 to 10 minutes) after the first heater is turned off (delay). (S7) The predetermined time is set to an appropriate value calculated by an experiment or the like. That is, the second heater is operated more than the first heater for a predetermined time (about 5 to 10 minutes). Through this process, the drain pan is heated while the water droplets formed in the evaporator and the drain pan flow and are drained to prevent freezing again during the draining process.

In addition, when the first heater is turned off and only the second heater is turned on, the second heater repeats on-off at a predetermined time interval. For example, the second heater may be turned on for one minute, turned off for the next one minute, and then turned on again. This requires the maximum capacity of the second heater to melt the frozen ice in the evaporator during the first defrosting to operate the first and second heaters simultaneously, but maintains the proper temperature during the second defrosting to operate only the second heater. Since 30% to 70% of the capacity of the second heater is sufficient, the second heater is repeatedly turned on and off at regular intervals to reduce the capacity.

Subsequently, the compressor is turned on and operated. (S9)

As such, by stopping the second heater later than the first heater, the defrosting can be effectively performed, and the defrost water accumulated in the drain pan can be effectively evaporated, and the internal temperature rise of the reservoir can be minimized.

 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.

The present invention can be applied to food storage, such as wine cellar, kimchi refrigerator, refrigerator of the cold or direct cooling.

1 is a cross-sectional view of a conventional refrigerator.

2 is a flowchart of a storage control method according to a preferred embodiment of the present invention.

Claims (3)

delete A defrosting step of turning on a first heater disposed in proximity to the evaporator and a second heater installed in the drain pan; A first off step of turning off the first heater; And a second off step of turning off the second heater after a predetermined time has passed after the first heater is turned off. Before the defrosting step, Including the determining step of determining whether the accumulated operating time of the compressor exceeds the limit time, The defrosting step is characterized in that the defrost step is executed if the time limit is exceeded. The method of claim 2, After the second off step, And a driving step of driving the compressor.

Images