KR20020057702A - Controlling method for refrigerator having a pair of evaporators - Google Patents

Abstract

PURPOSE: A method for controlling operation of refrigerator with pair of evaporator is provided to quietly operate the refrigerator without noise generated in accumulators by refrigerant. CONSTITUTION: A method includes the steps of: a step(110) determining whether a compressor is operated; a step(114) completely shutting a valve controlling distribution of refrigerant supplied to a plurality of evaporators when the compressor stops; and a step(112) opening the valve, at least partly, if operation of the valve starts again. Noise such as refrigerant noise generated in accumulators is prevented thereby.

Description

Controlling method for refrigerator having a pair of evaporators

The present invention relates to an operation control method of a refrigerator having a pair of evaporators, and more particularly, to an operation control method of a refrigerator configured to prevent the generation of refrigerant noise in the accumulator when the refrigeration cycle is inoperative.

For example, in a refrigerator such as a kimchi refrigerator, it is common to use a compressor and a pair of evaporators to separately control whether cold air is supplied to two storage compartments. For example, by providing separate evaporators for two storage spaces separated from the refrigerator, it is controlled to separately supply cold air to each storage space.

The refrigeration cycle of such a refrigerator is shown schematically in FIG. 1. As shown, the refrigerant compressed by one compressor 2 flows into the valve 6 via the condenser 4. In the valve 6, the refrigerant is divided into two refrigerant tubes and supplied to the pair of evaporators 8a and 8b, respectively. And the said valve 6 is controlled so that the refrigerant | coolant of a low temperature low pressure state may be substantially supplied to either side of the said evaporator 8a, 8b. For example, when it is determined that the first storage chamber is in a high temperature state, the refrigerant is supplied to the first evaporator 8a installed therein, and when it is determined that the second storage chamber is in a high temperature state, the second evaporator 8b installed therein is provided. The refrigerant is supplied to the furnace. When both storage chambers are at a high temperature, the refrigerant is simultaneously supplied to the first evaporator 8a and the second evaporator 8b.

The refrigerant exiting the evaporators 8a and 8b passes through a pair of accumulators 10a and 10b and then flows into one compressor 2 and then the circulation of the refrigerant as described above is repeated.

Here, for example, when the first storage chamber is in a high temperature state (higher temperature than the set temperature) and the second storage chamber is in a low temperature state (low temperature state that satisfies the set temperature), the refrigerant is supplied to the first storage chamber. The compressor 2 is operated, and the evaporator 8a is operated by the operation of the compressor, thereby generating cold air in the first storage chamber. In this state, the refrigerant pipe going to the first evaporator 8a is opened by the valve 6, and the refrigerant pipe going to the second evaporator 8b is closed. This state is illustrated in FIG. 2A. It is natural that the control of the valve 6 is controlled by a microprocessor based on the detected value of the temperature sensor which senses the temperature of the storage compartment.

When the operation continues for a predetermined time and the temperature of the first storage chamber is satisfied, the compressor 2 stops driving. However, at this time, the valve 6 is in a state where the refrigerant pipe going to the first evaporator 8a is kept open.

Therefore, although the driving of the compressor 2 is in a stopped state, the refrigerant supplied by being compressed until just before the compressor 2 is stopped is supplied to the condenser 4, and such refrigerant is stored in the condenser 4. Because of the high pressure, it is substantially passed through the valve (6). Therefore, the refrigerant flows to the evaporator 8a up to a certain time, and the refrigerant enters the accumulator 10a.

As shown in FIG. 2B, the refrigerant entering the accumulator exits through the orifice hole 10c of the accumulator 10a. At this time, bubbles of the vaporized refrigerant are discharged through the orifice hole 10c. Such bubbles are generated on the surface of the liquid refrigerant accumulated in the accumulator while generating a sound of refrigerant bursting in the water surface. Such refrigerant sound is generated while the compressor 2 is not driven substantially, and corresponds to the noise of the refrigerator in actual use. Therefore, according to the conventional valve control method, it can be seen that there is a disadvantage that the refrigerant sound is generated inside the accumulator during the non-driving time of the refrigerator.

The object of the present invention is to provide a refrigerator configured to enable quiet operation without generating refrigerant sound in a refrigerator using a compressor and a pair of evaporators.

1 is a configuration of a typical refrigeration cycle of a refrigerator having a pair of evaporators.

2 is an exemplary explanatory view of a conventional valve portion.

3 is an exemplary explanatory view of a valve portion of the present invention.

4 is a flow chart illustrating exemplary operation of the present invention.

Explanation of symbols on the main parts of the drawings

6 ..... valve 8a ..... first evaporator

8b ..... 2nd Evaporator

10a, 10b ..... accumulator

According to the present invention for achieving the above object, a plurality of evaporators installed in a plurality of storage chambers, an accumulator for separating the gas liquid from the refrigerant from the evaporator, and a compressor for compressing the refrigerant, and distributes the refrigerant to the plurality of evaporators In the refrigerator having a valve for controlling the supply; Determining whether the compressor is operated; Completely shutting off the valve when the compressor stops operating; And opening at least a portion of the valve when the compressor resumes operation.

According to the control method of the present invention, by completely blocking the valve in the stopped state of the compressor, it is possible to completely block the refrigerant flowing into the evaporator and the accumulator, thereby eliminating noise such as the refrigerant sound generated in the accumulator You will be able to.

Next, the present invention will be described in more detail with reference to the embodiments shown in the drawings. In the following description, the refrigeration cycle shown in FIG. 1 will be referred together if necessary.

The above-mentioned conventional problem is that the temperature of the storage compartment is set by supplying the refrigerant to the evaporators 8a and 8b on both sides because the temperature of the compressor or the storage compartment is substantially higher than the set temperature. Immediately after the temperature is satisfied, it is judged to be due to the fact that the valve 6 is open to at least one side.

Therefore, when the current temperature of the storage compartment satisfies the set temperature and stops the operation of the compressor, it is possible to solve the above problems by blocking the refrigerant supplied to the evaporator.

First, as shown in FIG. 4, the control method of the present invention starts by determining whether a compressor for compressing a refrigerant is operating (step 110). If the compressor is in operation 110, the flow proceeds to operation 112 to open the valve 6. This process will substantially open the valve 6 at the start of the compressor operation.

In addition, when the compressor starts to operate, substantially two of the evaporators 8a and 8b are respectively installed, which means that the temperature of at least one of the storage compartments of the pair of storage compartments in which cold air is generated becomes less than or equal to the set temperature. And opening the valve 6 in step 112 means opening at least one of the paths of the refrigerant pipes supplied to the pair of evaporators 8a and 8b. That is, when the temperature of the first storage chamber in which the first evaporator 8a is installed does not satisfy the set temperature, the valve is opened to supply refrigerant to the first evaporator 8a, and the second evaporator 8b is opened. When the temperature of the installed second storage chamber does not satisfy the set temperature, it is controlled to open the valve so that the refrigerant can be supplied to the second evaporator 8b. In addition, when both the first storage chamber and the second storage chamber do not satisfy the set temperature, the valve is opened so that the refrigerant can be simultaneously supplied to the first evaporator 8a and the second evaporator 8b. Therefore, in the step 112, it can be seen that it means a process of opening the valve 6 so that the refrigerant can be supplied to at least one side among the pair of evaporators 8a and 8b.

In addition, the valve 6 is naturally driven by the control of the microprocessor receiving the temperature value detected by the temperature sensor for sensing the temperature of the storage compartment.

If it is determined in step 110 that the compressor is not being driven, the process proceeds to step 114 to control to close the valve 6. That is, the fact that the compressor is not running means that the temperature of the first storage chamber or the second storage chamber is a condition that satisfies the set temperature. This condition also includes a state in which the temperature of the storage compartment is satisfied by the generation of cold air in the first storage chamber or the second storage chamber while the compressor is operating, and the driving of the compressor is completed just before.

In any case as described above or when it is determined that the compressor is not driven, all the valves 6 are closed. Substantially closing the valve in the 114 step means shutting off the entire valve 6 so that the refrigerant is not supplied to either the first evaporator 8a or the second evaporator 8b. By blocking the valve 6 in this manner, since the refrigerant is substantially not supplied to the evaporators 8a and 8b, the refrigerant will not be supplied to the accumulator at all.

Since the coolant is not supplied to the accumulators 10a and 10b at all, the coolant generated by the accumulator is not generated at all, and thus the refrigerator may be operated in a quieter state.

As described above, according to the present invention, in a refrigerator using a pair of evaporators used in a pair of storage chambers, it is basic to completely shut off the valve when it is not necessary to supply cold air to any one evaporator. It can be seen that the technical idea. Within the scope of the basic technical idea according to the present invention, of course, many other modifications are possible to those skilled in the art.

According to the present invention as described above, it can be seen that the refrigerant going to the evaporator is completely blocked while the compressor is not driven in the refrigeration cycle. Therefore, when the compressor is not driven, there is no refrigerant flowing into the accumulator, no refrigerant sound generated in the accumulator is produced at all, and there is a convenience in use in which a quieter state can be maintained.

Claims (1)

And a plurality of evaporators installed in the plurality of storage chambers, an accumulator for separating gas liquid from the refrigerant from the evaporator, a compressor for compressing the refrigerant, and a valve for distributing the refrigerant to the plurality of evaporators and controlling supply thereof. In a refrigerator; Determining whether the compressor is operated; Completely shutting off the valve when the compressor stops operating; And And opening at least a part of the valve when the operation of the compressor is resumed.