KR100443989B1 - Refrigerator for kimch - Google Patents

Abstract

The present invention relates to a kimchi refrigerator having an inner phase for accommodating a storage, an outer wound surrounding the inner wound with a foam space therebetween, an evaporator wound around the inner wound, and a temperature sensor for detecting an internal temperature of the inner wound. In one aspect, the temperature sensor is installed on the outer surface of the inner phase in which the inflow pipe portion of the evaporator is not disposed and is spaced apart from the evaporator. Thereby, the suitability of the detection of high internal temperature can be improved.

Description

Kimchi Refrigerator {REFRIGERATOR FOR KIMCH}

The present invention relates to a kimchi refrigerator, and more particularly, to a kimchi refrigerator to improve the appropriateness of the temperature detection in the high temperature.

1 is a cross-sectional view of a conventional kimchi refrigerator having two reservoirs. As shown in FIG. 1, the kimchi refrigerator includes a pair of inner beds 1 that form a storage space for accommodating kimchi, and a foam space in which the foam material 3 is filled. It has a trauma (2) that is left to surround. The inner box 1 has an upper opening for entering and exiting the storage, and the upper opening is opened and closed by the door 4, respectively. Commercially available kimchi refrigerators, unlike the kimchi refrigerators of FIG. 1, also have relatively small ones having a single inner box, and drawer-type types in which the contents of the storage are made from the front. The following description with reference to FIG. 1 is generally common to all types of Kimchi refrigerators.

An evaporator 20 for cooling the inside of the inner phase 1 is wound around the outer surface of the inner phase 1. The evaporator 20 is wound on the upper side of the inner bed 1 in consideration of the downward flow characteristic of the cold air. The evaporator 20 receives refrigerant through a condenser (not shown) from the compressor 5 provided at the lower portion of the inner bed 1, and returns the refrigerant having a cooling function back to the compressor 5. As shown in the drawing, when two storage chambers are provided, the evaporator 20 attached to each inner bed 1 is selectively or simultaneously branched and supplied with the refrigerant from the condenser by a branch valve device (not shown).

Moreover, the heater 6 which can heat the inside of the inner case 1 is wound in the lower area | region of the inner case 1. The heater 6 serves to ferment the stored matter, especially kimchi, by heating the storage space of the inner phase 1 as necessary.

2 is a perspective view of the inner box 1. The inner phase 1 has a generally square cross-sectional shape, thereby having two relatively narrow mutually opposite sidewalls and two relatively wider opposite sidewalls. The evaporator 20 is wound around the inner phase 1 in the form of a coil. The evaporator 20 has an inlet tube section 21 and an outlet tube section 22 for the inlet and outlet of the refrigerant, which extend in parallel to the bottom of the inner bed 1. Thus, the refrigerant supplied from the lower part through the inlet pipe part 21 from the condenser flows upward along the flow path on the coil, and then flows downward again along the outlet pipe part 22 to return to the compressor 5.

On the other hand, adjacent to the inlet pipe part 21 and the outlet pipe part 22, a temperature sensor 30 for detecting the temperature in the refrigerator is attached to the outer surface of the inner box 1. The temperature sensor 30 provides a temperature signal detected at the corresponding position to a controller (not shown), and the controller controls the operation of the compressor 5 or the heater 6 based on the temperature signal to set the temperature in the refrigerator within the set range. Keep it.

As shown in the drawing, the temperature sensor 30 is attached to the outer surface of the same side wall as that where the inlet pipe part 21 and the outlet pipe part 22 are arranged, and the connection of the outlet pipe parts 21 and 22 and the temperature sensor ( Considering the convenience of the operation that the attachment of 30) can be performed on the same side wall, the temperature sensor 30 appears to be due to the anticipation of the speed of temperature sensing by adjoining the inflow and outflow refrigerant.

However, in the conventional Kimchi refrigerator, as the temperature sensor 30 is disposed adjacent to the same side wall as the inlet and outlet pipe parts 21 and 22, the temperature sensor 30 is connected to the inlet pipe part 21 or the outlet pipe part 22. There is a problem that a lot of influence is generated, and temperature information different from the actual internal temperature is generated.

For example, when the refrigerant is initially supplied to the evaporator 20 by opening the valve, the refrigerant is excessively concentrated in the region of the inlet pipe portion 21, while the other region of the evaporator 20 is not filled with the refrigerant. The full-fledged cooling function is not achieved. At this time, since the temperature sensor 30 is adjacent to the inlet pipe 21, it can be directly or indirectly affected. That is, not only the temperature of the refrigerant in the inlet pipe part 21 can directly affect the temperature sensor 30, but also the temperature in the refrigerator in the area in which the inlet pipe part 21 is cooled is faster than other areas. 30 detects only the local temperature.

In this way, since the temperature sensor 30 is affected by the local temperature in the refrigerator or the temperature of the external inlet and outflow pipe portion, the target position temperature in the refrigerator cannot be detected properly, so that the temperature control in the refrigerator is inappropriate, Since the intermittent period of the compressor is unduly shortened according to the temperature distribution deviation, it takes a lot of time to bring the high internal temperature to the desired range initially. This problem also results in increased energy consumption, reduced product reliability, excessive test time and consequently lower productivity.

This irrational point is also caused by the so-called after-cooling effect due to the evaporation of the remaining refrigerant after the operation of the compressor and the so-called coolant effect in which the refrigerant is directed to either side according to the discrepancy in the refrigerant interruption time provided in the two valves at the branch valve. Can be increased.

Accordingly, it is an object of the present invention to provide a kimchi refrigerator that improves the adequacy of high temperature detection and improves test time and temperature control.

Another object of the present invention is to provide a kimchi refrigerator capable of properly detecting the target position temperature in the refrigerator.

1 is a cross-sectional view of a conventional kimchi refrigerator,

Figure 2 is a perspective view of the inside of the conventional kimchi refrigerator,

Figure 3 is a perspective view of the inside of the kimchi refrigerator according to the present invention,

4 is a front view of the inside of FIG.

* Explanation of symbols for the main parts of the drawings

1: inner wound 6: heater

20: evaporator 21: inlet pipe

21: outlet pipe part 30, 35: temperature sensor

36: adhesive tape

The object is a Kimchi refrigerator having an inner phase for accommodating a storage, an outer wound surrounding the inner wound with a foam space therebetween, an evaporator wound around the inner wound, and a temperature sensor for detecting the internal temperature of the inner wound. In the, the temperature sensor is achieved by the kimchi refrigerator characterized in that spaced apart from the evaporator on the outer surface of the inner phase in which the outflow pipe portion of the evaporator is not disposed.

It is more preferable that the temperature sensor is provided on an outer surface of the inner surface of the inner phase in which the inflow pipe portion is disposed. When the inner phase has a rectangular cross-sectional shape with an upward opening, the inflow pipe part and the temperature sensor are respectively disposed on the outer surface of the narrow side wall, and the temperature sensor is attached downwardly away from the evaporator, so that the temperature distribution is as homogenous as possible. The internal temperature can be measured. Here, in order to prevent the temperature sensor from being affected by the heater, the heater is preferably installed in the lower region of the temperature sensor so as to surround the inner phase spaced apart from the temperature sensor.

In order to allow the temperature sensor to properly measure the mid-height temperature in the chamber, the evaporator is placed from the top of the inner bed to a length of 30 to 60% of the total height of the inner bed, and the temperature sensor is placed at the full height of the inner bed from the bottom of the evaporator. Preferably, they are spaced at least 10% apart.

Hereinafter, with reference to the accompanying drawings of an embodiment of the present invention will be described in detail the present invention. In the embodiment of the present invention will be given the same reference numerals for the same components as described with respect to the conventional kimchi refrigerator of Figure 1 while the duplicate description will be omitted.

In addition, the embodiment of the kimchi refrigerator according to the present invention since the basic structure is substantially the same as the conventional kimchi refrigerator of Figure 1, the description of the basic structure uses those of the prior art.

Figure 3 is a perspective view of the inner wound (1) applied to the kimchi refrigerator according to the present invention, and corresponds to Figure 2 showing the inner wound (1) applied to the conventional kimchi refrigerator, with reference to Figure 2 will be able to improve understanding. .

Similar to the inner wound 1 of FIG. 2, the inner wound 1 of FIG. 3 has a generally square cross-sectional shape, and has a pair of mutually opposite narrow sidewalls and a pair of mutually opposite wide sidewalls. The evaporator 20 is wound around the inner phase 1 in the form of a coil. The evaporator 20 has an inlet tube section 21 and an outlet tube section 22 for the inlet and outlet of the refrigerant, which extend in parallel to the bottom of the inner bed 1. These inlet pipe sections 21 and outlet pipe sections 22 are in contact with the narrow side walls at the rear in the drawing.

The temperature sensor 35 is electrically conductive, such as AL tape, at a position spaced downward from the lower end of the evaporator 20 on a narrow side wall in front of the drawing opposite to the side wall on which the inlet pipe part 21 and the outlet pipe part 22 are disposed. It is attached by the adhesive tape 36.

4 is a front view of the inner wound 1 according to FIG. 3. In this figure the geometric relationship between the evaporator 20, the temperature sensor 35 and the heater 6, which is installed in the inner phase 1, is shown.

As can be seen in this figure, in consideration of the downward flow characteristics of the cold air and the upward flow characteristics of the heat, the evaporator 20 is disposed in the upper region of the inner phase 1, the heater 6 is disposed in the lower region. The temperature sensor 35 is attached between the evaporator 20 and the heater 6 spaced apart from them, respectively.

The evaporator 20 extends downwardly from the top of the internal wound (He) in the range of 30 to 60% of the total height (H) of the internal wound (1) to prevent local subcooling and uncooling. It is advantageous, and the range of 40-50% is more preferable.

The temperature sensor 35 is required to be installed at a position capable of detecting the temperature at the center (target position) of the inside of the refrigerator at the middle height (1 / 2H) of the inner box 1 in order to properly control the temperature. However, since the temperature sensor 35 is attached to the outer surface of the inner phase 1, it is impossible to actually detect the temperature of the target position. Thus, the inventors of the present invention after a number of tests, the distance (S) from the lower end of the evaporator 20 of the temperature sensor 35 is closer to the temperature of the target position when the distance (S) of the inner phase (1) 10% or more. It was confirmed that the detection result was shown. More preferably, the separation distance S of the temperature sensor 35 is 25 to 35% of the total height H of the inner phase 1.

On the other hand, since the frequency of operation of the heater 6 is lower than that of the evaporator 20, the influence on the temperature sensor 35 is not large. Thus, the temperature sensor 35 only needs to have a separation distance such that the adhesive tape 36 fixing the temperature does not come into contact with the heater 6.

With the above configuration, since the temperature sensor 35 and the inlet and outlet pipe parts 21 and 22 are arranged on the sidewalls facing each other, the refrigerant temperature in the outlet and inlet pipe parts 21 and 22 directly affects the temperature sensor 35. Can't be crazy. In addition, since the air in the refrigerator locally cooled by the inflow and outflow pipe portions 21 and 22 passes through the storage space in the refrigerator and then is transferred to the temperature sensor 35, the temperature sensor 35 is minimized after the temperature distribution deviation in the refrigerator is minimized. The homogenized temperature of is detected. In particular, when the inflow and outflow pipe parts 21 and 22 and the temperature sensor 35 are arranged on the short sidewalls of the inner box 1 each having a rectangular cross-sectional shape, the linear distance between each other is maximized, so that the influence of the temperature sensor 35 is Will be minimized.

In addition, according to one preferred embodiment of the present invention, when the temperature sensor 35 is disposed at an appropriate position in relation to the overall height of the inner phase 1 and the extension length of the evaporator 20, the temperature of the target position in the high effectively It can detect, and can improve control adequacy further.

In the above embodiment, although the top-opening kimchi refrigerator having two storage compartments is taken as an example, it is obvious that the present invention can be suitably applied to the type or drawer-type kimchi refrigerator having a single storage compartment. In addition, in the preferred embodiment, it has been described that the inlet and outlet pipe parts 21 and 22 and the temperature sensor 35 are disposed on opposite sidewalls, but the object of the present invention can naturally be achieved even when disposed on different adjacent sidewalls.

As described above, according to the kimchi refrigerator of the present invention, by achieving the adequacy of high temperature detection, significant effects such as energy saving, improved product reliability, and increased productivity are provided.

Claims (5)

In a kimchi refrigerator having an inner phase for accommodating a storage, an outer wound surrounding the inner wound with a foam space therebetween, an evaporator wound around the inner wound, and a temperature sensor for detecting an internal temperature of the inner wound, The temperature sensor is a kimchi refrigerator, characterized in that spaced apart from the evaporator is installed on the outer surface of the inner phase in which the outflow pipe portion of the evaporator is not disposed. The method of claim 1, The temperature sensor is a kimchi refrigerator, characterized in that installed on the outer surface opposite the outer surface of the inner phase in which the outflow pipe portion is disposed. The method of claim 2, The inner phase has a rectangular cross-sectional shape that is open upward, the outlet pipe portion and the temperature sensor are each disposed on the outer surface of the narrow side wall, the temperature sensor is characterized in that the spaced apart from the evaporator. The method of claim 3, Kimchi refrigerator, characterized in that the heater is spaced apart from the temperature sensor in the lower region of the temperature sensor surrounding the inner phase. The method of claim 3, The evaporator is disposed from the upper end of the inner phase to a length of 30 to 60% of the total height of the inner phase, and the temperature sensor is spaced apart from the lower end of the evaporator by a distance of 10% or more of the total height of the inner phase. Kimchi refrigerator.