KR0128201Y1 - Defrosting water penetration prevention structure of cooling units - Google Patents

Abstract

The present invention relates to a defrost water penetration prevention structure of the cooling unit, the evaporator, the compressor, the condenser, the capillary tube is installed in a cycle, a premise of the cooling unit is installed on the lower side of the evaporator drain box for the discharge of defrost water Thus, the defrost water is prevented from penetrating into the interior of the compressor, condenser, capillary, etc. installed in the predetermined portion of the inlet pipe and the outlet pipe connected to the evaporator, and each formed bent water inlet prevention portion guides to the lower drain box of the evaporator By doing so, by cooling the defrost water penetrated into the high temperature to prevent damage to the components in the high temperature.

Description

Defrost water penetration prevention structure of cooling unit

1 is a schematic view showing the main part configuration of a general cooling unit.

2 is a schematic view showing the configuration of the main part of the cooling unit to which the defrost water penetration prevention structure according to the present invention is applied.

* Explanation of symbols for main parts of the drawings

1: evaporator 2: compressor

3: condenser 4: capillary tube

7 ': Inlet pipe 7'c, 8'c: Defrost water penetration prevention part

8 ': outlet pipe 11: drain box

The present invention relates to a defrost water penetrating prevention structure of a cooling unit, for example in a showcase such as a balanced showcase having a structure in which an evaporator is exposed in a refrigerator. The present invention relates to a structure for preventing defrost water infiltration of a cooling unit that prevents water from penetrating into a refrigerator along an inlet and an outlet pipe of an evaporator, thereby preventing damage to components in the refrigerator.

In a general cooling showcase or the like, the evaporator 1, the compressor 2, the condenser 3, and the capillary tube 4 are cycled as shown in FIG.

In the evaporator 1, a plurality of fins 5 are arranged in the transverse direction at regular intervals, and the fins 5 are provided with a refrigerant tube 6 therethrough, and an inlet side of the refrigerant tube 6 is provided. The inlet pipe 7 and the outlet pipe 8 are connected to the outlet side, respectively.

The inlet pipe 7 and the outlet pipe 8 have horizontal portions 7a and 8a which are horizontally coupled to the refrigerant pipe 6 and have a predetermined length, and the vertical portions are formed from the horizontal portions 7a and 8a. (7b, 8b) is substantially perpendicular and extends downward, the horizontal (7a, 8a) and vertical (7b, 8b) is surrounded by a heat insulating material (9, 10) for blocking heat from the outside, respectively have.

The compressor 2, the condenser 3, and the capillary tube 4 are connected to the vertical portions 7b and 8b of the inlet pipe 7 and the outlet pipe 8 to form a cycle.

In addition, the bottom of the evaporator 1 is formed with a drain box 11 for drainage of the defrost water at a predetermined inclination angle so that the defrost water is discharged to the outside on the inclined surface (not shown) formed in the drain box 11 It is.

The cooling unit applied to the general equilibrium showcase or the like is a refrigerant that passes through the interior of the evaporator (1), the compressor (2), the condenser (3) and the capillary tube (4) and repeats the phase change from liquid to gas and gas to liquid. By circulating, the latent heat of evaporation necessary for evaporation is taken away from the air around the evaporator 1 so that the air is cooled and the refrigerated food is stored at a low temperature using the cooling air.

Due to the repeated cooling action of the cooling unit, frost is generated on the fins 5 and the refrigerant pipe 6 of the evaporator 1 and the horizontal portions 7a and 8a of the inlet pipe 7 and the outlet pipe 8. In this case, since the performance of the evaporator 1 is lowered to make it difficult to maintain the temperature in the refrigerator, a separate defrost heater (not shown) is operated every predetermined time to remove the frost, thereby preventing the deterioration of the performance of the evaporator 1. Done.

At this time, the defrost water generated from the fin 5 and the refrigerant pipe 6 of the evaporator 1 flows downward and is discharged to the outside on the inclined surface of the drain box 11.

However, in the cooling unit such as the equilibrium showcase as described above, the defrost water generated from the fin 5 of the evaporator 1 and the refrigerant pipe 6 flows downward when the frost attached to the evaporator 1 is defrosted. By discharging to the outside of the inclined surface of the (11), it is possible to prevent the phenomenon that the compressor 2, the condenser 3, the capillary tube 4, etc. penetrate into the interior of the installation, but the inlet pipe 7 and the outlet pipe 8 The defrost water resulting from the removal of the frost attached to the horizontal portions 7a and 8a of the water is penetrated into the interior of the compressor (2), the condenser (3), the capillary tube (4), etc. by the heat insulating material (9, 10). When the cooling unit is driven again after the defrosting operation, the compressor 2, the condenser 3, and the capillary tube 4 may be frozen, thereby causing a serious damage to the components in the refrigerator.

An object of the present invention is to provide a defrost water penetration prevention structure of the cooling unit to prevent the defrosting water penetrates into the interior of the defrosting operation to prevent damage to the components in the interior.

In order to achieve the above object of the present invention, a compressor for compressing a refrigerant into a gas of high temperature and high pressure, a condenser for liquefying the gas compressed in the compressor with heat in the refrigerator, and a low pressure refrigerant for easily evaporating the refrigerant liquefied in the condenser. Cooling consisting of a capillary tube to convert to a state, an evaporator to absorb the heat required for vaporization of the low-pressure refrigerant of the capillary tube from the outside to cool the inside, and a drain box installed at the lower side of the evaporator to discharge the defrost water to the outside In the unit, defrost water penetration prevention unit of the cooling unit, characterized in that the defrost water intrusion prevention portion is formed in each of the predetermined portion of the inlet pipe connecting the evaporator and the capillary and the outlet pipe connecting the outlet of the evaporator and the compressor, respectively. A structure is provided.

Hereinafter, the defrost water penetration prevention structure of the cooling unit according to the present invention will be described according to the embodiment shown in the accompanying drawings.

2 is a schematic view showing the configuration of the main part of the cooling unit to which the defrost water penetration prevention structure according to the present invention is applied.

As shown in the figure, the defrost water penetration prevention structure of the cooling unit according to the present invention has an inlet pipe 7 'on the inlet side and the outlet side of the refrigerant pipe 6 installed through the fin 5 of the evaporator 1. And the outlet pipe 8 'are connected to each other, and the compressor 2, the condenser 3, and the capillary tube 4 are connected to each other, and the inlet pipe 7' and the outlet pipe 8 'are externally connected. And the heat insulating material (9, 10) for blocking the heat is coupled to each, and the drain box 11 for discharging the defrost water to the outside of the evaporator 1 is installed to constitute a cooling unit.

The defrost water penetration prevention part 7 'which guides the defrost water into the predetermined portion of the inlet pipe 7' and the outlet pipe 8 'to the drain box 11 installed below the evaporator 1 without defrosting water. c and 8'c) are formed respectively.

That is, the defrost water penetration preventing unit 7'c and 8'c may include a predetermined portion of the inlet pipe 7 'connecting the evaporator 1 and the capillary tube 4, an outlet of the evaporator 1, and a compressor ( It forms in predetermined part of the outlet pipe 8 'which connects 2), respectively.

As the defrost water penetration preventing portion 7'a, 8'a has the vertices of the vertical portions 7'b, 8'b, as shown in the embodiment of the figure, the horizontal portions 7'a, 8'a. It may be configured to be bent in an arc shape so as to be located on the upper side, or to form the horizontal portions 7'a, 8'a of the inlet pipe 7 'and the outlet pipe 8' to have a predetermined upward inclination angle. .

The cooling unit having the defrost water penetration prevention structure according to the present invention configured as described above has a fin 5 of the evaporator 1 and a refrigerant pipe 6, and horizontal inlet pipe 7 ′ and outlet pipe 8 ′. When the defrost heater is operated while the frost is attached to the portions 7'a and 8'a, the defrost water generated from the fin 5 of the evaporator 1 and the refrigerant pipe 6 flows downward to the drain box. The defrosted water discharged to the outside on the inclined surface of (11), and also generated from the horizontal portions 7'a and 8'a of the inlet pipe 7 'and the outlet pipe 8' is the inlet pipe 7 '. ) And the defrost water penetration preventing parts 7'c and 8'c are bent at predetermined portions of the outlet pipe 8 'and the defrost water penetration preventing parts 7'c and 8'c. If there is no forcible external force at the beginning of bending of the defrost water ingress prevention part 7'c, 8'c, it will fall to the drain box 11 and be discharged to outside. It flows backward along 7'a, 8'a and falls from the evaporator 1, and is guided to the drain box 11.

As described above, the defrost water penetration prevention structure of the cooling unit according to the present invention prevents the defrost water from penetrating into a chamber in which a compressor, a condenser, and a capillary tube are installed at predetermined portions of an inlet pipe and an outlet pipe connected to an evaporator. Each of the defrost water penetrating prevention portion guided to the lower drain box of the bend is formed to prevent the phenomenon of damage to the parts in the refrigerator by cooling the defrost water penetrated into the high.

Claims (4)

A compressor for compressing the refrigerant into a gas of high temperature and high pressure, a condenser for liquefying the gas compressed in the compressor with heat in the refrigerator, a capillary tube for converting the refrigerant liquefied in the condenser into a low pressure refrigerant state that is easy to evaporate, and the capillary tube A cooling unit comprising an evaporator for absorbing heat required for vaporizing low pressure refrigerant from the outside to cool the inside of the refrigerator, and a drain box installed at the lower side of the evaporator for discharging defrost water to the outside, wherein the evaporator and the capillary tube are connected to each other. Defrost water penetration prevention structure of the cooling unit, characterized in that to form a defrost water intrusion prevention portion respectively in a predetermined portion of the inlet pipe and the outlet pipe connecting the outlet of the evaporator and the compressor. The defrost water penetration prevention structure of a cooling unit according to claim 1, wherein the defrost water penetration prevention part is formed so that its peak is located above the horizontal part. The defrost water penetration preventing structure of claim 2, wherein the defrost water penetration preventing part is formed to be bent so that its peak is located above the horizontal part. 3. The defrost water penetration preventing structure of claim 2, wherein the defrost water penetration preventing unit is configured to have a horizontal portion having a predetermined upward inclination angle so that its peak is located above the horizontal portion.