KR100547421B1 - Freezing detector of the refrigerator - Google Patents

Abstract

The present invention relates to a freezing detection device for detecting whether the surface of the evaporator is frozen, so that the defrosting process required by the evaporator can be performed more accurately.

According to the present invention, the outer surface, the groove 51 is formed to be sealed on one side of the evaporator 32 so as to have a surface freezing condition equivalent to the evaporator, the heating element 54 is provided inside the groove, and the It is configured to include a temperature sensor 58 that can detect the temperature change by the driving of the heating element. In addition, periodically applying current to the heating element 54, considering the temperature change inside the groove 51, if the temperature change slope is relatively gentle, it is determined that the surface of the evaporator is frozen, the temperature inside the groove 51 If the change appears relatively rapid, we do not believe it is frozen.

Description

Freezing detector of the refrigerator

The present invention relates to a freezing detection device of the evaporator of the refrigerator, and more particularly, to a freezing detection device configured to accurately detect whether the surface of the evaporator of the refrigerator freezes, and to perform the defrosting process with an accurate defrosting cycle.

A general configuration of a refrigerator will be described with reference to FIG. 1. As shown, the refrigerator is divided into a freezer compartment 2 and a refrigerating compartment 4. An evaporator 6 for supplying cold air to the refrigerating chamber 4 and the freezing chamber 2 is provided inside the heat exchange chamber 5 behind the freezing chamber 2. And inside the heat exchange chamber 5, a blowing fan 8 for supplying cold air generated by heat exchange with the evaporator 6 to the freezing chamber 2 and the refrigerating chamber 4 is provided.

In the conventional refrigerator configured as described above, when it is determined that the temperature detected by the temperature sensor 11 installed in the freezing chamber 2 is lower than or equal to the set temperature, the compressor 7 is driven while the refrigeration cycle operates. Therefore, the evaporator 6 generates cold air by heat exchange, and the generated cold air is supplied to the freezing chamber 2 and the refrigerating chamber 4.

The cold air supplied to the freezer compartment 2 and the refrigerating compartment 4 is relatively heated while undergoing a heat exchange process with the food stored therein, and thus the cold air is heated to the inside of the heat exchange chamber 5 again. Inflow is produced | generated as cold air by heat exchange with the evaporator 6.

Through this process, moisture contained in the freezer compartment 2 and the refrigerating compartment 4 is also introduced into the heat exchange chamber 5, and when moisture is introduced into the heat exchange chamber 5, the minimum temperature is relatively low. It is attached to the evaporator 6 in a state where freezing occurs. The freezing phenomenon occurring on the surface of the evaporator 6 reduces the heat exchange efficiency of the evaporator, and thus the refrigerator removes frost such as frost on the surface through the defrosting process of the evaporator. Usually, this defrost process is performed by supplying heat to the evaporator side through the defrost heating element 10 provided adjacent to the compressor 6.

According to the related art of the defrosting process, the defrosting cycle usually calculates the driving time of the compressor, and when the driving time passes for a predetermined time, the defrosting is performed. In other words, according to the conventional defrosting process, the defrosting process is not performed depending on whether the evaporator is actually frozen or not, but according to the cycle of the driving time of the compressor in the refrigerating cycle.

According to such a conventional defrosting apparatus and method has the following disadvantages.

First, since the defrost cycle is determined by simply operating time of the compressor without judging whether there is actually freezing of the evaporator, there is a problem from the reliability of whether accurate defrost is performed. The defrosting process may be performed in the absence of substantially freezing, and the defrosting process may not be performed despite the freezing phenomenon. This is a problem of deterioration of the efficiency of the refrigeration cycle due to the waste of energy by performing unnecessary defrosting process and the defrosting is not performed even when defrosting is required. In addition, when the temperature inside the heat exchange chamber rises due to unnecessary defrosting, there is a double burden such as waste of energy in order to cool this.

An object of the present invention is to provide a freezing detection device that can accurately detect whether the evaporator freezes, it is possible to drive the refrigeration cycle most efficiently.

By this object of the present invention it will be possible to prevent unnecessary waste of energy and to provide the most efficient heat exchange performance.

In the ice-sensing device according to the present invention for achieving the above object, the outer surface, the space having the surface freezing conditions equivalent to the evaporator, the heating means installed in the space, and the temperature by the driving of the heating means It is configured to include a temperature sensing means for detecting a change, it is a technical gist to determine whether the freezing of the evaporator by using the difference in temperature change by the presence or absence of freezing of the surface of the space.

According to this configuration, since the temperature change in the space is different depending on whether the surface is frozen, it is possible to more accurately detect whether the surface of the evaporator is frozen. Therefore, the evaporator surface is frozen, and by performing the defrosting process only when defrosting is required, it becomes possible to perform a more accurate defrosting process.

And according to one embodiment of the space, it is composed of a sealable groove formed on one side of the evaporator. In addition, according to another embodiment of the space, it is composed of a sealable groove formed in the heat conduction plate provided on one side.

Next, the present invention will be described in more detail with reference to the embodiments shown in the drawings.

As shown in FIG. 2, the refrigerator according to the present invention is divided into a freezing compartment 20 and a refrigerating compartment 40, and a heat exchange chamber 30 provided with an evaporator 32 is formed at the rear of the freezing compartment 20. .

In addition, in one embodiment of the evaporator 32, that is, in the illustrated embodiment, the ice detection device 50 according to the present invention is installed at the lower end.

The temperature sensing device 50 according to the present invention includes a heat conduction plate 52 installed on one side of the evaporator 32 so that the temperature of the evaporator 32 is transmitted as it is, and a concave groove formed inside the heat conduction plate 52. And a temperature sensor 58 provided at 51.

The thermal conductive plate 52 is formed of a material having a high thermal conductivity such that the temperature of the evaporator 32 can be conducted as it is, and the groove 51 into which the temperature sensor 58 is inserted is formed. The temperature sensor 58 is inserted into the groove 51. In the illustrated embodiment, the temperature sensor 58 is provided inside the cylindrical ceramic container 56. The ceramic container 56 has a function of sufficiently enduring heat of the heating element 54, which will be described later, so that heat from the heating element is not directly conducted to the temperature sensor 58.

The heating element 54 is wound around the outside of the ceramic container 56. The heating element 54 is a kind of heater, and is configured to generate heat by supply of current. However, if the current supplied to the heating element 54 is so small that power consumption can be neglected, the heating element 54 can be configured to be capable of detecting a temperature change inside the groove 51 substantially. Suffice.

Next, the operation principle of the ice detection device configured as described above will be described.

First, when the freezing cycle inside the refrigerator is driven, the evaporator 32 is in a low temperature state, thereby making the surrounding air cold through heat exchange with the surrounding air. At this time, moisture contained in the air inside the heat exchange chamber 51 freezes while being attached to the surface of the evaporator 32 in a low temperature state. At this time, according to the present invention, moisture is also frozen on the outer side of the heat conduction plate 52 attached to the lower end of the evaporator 32, so that freezing F is generated as shown in FIG.

Here, the icing detection device 50 according to the present invention detects the temperature change through the temperature sensor 58 while applying a current to the heating element 54 at a predetermined time period. That is, when a predetermined time is reached, a current is applied to the heating element 54. The amount of current applied at this time is a very low power value as described above, and therefore, it is desirable that the power consumption is almost negligible.

As the current is applied to the heating element 54, the temperature inside the groove 51 formed in the heat conductive plate 52 is increased, and the temperature sensor 58 detects the temperature change and outputs the temperature change.

At this time, if there is freezing (F) on the outside of the heat conduction plate 52 as shown in Figure 4, due to the absorption of heat in the process of melting the freezing (F) temperature change inside the groove 51 is somewhat It will appear slowly. And if there is no freezing outside the heat conduction plate 52 is generated by the heating element 54, the temperature change will occur somewhat rapidly by heat. The temperature change in each of these cases is shown in the graph of FIG. As shown, when the surface of the heat conduction plate 52 does not freeze, the slope of the temperature rise is relatively rapid as shown by the solid line, and when the outer surface of the heat conduction plate 52 is frozen, the temperature is relatively high. The slope of the rise will appear smooth as shown by the dotted line.

Therefore, by considering the temperature change detected by the freezing detection device 50 according to the present invention, which operates periodically, it is possible to more fully determine the presence or absence of freezing outside the evaporator 32. Thus, by more completely determining the icing of the outside of the evaporator 32, it becomes possible to perform the defrost process more accurately. That is, by not performing the defrosting process when the ice is not frozen, unnecessary waste of energy can be reduced, and when the ice is frozen, the defrosting process can be performed more quickly and accurately, thereby ensuring efficient operation of the evaporator. It will be possible.

As described above, according to the present invention, it is determined whether the surface of the evaporator 32 is frozen by observing the temperature change of the inside of the groove 51 formed in the portion where the temperature in the evaporator 32 is sensitively conducted. Doing.

And of course, the present invention can be modified more within this technical scope.

First, in the above-described embodiment, the groove 51 is formed on one side of the heat conduction plate 52, and it has been shown and described as a built-in temperature sensor. However, the heat conduction plate 52 is merely an exemplary configuration configured to allow the heat in the evaporator 32 to be most sensitively conducted. Thus, for example, a groove is formed on one side of the surface of the evaporator 32 (specifically, for example, one side of a fin attached to the evaporator, etc.), and the ice detection device 50 according to the present invention described above is provided inside the groove. It is a matter of course that the present invention can be sufficiently carried out by doing so.

In the illustrated embodiment, the heating element 54 has been described through an embodiment of being wound on the outside of the ceramic container 56, but is not limited thereto. That is, the heating element 54 and the temperature sensor 58 are installed inside the groove 51 formed in the heat conduction plate 52, and the temperature change inside the groove 51 generated during the heating process of the heating element 54. If it can be detected, it will be possible to implement the present invention sufficiently.

In addition, the temperature sensor 58 represents a member capable of sensing a temperature inside the groove 51, and if the temperature can be sensed, the present invention can be embodied in various ways.

According to the present invention as described above it can be expected the following advantages.

By periodically operating the ice detection device, it is possible to detect whether the surface of the evaporator is frozen most accurately. The accurate determination of the icing state thus prevents waste of energy by performing unnecessary defrosting processes and at the same time improves heat exchange efficiency by performing accurate defrosting processes. Therefore, the reliability and energy saving of the product itself can be expected.

1 is a cross-sectional view showing the configuration of a typical refrigerator.

2 is a cross-sectional view of a refrigerator provided with an ice detection device according to the present invention.

Figure 3 is an illustration of the operation of the ice detection device of the present invention.

Figure 4 is a graph showing the temperature change during operation of the ice detection device of the present invention.

Explanation of symbols on the main parts of the drawings

20 ..... Freezer 30 ..... Heat Exchange Chamber

40 ..... Fridge 51 ..... Home

52 ..... Thermal Plate 54 ..... Heating Element

56 ...... Ceramic container 58 ..... Temperature sensor

F ..... Freezing

Claims (4)

A space in which the outer surface has surface freezing conditions comparable to the evaporator; Heat generating means installed in the space; And And a temperature sensing means capable of sensing a temperature change caused by driving of the heat generating means; Evaporator freezing detection device of the refrigerator to determine whether the evaporator is frozen by using the difference in the temperature change by the presence or absence of freezing of the surface of the space. The method of claim 1, wherein the space is, Evaporator freezing detection device of the refrigerator, characterized in that consisting of a sealable groove formed on one side of the evaporator. The method of claim 1, wherein the space is, Evaporator freezing detection device of the refrigerator, characterized in that consisting of a sealable groove formed in the heat conduction plate installed on one side of the evaporator. The evaporator freezing detection device according to any one of claims 1 to 3, wherein the temperature detection means is provided inside the ceramic container in which the heat generating means is wound.