KR100683629B1 - Hole Structure Outlet of Evaporator at Kim-Chi Storage - Google Patents

Abstract

The present invention relates to the evaporator outlet shape structure of the kimchi storage, the present invention is the suction pipe of the outlet side of the first and second evaporators arranged in the plurality of storage chambers respectively through the through-hole formed on the base cover of the upper machine room in the machine room In the kimchi storage having a refrigerant pipe connection structure to be connected to the compressor and the capillary connected to the condenser, the through-hole formed on the base cover is formed into a plurality of separation to correspond to each suction pipe; The through hole is provided in the evaporator outlet through hole structure of the kimchi storage, characterized in that formed in the groove shape wider than the cross-sectional area of the suction pipe.

According to the through-hole structure according to the present invention, as the foam liquid enters into the through-hole of the groove shape during the foam molding work for the internal insulation of the kimchi storage is naturally sealed (sealing), as well as workability, each evaporator Capillary to be connected has an effect that can be prevented from being assembled incorrectly cross.

     Kimchi storage, compressor, evaporator, suction pipe, capillary tube, base cover, through hole

Description

Hole Structure Outlet of Evaporator at Kim-Chi Storage

1 is a perspective view showing one embodiment of the conventional kimchi storage,

2 is a view schematically showing the internal configuration of the conventional kimchi storage,

3 is a cross-sectional view showing a state in which a suction pipe is disposed through a through hole formed on a base cover according to the prior art;

Figure 4 is a view schematically showing the internal configuration of the kimchi storage in accordance with the present invention,

5 and 6 is an enlarged perspective view of the main portion showing a state in which a through hole is formed on the base cover according to the present invention.

* Description of the symbols for the main parts of the drawings *

1 body 2,2 'door

3: machine room 4,4 ': storage room

5: compressor 6: condenser

7,7 ': first and second evaporators 9,9': capillary

10: base cover 11,11 ': suction pipe

14,14 ': through hole

The present invention relates to the evaporator outlet through-hole structure of the kimchi storage, and more specifically to each of the evaporator outlet side suction pipes provided in the plurality of storage chambers to form a through-hole on the base cover to be connected to the machine room, respectively, suction pipe By forming a groove having a larger cross-sectional area, the foaming liquid enters into the groove-shaped through hole during the internal foaming operation of the kimchi storage, and as the sealing becomes natural, the workability is improved, as well as the capillaries connected to each evaporator. It is related to the evaporator outlet through-hole structure of the Kimchi reservoir to prevent misassembly from being staggered.

As it is known, Kimchi storage was developed exclusively for kimchi, which allows the kimchi to be matured and stored freshly by using a cooling system and a heater. Next, it is configured to maintain a proper temperature to preserve the taste of ripe kimchi for a long time.

Accordingly, the use of kimchi storage is gradually increasing as it is popular among housewives who have recently suffered from long-term storage (or storage) of kimchi at home.

These kimchi storage is very diverse bar, according to the door opening and closing method, the top of the door hinged to the upper surface attached, the drawer of the door is formed in the form of drawers, the top of the drawer and drawer mixed mixture It can be divided into

Here, looking at the configuration of the kimchi storage is divided into various ways according to the door opening and closing method as described above.

That is, as shown in Figs. 1 and 2, in the conventional kimchi storage, a plurality of storage chambers 4 and 4 'are usually partitioned above the main body 1, which forms an appearance, and the plurality of storage chambers 4 and 4' are divided. A plurality of doors (2, 2 ') for opening and closing the hinge is coupled to the upper end of the rear surface of the main body (1) so that it can be opened and opened upward.

In the lower part of the storage chambers 4 and 4 ′, a machine room including a compressor 5 for a refrigeration cycle, a condenser 6, and a blower 10 for cooling the heat generated by the condenser 6 is disposed. (3) is separately divided.

In addition, the first evaporator and the second evaporator (7,7 ') having a structure in which the refrigerant pipes for supplying cold air through the direct cooling method are arranged at regular intervals and wrapped around each of the storage chambers 4 and 4'. Each of the first and second evaporators 7 and 7 'is connected to the compressor 5 and the condenser 6 of the machine room 3 so that the refrigerant can circulate.

In addition, heaters 8 and 8 'are provided below the first and second evaporators 7 and 7' which surround the respective storage compartments 4 and 4 ', respectively. It is designed to provide a constant heating temperature when fermenting kimchi.

In particular, the heat insulation effect, such as urethane foam is put through the foam molding to the part that needs heat insulation inside the main body 1 to obtain a heat insulation effect.

In addition, on the upper front surface of the main body (1) can be selected according to the type of kimchi accommodated in the storage compartment (4, 4 '), storage time and temperature conditions, as well as a display control unit that can display the selected signal (13) is provided.

Therefore, the control of all operations of the kimchi storage by the user is to be made in the display operation unit 13 provided on the front of the main body (1).

In the conventional kimchi storage having such a configuration, the kimchi is stored using a separate kimchi container not shown in the storage chambers 4 and 4 ', and the kimchi is matured through temperature control in the storage chambers 4 and 4'. Long term storage will be performed.

In this case, the temperature control in the storage chambers 4 and 4 'is performed by supplying cold air by operating a control program preset in a microcomputer (not shown) connected to the display control unit 13.

On the other hand, as is well known, the compressor 5, the condenser 6 and the evaporators 7, 7 'each form a closed loop by refrigerant piping, which is called a cooling system.

Here, the kimchi storage having the plurality of storage chambers 4 and 4 'as described above includes first and second evaporators 7 and 7' for supplying cold air to the respective rooms. 7 ') is provided with a solenoid valve 12 for smoothly supplying by adjusting the flow rate of the refrigerant supplied to.

At this time, the solenoid valve 12 is a kind of on-off valve while the refrigerant flow is maintained when opening while the refrigerant flow is blocked.

In addition, the refrigerant pipe connecting the outlet of the condenser 6 and the inlet of the evaporator 7, 7 ′ has a flow path of the refrigerant so that the refrigerant can be evaporated smoothly in the evaporator 7, 7 ′. Very narrow capillaries (9, 9 '; commonly called capillary tubes) are provided.

In addition, between the outlets of the evaporators 7 and 7 'and the inlet of the compressor 5, a refrigerant pipe called suction pipe 11, 11' is provided, and the storage chambers 4 and 4 ' It is connected through the base cover 10 that partitions between the machine room (3).

As such, a schematic view of a conventional cooling system equipped with the first and second evaporators 7 and 7 ′ shows a capillary tube 9, 9 at the inlet side of the plurality of first and second evaporators 7 and 7 ′. ') Are arranged and connected to each other, and when the cooling system is operated while the solenoid valve 12 for controlling the refrigerant flow to the capillaries 9 and 9' is provided, the refrigerant is circulated.

That is, the gas refrigerant compressed at high temperature and high pressure in the compressor 5 is exchanged with the ambient air in the condenser 6 to be converted into a liquid refrigerant of medium temperature and high pressure higher than room temperature, and then the first evaporator 7 or the first The solenoid valve 12 is selectively opened depending on whether the evaporator 7 'is operated.

For example, when only the first evaporator 7 is operated, the flow path of the solenoid valve 17 directed toward the second evaporator 7 'is closed and the solenoid valve 12 directed toward the first evaporator 7 is closed. The flow path is open.

As a result, the high pressure liquid refrigerant flows into the capillary tube 9 through the solenoid valve 12 and changes into a medium temperature and low pressure liquid refrigerant.

Next, the liquid refrigerant changed into the medium temperature and the low pressure flows into the first evaporator 7 and vaporizes through heat exchange with the ambient air. At this time, the storage compartment 4 is cooled by the heat of vaporization of the refrigerant absorbed.

Meanwhile, the gaseous refrigerant having passed through the first evaporator 7 is introduced into the compressor 5 through the suction pipe 11 and compressed at high pressure, and then circulated again in the above-described cycle.

However, as described above, since the suction pipe 11 is a refrigerant pipe through which the low-temperature / low-pressure gas refrigerant evaporated through heat exchange in the first evaporator 7 flows into the compressor 5, the first evaporator 7 The refrigerant exiting the outlet and passing through the suction pipe 11 forms a relatively cold state below room temperature.

As a result, as the refrigerant temperature flowing into the compressor 5 is low, the inlet temperature of the compressor 5 is lowered, resulting in a decrease in the compression ratio and efficiency of the compressor 5, thereby lowering the reliability of the compressor 5. There was a problem.

In general, the inlet temperature of the compressor (5) is currently recommended because it is preferable to maintain a room temperature state, and thus the refrigerant exiting toward the outlet of the first and second evaporators (7,7 ') In order to prevent the temperature from dropping below a certain level, the first and second evaporators (7,7 ') are used in a state where the efficiency of the first and second evaporators (7,7') is not maximized. to be.

In addition, when the refrigerant in the suction pipes 11 and 11 'is introduced into the compressor 5 after being present in a liquid state rather than a gas state, there is a problem that the compressor 5 may be damaged.

Therefore, in the related art, an accumulator (not shown) is provided between the outlets of the first and second evaporators 7 and 7 'and the inlet of the compressor 5 to prevent the liquid refrigerant from entering the compressor 5 as much as possible. Doing.

Meanwhile, as described above, the refrigerant flowing into the inlets of the first and second evaporators 7 and 7 ', that is, the refrigerant passing through the capillaries 9 and 9', passes through the condenser 6 and is relatively high in temperature. (Medium temperature state relatively lower than the temperature in the high-pressure high-pressure compressor 5) is taken.

Therefore, in the conventional kimchi storage, a certain length of the suction pipes 11 and 11 'at the outlets of the first and second evaporators 7 and 7' are respectively wound with capillaries 9 and 9 'to secure the contact area as wide as possible. Heat transfer from the capillary tubes 9 and 9 'to the suction pipes 11 and 11' results in the evaporation of the liquid refrigerant remaining in the suction pipes 11 and 11 '. In order to maintain the inlet temperature as close as possible to room temperature has been proposed and used.

However, in the kimchi storage having such a structure, as shown in FIG. 3, when the plurality of suction pipes 11 and 11 'are conventionally connected through the storage chambers 4 and 4' toward the machine room 3, As described above, one through hole 14 is formed on the base cover 10 in the upper part of the machine room 3, and the plurality of suction pipes 11 and 11 ′ are connected through the one through hole 14. I was trying to.

And, in order to maintain the airtight between the suction pipe (11, 11 ') and the through hole 14, the rubber packing (15) is fitted on the suction pipe (11, 11'). By blocking the through-holes 14, the foaming liquid was prevented from leaking through the through-holes 14 in the process of foam molding in the kimchi storage.

However, according to the conventional structure, the plurality of suction pipes 11 and 11 'are drawn out through one through hole 14, so that the suction pipes 11 and 11' are first and second evaporators 7. When the suction pipes 11 and 11 'are not carefully examined, each of the capillary tubes 9 and 9' corresponding to each of the suction pipes 11 and 11 'is wound. The carelessness of the capillaries (9,9 ') could cause them to be wound up interchangeably.

In addition, after the rubber packing 15 is inserted into the suction pipes 11 and 11 ′ according to the related art, the work itself of inserting the rubber packing 15 into the through hole 14 for sealing the through hole 14 is cumbersome. There was a disadvantage of poor productivity and productivity.

The present invention has been made to solve the above problems, an object of the present invention is to provide a through-hole formed on the base cover to connect the suction pipe of each evaporator outlet side provided in the plurality of storage chambers to the machine room. A plurality of separation pipes may be formed to correspond to the suction pipes, and through holes may be formed in a groove shape wider than the cross-sectional area of the suction pipes, so that capillaries wound around the exit suction pipes of each evaporator may be prevented from being incorrectly assembled. In addition, to provide the evaporator outlet through-hole structure of the kimchi storage to improve the workability as the foam liquid enters into the groove-shaped through hole during the internal foaming operation of the kimchi storage, and naturally becomes a sealing (sealing).

In order to achieve the above object, the present invention is connected to the compressor provided in the machine room through the through-hole formed on the base cover of the upper part of the machine room, the suction pipe of the outlet side of the first and second evaporators disposed respectively in the plurality of storage chambers; In addition, Kimchi storage having a refrigerant pipe connection structure in contact with the capillary connected to the condenser, the through-hole formed on the base cover is formed into a plurality of separation to correspond to each suction pipe; The through hole is achieved by providing an evaporator outlet through hole structure of the kimchi storage, characterized in that formed in the groove shape wider than the cross-sectional area of the suction pipe.

Hereinafter, with reference to the accompanying drawings will be described in detail a preferred embodiment of the present invention.

Figure 4 is a view schematically showing the internal configuration of the kimchi storage according to the present invention, Figure 5 and Figure 6 is an enlarged perspective view of the main portion showing a state in which a through hole is formed on the base cover according to the present invention.

At this time, the configuration state of the kimchi storage except for the features of the technical configuration according to the present invention is the same as in the prior art, the general configuration and operation state of the kimchi storage cited the prior art as it is or omitted the specific details except the characteristic configuration of the present invention The same name and the same code | symbol are attached | subjected about the same structure as before.

That is, as shown in the accompanying drawings, the kimchi storage according to the present invention, the machine room 3, the compressor 5, the condenser 6, etc. constituting the refrigeration cycle is disposed, and the first and second of the refrigeration cycle It has the main body 1 in which the some storage chamber 4 and 4 'which the evaporators 7 and 7' enclose is formed.

At this time, the first and second evaporators (7, 7 ') are communicated with the compressor (5) and the condenser (6) arranged in the machine room (3) by the refrigerant pipe so that the refrigerant can circulate.

As described in the related art, a refrigerant pipe, called suction pipes 11 and 11 ', is provided between the outlets of the evaporators 7 and 7' and the inlet of the compressor 5. It is connected through the base cover 10 partitioning between the (4, 4 ') and the machine room (3).

Herein, in the structure in which the suction pipes 11 and 11 'are connected to the base cover 10, the suction pipes 11 and 11' of the through holes 14 and 14 'are penetrated. Its characteristics are that it changes the shape structure and arrangement structure differently from the prior art.

That is, as shown in FIGS. 4 to 6, the present invention includes a plurality of through holes 14 and 14 ′ corresponding to the plurality of suction pipes 11 and 11 ′ on the base cover 10, respectively. Its features are in forming.

As described above, when the plurality of through holes 14 and 14 ′ are formed on the base cover 10, the positions of the first and second evaporators 7 and 7 ′ (that is, the left and right storage compartments 4) are formed. , 4 '), the through holes 14 and 14' are disposed in the left and right directions of the base cover 10, and thus are connected to the first and second evaporators 7 and 7 '. The suction pipes 11 and 11 'may be connected to the machine room 3 through the through holes 14 and 14' corresponding to their respective positions.

Therefore, when the operator checks only the positions of the suction pipes 11 and 11 'which are respectively penetrated along the left and right through holes 14 and 14', the operator is connected to the outlets of the first and second evaporators 7 and 7 ', respectively. It is possible to determine the exact position of the suction pipes 11 and 11 'so that the respective capillaries 9 and 9' corresponding to the first and second evaporators 7 and 7 'are precisely attached to the suction pipes 11 and 11'. I can wind it up.

As a result, the mistake of winding the capillary tubes 9 and 9 'as mentioned in the prior art to the suction pipes 11 and 11' can be prevented in advance.

Meanwhile, as shown in FIGS. 5 and 6, in the present invention, the through holes 14 and 14 ′ respectively formed on the base cover 10 have grooves wider than the cross-sectional areas of the suction pipes 11 and 11 ′. It is characterized in that it is formed to be stepped downward in the machine room 3 direction while having a shape.

As such, when each of the through holes 14 and 14 'is formed in a groove shape wider than the cross-sectional area of the suction pipes 11 and 11', the suction pipes 11 and 11 'are formed through the through holes 14 and 14'. In the through-connected state through ') when performing the operation of foam-molding an insulating material such as urethane foam to insulate the outer circumferential surface of the storage compartment (4,4') as shown in the prior art, the groove-shaped through hole ( 14,14 ') and the foam liquid is filled into the grooves to naturally seal (sealing).

Therefore, there is no need to perform a work such as sealing the through hole 14 with a separate rubber packing 15 as in the prior art will have an effect that can greatly improve the workability.

In the above-described embodiment, the top-opening kimchi storage is described as an example, but this is only one preferred embodiment, and the idea of the present invention can be sufficiently applied to the top-opening kimchi storage, as well as the mixed and draw-out kimchi storage. It is self-evident.

As described above, according to the present invention, by providing a plurality of through holes on the base cover to clearly determine the position of the suction pipe corresponding to the first and second evaporators, heat transfer from the capillary to the suction pipe is performed. In order to prevent the mistake of reversing the position of each capillary tube corresponding to each suction pipe in the process of winding the capillary tube to each suction pipe in advance.

In addition, the present invention by forming the through-hole stepped downward in the machine room direction in the form of a groove larger than the cross-sectional area of the suction pipe, the through-hole in the process of foam molding the heat insulating material such as urethane foam to insulate the outer peripheral surface of the storage compartment As the foam liquid fills the inside and has a sealing structure, the work can be greatly improved because the sealing is achieved by a relatively simple structure without using a separate member such as rubber packing as in the prior art. It has an effect.

Claims (1)

The suction pipe connection structure of the suction pipes of the outlets of the first and second evaporators respectively disposed in the plurality of storage chambers is connected to the compressor provided in the machine room through a through hole formed on the base cover of the upper part of the machine room and to contact the capillary tube connected to the condenser. In kimchi storage having,   A plurality of through-holes formed on the base cover are separately formed to correspond to the respective suction pipes; The through-hole evaporator outlet through-hole structure of the kimchi storage, characterized in that formed in the groove shape wider than the cross-sectional area of the suction pipe.

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