KR20140064457A - Refrigerant gas distribution apparatus of drum type an ice making machine - Google Patents

Abstract

The present invention relates to a refrigerant distribution apparatus of a drum-type ice making machine forming a refrigeration cycle by comprising a compressor (100), a condenser (200), a refrigerant supply pipe (300), and a refrigerant recovery pipe (400), wherein the refrigerant distribution apparatus includes: a first branch supply pipe (S1) branching off from the refrigerant supply pipe (300); an evaporator (E) connected to the end of the first branch supply pipe (S1), and installed in an ice storage chamber (A); a first branch recovery pipe (R1) transferring the refrigerant to the refrigerant recovery pipe (400) after recovering the refrigerant evaporated through the evaporator (E), and formed into a venturi connected to the refrigerant recovery pipe (400); a second branch supply pipe (S2) branching off from the refrigerant supply pipe (300) passing the first branch supply pipe (S1); refrigerant nozzles (N) installed on the respective pipelines of the second branch supply pipe (S2), arranged inside an ice making drum (D), and cooling the ice making drum (D) by spraying and evaporating the refrigerant; and a second branch recovery pipe (R2) transferring the refrigerant to the refrigerant recovery pipe (400) after recovering the refrigerant sprayed from the refrigerant nozzles (N). According to the present invention, ice stored in the ice storage chamber can be kept for a long time, the cooling efficiency of the drum-type ice making machine can be improved, the nozzles can be prevented from being clogged, and manufacturing costs can be reduced.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a refrigerant dispensing apparatus for a drum type ice maker,

[0001] The present invention relates to a refrigerant dispensing apparatus for a drum type ice maker, and more particularly, to a refrigerant dispensing apparatus for a drum type ice maker, To a refrigerant dispensing apparatus for a drum-type ice maker which can store snow ice produced for a long time for a long time.

In general, the drum type ice maker is provided with a cylindrical ice maker drum rotatably installed inside the ice maker tank, water in which a part of the ice maker drum is immersed is stored in the ice maker tank, And the ice-making drum is rotated to grow layered ice on the surface of the ice-making drum.

Further, the ice-making tank is provided with a cutter close to the surface of the ice-making drum, so that ice on the rotating ice-making drum is removed and discharged to the ice-bingo.

The refrigerant of the drum-type ice-maker is supplied from a refrigerant circulation system connected to the compressor, the condenser and the expansion valve by a refrigerant pipe to a cooling nozzle device installed in the ice-making drum, and is sprayed.

Such a drum type ice maker is disclosed in, for example, JP-A-1993-0000306 and JP-A-2006-0059632. However, the former has a problem of heat transfer efficiency and the latter has a disadvantage that a uniform ice- The Applicant has thus made the registered patent No. 0821558 a right-handled technology.

The applicant of the present invention has also made a right of Patent Application No. 0878589 in which the drum structure is improved so as to increase the icing efficiency of the drum type ice maker.

In addition, as another example, Patent No. 0809928, No. 0825980, No. 1999-0022144, etc. are also disclosed.

In this drum type ice maker, as shown in FIG. 1, a high temperature and high pressure refrigerant gas compressed by a compressor is sent to a condenser, and air is forcedly circulated by a pan motor to cool the refrigerant, thereby liquefying the refrigerant into a saturated liquid. After being separated into a complete saturated liquid, the saturated liquid refrigerant passes through the pores of the heat exchanger and the expansion valve, and the pressure is lowered to become the wetted vapor in the saturated liquid. A cooling effect is exhibited by absorbing the surrounding heat in the process of becoming steam, and the dry saturated steam is sent back to the compressor to continue the circulation of the refrigerant, thereby performing the cooling action. In the refrigeration cycle of Patent No. 0809928 .

Then, the ice produced through the ice maker, such as snow-type ice or powder ice, is stored in a low-bingo area below the ice-making drum.

However, in the conventional drum type ice maker, since the ice stored in the ice bingo can not be stored for a long time, it melts in a short period of time or is rapidly hardened, resulting in deterioration of the product.

However, in order to cool the bingo, a separate cooling system must be constructed, which is costly, inefficient, and has a disadvantage in that the volume and weight of the product are increased and the competitiveness is weakened.

SUMMARY OF THE INVENTION The present invention has been made in view of the above-mentioned problems in the prior art, and it is an object of the present invention to provide a refrigerator which is branched into two refrigerant tubes, The present invention provides a refrigerant dispensing apparatus for a drum type ice maker.

The present invention provides a drum type ice maker comprising a compressor (100), a condenser (200), a refrigerant supply pipe (300), and a refrigerant recovery pipe (400) A first branch supply pipe S1 branched from the refrigerant supply pipe 300; An evaporator (E) connected to an end of the first branch supply pipe (S1) and provided in the lower bingo (A); A first branch recovery pipe (R1) connected to the refrigerant recovery pipe (400) in a venturi form to recover refrigerant vaporized through the evaporator (E) and return to the refrigerant recovery pipe (400); A second branch supply pipe S2 branched from the refrigerant supply pipe 300 passing through the first branch supply pipe S1; A coolant spray nozzle N installed on each pipe of the second branch supply pipe S2 and disposed inside the ice-making drum D to atomize the coolant to cool the ice-making drum D; And a second branch recovery pipe (R2) for recovering the refrigerant sprayed from the refrigerant spray nozzle (N) and transferring the recovered refrigerant to the refrigerant recovery pipe (400). do.

The directional valve (V) further comprises a direction switching valve (V) for connecting the second branch supply pipe (S2) and the second branch return pipe (R2) to switch the flow of the refrigerant in the reverse direction, It is also a four-way valve.

Further, the refrigerant supply pipe 300 between the condenser 200 and the first branch supply pipe S1 is further provided with a replaceable metal mesh filter F.

According to the present invention, it is possible to maintain the ice stored in the low bingo for a long time, to improve the cooling efficiency of the drum type ice maker, to prevent the nozzle clogging, and to reduce the manufacturing cost.

FIG. 1 is an exemplary view showing a refrigeration cycle implemented in a general drum type ice maker.
2 is a view illustrating an example of a refrigeration cycle implemented in a drum type ice maker according to an embodiment of the present invention.
3 is a view illustrating a refrigeration cycle implemented in a drum type ice maker according to another embodiment of the present invention.

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

Before describing the present invention, the following specific structural or functional descriptions are merely illustrative for the purpose of describing an embodiment according to the concept of the present invention, and embodiments according to the concept of the present invention may be embodied in various forms, And should not be construed as limited to the embodiments described herein.

In addition, since the embodiments according to the concept of the present invention can make various changes and have various forms, specific embodiments are illustrated in the drawings and described in detail herein. However, it should be understood that the embodiments according to the concept of the present invention are not intended to limit the present invention to specific modes of operation, but include all modifications, equivalents and alternatives falling within the spirit and scope of the present invention.

As shown in FIG. 2, the drum type ice maker according to the embodiment of the present invention has a type of composite refrigeration cycle structure.

In the present invention, the compressor 100, the condenser 200 as a condenser, and the refrigerant supply pipe 300 and the refrigerant recovery pipe 400 for constituting a closed circuit through which the refrigerant flows, .

In addition, portions not specifically described generally follow the well-known refrigeration cycle structure and function.

In the illustrated example, the low bingo A and the ice-making drum D are schematically shown for the convenience of explanation. In fact, the low-bingo (A) evaporator E for cooling is located inside the low- And the refrigerant tube for cooling the ice-making drum (D) is installed so as to be in and out in the axial direction of the side of the ice-making drum (D) so as to be smoothly rotated without being interfered when the ice-making drum (D) , And briefly schematized to explain the concept of the present invention.

The refrigeration cycle according to an embodiment of the present invention further includes a first branch supply pipe S1 and a second branch supply pipe S2 branched from the refrigerant supply pipe 300 at the rear end of the condenser 200 as shown in the figure.

The first and second branch supply pipes S1 and S2 are connected to the evaporator E installed in the low bingo pot A and the ice making drum D. The first branch supply pipe S1 is connected to the evaporator E- (E), and the second branch supply pipe (S2) is connected to cool the ice-making drum (D) through the coolant injection nozzle (N).

Particularly, in the ice making drum D, the refrigerant is injected (actually, the concept of spraying) through the coolant injection nozzle N and is vaporized. At this time, the evaporation latent heat is taken away to cool the surface of the ice-

Since the dual cooling structure capable of simultaneously cooling the low bingo (A) and the cooling drum (D) using one refrigeration cycle is provided, the present invention provides a long ice keeping effect of the produced ice which can not be obtained by the conventional drum type ice maker .

After the refrigerant having passed through the evaporator E is heat-exchanged, the refrigerant is recovered to the refrigerant recovery pipe 400 by the first branch recovery pipe R1. The refrigerant sprayed through the refrigerant injection nozzle N is heat- The refrigerant is recovered to the refrigerant recovery pipe 400 by the second branch recovery pipe R2 and sucked into the compressor 100. [

In this case, it is very important in the present invention that the first branch recovery pipe R1 is connected to the refrigerant recovery pipe 400 so as to have a venturi structure, and the refrigerant pressure on the side of the second branch supply pipe S2 Is always maintained to be greater than the refrigerant pressure on the side of the first branch supply pipe (S1), so that the refrigerant recovered through the first branch recovery pipe (R1) is smoothly and smoothly And is sucked naturally into the refrigerant flowing through the pipeline of the second branch recovery pipe R2, which is recovered, and is recovered.

To this end, the number of the coolant injection nozzles N provided on the second branch supply pipe S2 and the number of the injection holes may be adjusted.

That is, the refrigerant pressure on the side of the second branch supply pipe (S2) must be always larger than the pressure of the refrigerant on the side of the first branch supply pipe (S1).

In addition, if the metal mesh filter (F) is further provided on the refrigerant supply pipe (300) before the branching, the fine metal powder caused by the piston and the inner wall of the cylinder can be filtered during operation of the compressor (100) Can be minimized.

In addition, as in the other embodiment of Fig. 3, the nozzle clogging phenomenon can be completely prevented.

3, in the case of the second branch supply pipe S2 having the coolant injection nozzle N, it is possible to switch the direction of the flow of the coolant through the direction switching valve V At this time, the directional valve V2 is preferably a four-way valve.

At this time, since the first branch supply pipe S1 does not use any nozzles but uses the evaporator E, the metal mesh filter F is sufficient and is not related to nozzle clogging. However, It is very important to add a means for solving nozzle clogging at this portion because the refrigerant injection nozzle N performs the function of the evaporator at the same time.

When the directional valve V is operated to change the direction of the refrigerant flow when the nozzle clogging phenomenon of the refrigerant jetting nozzle N occurs, the refrigerant jetting nozzle N moves to the refrigerant pressure pushed in the reverse direction The fine metal powder or the like is separated and separated from the nozzle bore, thereby preventing the clogging of the nozzle.

In this case, if the control unit periodically controls the direction switching operation of the directional valve V, the clogging due to the nozzle reverse injection is eliminated periodically, so that the nozzle replacement period can be extended and maintenance is easy And can reduce costs.

3, the connection structure of the first branch recovery pipe R1 with the refrigerant recovery pipe 400 has a venturi structure as in the embodiment of FIG.

100: compressor 200: condenser
300: Refrigerant supply pipe 400: Refrigerant recovery pipe

Claims (3)

1. A drum type ice maker comprising a compressor (100), a condenser (200), a refrigerant supply pipe (300), and a refrigerant recovery pipe (400)
A first branch supply pipe S1 branched from the refrigerant supply pipe 300;
An evaporator (E) connected to an end of the first branch supply pipe (S1) and provided in the lower bingo (A);
A first branch recovery pipe (R1) connected to the refrigerant recovery pipe (400) in a venturi form to recover refrigerant vaporized through the evaporator (E) and return to the refrigerant recovery pipe (400);
A second branch supply pipe S2 branched from the refrigerant supply pipe 300 passing through the first branch supply pipe S1;
A coolant spray nozzle N installed on each pipe of the second branch supply pipe S2 and disposed inside the ice-making drum D to atomize the coolant to cool the ice-making drum D;
And a second branch recovery pipe (R2) for recovering the refrigerant sprayed from the refrigerant spray nozzle (N) and transferring the recovered refrigerant to the refrigerant recovery pipe (400).
The method of claim 1,
And a direction switching valve (V) for connecting the second branch supply pipe (S2) and the second branch return pipe (R2) to switch the flow of the refrigerant in a reverse direction, wherein the direction switching valve (V) Wherein the refrigerant is supplied to the refrigerant circulation passage.
The method of claim 1,
Wherein the refrigerant supply pipe (300) between the condenser (200) and the first branch supply pipe (S1) is further provided with a replaceable metal mesh filter (F).

Images