KR102555425B1 - Defrosting cycle apparatus for evaporator of refrigerating cycle - Google Patents

Abstract

As the defrost cycle device for the evaporator of the disclosed refrigeration cycle includes a defrost expansion valve, a defrost evaporator, a defrost compressor, and a defrost condenser, it is possible to remove frost formed on the main evaporator by the heat generated by the defrost condenser, so that a separate There is an advantage in that defrosting of the main evaporator can be performed efficiently without the provision of a defrosting heater.

Description

Defrosting cycle apparatus for evaporator of refrigerating cycle}

The present invention relates to a defrost cycle device for an evaporator of a refrigeration cycle.

The refrigerating cycle includes an evaporator, a compressor, a condenser, and an expansion valve, so that the refrigerant can move heat from a low-temperature space to a high-temperature space while repeating the process of sequentially evaporating, compressing, condensing, and expanding the refrigerant.

During the operation of this refrigeration cycle, water vapor in the air is condensed and frozen in the evaporator and deposited in the form of frost. Since this frost causes the operation efficiency of the evaporator to decrease, the frost of the evaporator is reduced through defrosting. should be removed

What can be presented as an example of defrosting for the evaporator is that of the patent document presented below.

However, conventionally, a defrost heater that performs defrost by generating heat mainly by electric energy has been used for defrosting the evaporator, but the defrost by the defrost heater has a problem of low operating efficiency.

Utility Model Registration No. 20-0086716, registration date: 1995.03.30., name of design: evaporator with defrost heater

An object of the present invention is to provide a defrost cycle device for an evaporator of a refrigeration cycle so that defrost for the evaporator constituting the refrigeration cycle can be made efficiently without the provision of a defrost heater.

A defrost cycle device for an evaporator of a refrigerating cycle according to an aspect of the present invention is applied to a main refrigerating cycle having a main evaporator, a main compressor, a main condenser, and a main expansion valve,

a defrost expansion valve for expanding the refrigerant for defrosting; a defrost evaporator evaporating the defrost refrigerant expanded by the defrost expansion valve; a defrost compressor for compressing the refrigerant for defrosting evaporated in the defrost evaporator; And a defrost condenser for condensing the refrigerant for defrosting compressed by the defrosting compressor;

The defrost condenser is provided in the main evaporator so that defrosting for the main evaporator can be performed,
The defrost condensation pipe constituting the defrost condenser is disposed in a form surrounded by the main evaporation pipe constituting the main evaporator,
The defrost condensation pipe is formed on one side of the inside of the pipe body and the pipe body to redirect a portion of the refrigerant for defrosting flowing through the defrost condensation pipe from one side of the inside of the pipe body to the other side A direction changer and a direction changer formed on the other side of the inside of the pipe body so as to face the direction changer, and the refrigerant for defrosting is changed by the direction changer and flows to the other side of the inside of the pipe body. A reflux part for returning back to the front of the direction conversion part among one side of the inside of the tube body,
The direction conversion unit is convexly protruded from one side of the inside of the tube body to a predetermined height, and an inclined surface for converting the direction of the refrigerant for defrosting from one side of the inside of the tube body to the other side of the inside of the tube body The inclined surface forming protrusion to be formed, and the defrosting refrigerant protruding from the top of the inclined surface forming protrusion toward the other side of the inside of the tube body in the form of a plate of a predetermined width, and the defrosting refrigerant converted in direction by the inclined surface forming protrusion is described above. An inclined surface extension plate that guides the flow to the other side of the inside of the pipe body, a surface corresponding to the front side of the inclined surface forming protrusion of one side of the inside of the pipe body, the front surface of the inclined surface forming protrusion and the inclined surface extension A reflux receiving hole formed in the shape of a curved surface recessed to a predetermined depth formed on the front surface of the plate so that the refluxed refrigerant of the defrost refrigerant flows along one side of the inside of the tube body, and , Some of the refrigerant for defrosting rising along the inclined surface forming protrusion passing through the inclined surface forming protrusion so that the back surface of the inclined surface forming protrusion communicates with the reflux receiving hole is bypassed and introduced into the reflux receiving hole Including a bypass pipe,
The reflux part is formed in a curved shape that is recessed with a predetermined curvature outward from a portion facing the distal end of the inclined surface extension plate of the other side surface of the inside of the pipe body along one side of the inside of the pipe body of the refrigerant for defrosting. A mixed flow induction curved surface that flows along one side of the inside of the pipe body and the other of the refrigerant for defrosting and then changed in direction by the inclined surface extension plate mixes with each other and flows, and extends from the mixed flow induction curved surface and a reflux reversal curved body that is curved with a predetermined curvature toward the reflux receiving hole and changes direction so that the mixed refrigerant for defrosting while flowing along the mixed flow inducing curved surface is refluxed toward the reflux receiving hole, and the direction by the reflux reversing curved surface Including an upwardly inclined body that allows some of the converted refrigerant for defrosting to flow along the central portion of the inside of the tube body so that it is separated from the reflux reversal curved body and gradually upward without facing the reflux receiving hole and then gradually upward. to be characterized

According to the defrost cycle device for the evaporator of the refrigeration cycle according to an aspect of the present invention, as the defrost cycle device for the evaporator of the refrigeration cycle includes a defrost expansion valve, a defrost evaporator, a defrost compressor and a defrost condenser, by the defrost condenser Frost formed on the main evaporator can be removed by heat, and there is an effect that defrosting of the main evaporator can be efficiently performed without a separate defrosting heater.

1 is a view showing the configuration of a defrost cycle device for an evaporator of a refrigeration cycle according to an embodiment of the present invention.
Figure 2 is a view showing the arrangement of the defrost condenser constituting the defrost condenser constituting the defrost cycle device for the evaporator of the refrigeration cycle according to an embodiment of the present invention and the main evaporation pipe constituting the main evaporator.
Figure 3 is an enlarged cross-sectional view of a portion of the defrost condensation pipe constituting the defrost cycle device for the evaporator of the refrigeration cycle according to another embodiment of the present invention.

Hereinafter, a defrost cycle device for an evaporator of a refrigerating cycle according to embodiments of the present invention will be described with reference to the drawings.

1 is a view showing the configuration of a defrost cycle device for an evaporator of a refrigerating cycle according to an embodiment of the present invention, Figure 2 is a defrost condenser constituting a defrost cycle device for an evaporator of a refrigeration cycle according to an embodiment of the present invention It is a view showing the arrangement of the defrost condensation pipe constituting and the main evaporation pipe constituting the main evaporator.

1 and 2 together, the defrost cycle device 100 for the evaporator of the refrigeration cycle according to the present embodiment includes a main evaporator 20, a main compressor 30, a main condenser 40 and a main expansion valve 50 ) As applied to the main refrigeration cycle 10 having a defrost expansion valve 140, a defrost evaporator 110, a defrost compressor 120 and a defrost condenser 130.

The main refrigerating cycle 10 is installed in a part requiring refrigeration, refrigeration, etc. by the main refrigerating cycle 10, such as a refrigerator, the defrost expansion valve 140, the defrost evaporator 110, and the defrost compressor. 120 and the defrost condenser 130 constitute a defrost cycle independent of the main refrigeration cycle 10, and the main refrigerant circulating in the main refrigeration cycle 10 is a defrost refrigerant circulating in the defrost cycle. They do not mix with each other and circulate independently of each other.

The defrosting expansion valve 140 expands the refrigerant for defrosting.

The defrost evaporator 110 evaporates the refrigerant for defrost expanded by the defrost expansion valve 140 .

The defrosting compressor 120 compresses the refrigerant for defrosting evaporated in the defrosting evaporator 110 .

The defrosting condenser 130 condenses the refrigerant for defrosting compressed in the defrosting compressor 120 .

In this embodiment, the defrost condenser 130 is provided in the main evaporator 20 so that defrosting can be performed on the main evaporator 20 . Then, even if frost is generated on the main evaporator 20 during the operation of the main refrigerating cycle 10, the frost formed on the main evaporator 20 can be removed by heat from the defrost condenser 130 , Defrosting of the main evaporator 20 can be efficiently performed without a separate defrosting heater.

In this embodiment, as shown in FIG. 2, the defrost condensation tube 131 constituting the defrost condenser 130 is disposed in a form surrounded by the main evaporation tube 22 constituting the main evaporator 20. do.

The main evaporator 20 includes the main evaporation tube 22 formed in a zigzag shape by bending a plurality of tubes communicating with one another, and a main fixing panel 21 for fixing the bent parts of the main evaporation tube 22. ).

The defrost condensation tube 131 is formed in a zigzag shape by bending a plurality of tubes in communication with each other, and the tubes spaced apart from each other of the main evaporation tube 22 in the space between the tubes spaced apart from each other of the main evaporation tube 22 While spaced apart from each other, the main evaporation tube 22 is disposed in a form surrounded by spaced tubes.

When configured as described above, the heat of the defrost condensation tube 131 can be evenly spread to the tubes spaced apart from each other of the main evaporation tube 22 around them, so that the defrosting efficiency can be further improved.

Meanwhile, the defrost evaporator 110 is provided in a storage compartment requiring at least one of freezing and refrigeration, so that at least one of freezing and refrigeration may be performed for the storage compartment by the defrost evaporator 110 .

Here, the storage compartment may be a separate and independent space distinguished from the part where the main refrigeration ice is installed, and accordingly, according to the operation of the defrost cycle by the defrost cycle device 100 for the evaporator of the refrigerating cycle, the main With the defrosting of the main evaporator 20 constituting the refrigerating cycle 10, a secondary evaporation function for the separate storage compartment can be implemented.

As described above, as the defrost cycle device 100 for the evaporator of the refrigeration cycle includes the defrost expansion valve 140, the defrost evaporator 110, the defrost compressor 120 and the defrost condenser 130, Frost formed on the main evaporator 20 can be removed by heat from the defrost condenser 130, so that defrosting of the main evaporator 20 can be efficiently performed without a separate defrost heater. .

Hereinafter, a defrost cycle device for an evaporator of a refrigerating cycle according to another embodiment of the present invention will be described with reference to the drawings. In performing this description, descriptions overlapping with those already described in the above-described embodiment of the present invention are replaced therewith, and will be omitted here.

Figure 3 is an enlarged cross-sectional view of a portion of the defrost condensation pipe constituting the defrost cycle device for the evaporator of the refrigeration cycle according to another embodiment of the present invention.

Referring to FIG. 3 , in this embodiment, the defrost condensation pipe 231 constituting the defrost condenser is formed on a pipe body 232 and one side of the inside of the pipe body 232 to form the defrost condensation pipe 231 ) and a direction changing unit 255 for converting a portion of the refrigerant for defrosting flowing through the direction from one side of the inside of the pipe body 232 to the other side, and on the other side of the inside of the pipe body 232 The defrosting refrigerant that is formed to face the direction conversion unit 255 and is changed in direction by the direction conversion unit 255 and flows to the other side of the inside of the tube body 232 is transferred to the tube body 232. The front side of the direction conversion unit 255 of one side of the inside (based on the flow direction of the defrosting refrigerant, the defrosting refrigerant entering the direction conversion unit 255 is scheduled to arrive after a predetermined time side, hereinafter the same) includes a reflux unit 250 for refluxing again.

A plurality of direction changing parts 255 are continuously formed so as to be spaced apart from each other on one side of the inside of the pipe body 232, and the reflux part 250 is formed on the other side of the inside of the pipe body 232. A plurality of them are continuously formed so as to be spaced apart.

The direction conversion unit 255 protrudes convexly from one side of the inside of the tube body 232 to a predetermined height, and moves from one side of the inside of the tube body 232 to the other side of the inside of the tube body 232. an inclined surface forming protrusion 256 forming an inclined surface for converting the direction of the refrigerant for defrosting toward the inclined surface, and a predetermined area from the upper part of the inclined surface forming protrusion 256 toward the other side surface of the inside of the tube body 232. An inclined surface extension plate 257 protruding in the form of a plate and inducing the defrosting refrigerant converted by the inclined surface forming protrusion 256 to flow to the other side of the inside of the tube body 232; Formed on the front side of the inclined surface forming protrusion 256 of one side of the inside of the body 232, the front surface of the inclined surface forming protrusion 256 and the front surface of the inclined surface extension plate 257 A reflux receiving hole 258 formed in a curved shape depressed to a predetermined depth to change the direction of the defrost refrigerant refluxed by the reflux part 250 so that it flows along one side of the inside of the tube body 232 ), and the rear surface (inclined surface) of the inclined surface forming protrusion 256 and the reflux receiving hole 258 pass through the inclined surface forming protrusion 256 and rise along the inclined surface forming protrusion 256 It includes a bypass pipe 259 through which some of the refrigerant for defrosting is bypassed and introduced into the reflux receiving hole 258 .

The upper surface of the inclined surface forming protrusion 256 and the inclined surface extension plate 257 are formed to form an inclined surface smoothly connected to each other without a step, so that the refrigerant for defrosting flows along one side of the inside of the tube body 232. It can be guided to flow toward the other side of the inside of the tube body 232 along the upper surface of the inclined surface forming protrusion 256 and the inclined surface extension plate 257.

The reflux part 250 is formed in the form of a curved surface recessed with a predetermined curvature outward from a portion facing the distal end of the inclined surface extension plate 257 among the other side surfaces of the inside of the pipe body 232, Except for flowing along one side of the inside of the pipe body 232 (of the refrigerant for defrosting, which flows along the other side of the inside of the pipe body 232 and the refrigerant for defrosting, the pipe body 232 ) and the refrigerant for defrosting flowed along one side of the inside of the tube body 232 and then changed in direction by the inclined surface extension plate 257 so that they flow while being mixed with each other A mixed flow induction curved body 251 that

The refrigerant for defrosting, which extends from the mixed flow inducing curved surface 251 and is curved with a predetermined curvature toward the reflux receiving hole 258 and flows along the mixed flow inducing curved surface 251, is mixed with the refrigerant for defrosting through the reflux receiving hole 258. A reflux inversion curved body 252 that changes direction so that it refluxes toward the side;

Some of the defrosting refrigerant converted by the reflux reversal curved body 252 is not directed toward the reflux receiving hole 258 but is separated from the reflux reversing curved body 252 and gradually upward (of the tube body 232). It includes an upward sloped body 253 that flows along the central portion of the inside of the pipe body 232 so as to gradually move away from one side of the inside and then gradually upward.

When configured as described above, the defrost refrigerant flowing along one side of the inside of the tube body 232 is incident on the inclined surface forming protrusion 256, and the inclined surface forming protrusion 256 and the inclined surface While sequentially passing through the extension plate 257, the direction is changed so as to rise toward the other side of the inside of the tube body 232.

Then, among the refrigerant for defrosting, the direction of which has been changed by the inclined surface forming protrusion 256 and the inclined surface extension plate 257 flows along the mixed flow inducing curved surface 251, and the defrosting refrigerant for the tube body 232 ) Is mixed with the rest except for flowing along one side of the inside of the reflux receiving hole ( 258) is diverted back to reflux.

Then, some of the refrigerant for defrosting that has been turned toward the reflux receiving hole 258 by the reflux reversal curved body 252 flows into the reflux receiving hole 258, and the reflux reversing curved body 252 The rest of the refrigerant for defrosting, which has been diverted toward the reflux receiving hole 258, is pushed by the flow pressure of the refrigerant for defrosting flowing along the central portion of the inside of the tube body 232, and the inside of the tube body 232 It flows along the central part and then flows into another reflux part 250 adjacent to the reflux part 250 (located next to the front side of the reflux part 250) along the upward slope body 253. do.

Meanwhile, the defrosting refrigerant flowing into the reflux receiving hole 258 flows along the reflux receiving hole 258 and then flows to the reflux receiving hole 258 through the bypass pipe 259 among the refrigerant for defrosting. It leaves the reflux receiving hole 258 by the flow pressure of the inflow and flows along a portion corresponding to the front of the reflux receiving hole 258 of one side of the inside of the pipe body 232, and the direction conversion unit ( 255) and the neighboring direction change unit 255 (located next to the front of the direction change unit 255).

By being configured as above, the contact area and time of the refrigerant for defrosting flowing along the defrost condensation pipe 231 with the inner surface of the pipe body 232 can be increased, so that the defrost condensation pipe 231 The condensation efficiency of is further improved, so that defrost for the evaporator constituting the refrigeration cycle can be made more efficiently without the provision of a defrost heater.

Although the present invention has been shown and described in relation to specific embodiments above, those skilled in the art may modify the present invention in various ways without departing from the spirit and scope of the present invention described in the claims below. And it will be appreciated that it can be changed. However, it should be clearly stated that all of these modifications and variations are included within the scope of the present invention.

According to the defrost cycle device for the evaporator of the refrigeration cycle according to one aspect of the present invention, since it is possible to efficiently defrost the evaporator constituting the refrigeration cycle without the provision of a defrost heater, its industrial applicability is high. .

100: defrost cycle device for evaporator of refrigeration cycle
110: defrost evaporator
120: defrost compressor
130: defrost condenser
140: defrost expansion valve

Claims (4)

As applied to the main refrigeration cycle having a main evaporator, a main compressor, a main condenser and a main expansion valve,
a defrost expansion valve for expanding the refrigerant for defrosting;
a defrost evaporator evaporating the defrost refrigerant expanded by the defrost expansion valve;
a defrost compressor for compressing the refrigerant for defrosting evaporated in the defrost evaporator; and
A defrost condenser for condensing the refrigerant for defrosting compressed by the defrosting compressor;
The defrost condenser is provided in the main evaporator so that defrosting for the main evaporator can be performed,
The defrost condensation pipe constituting the defrost condenser is disposed in a form surrounded by the main evaporation pipe constituting the main evaporator,
The defrost condensation pipe
a tube body,
A direction changer formed on one side of the inside of the tube body and converting a portion of the refrigerant for defrosting flowing through the defrost condensation tube from one side to the other side of the inside of the tube body;
It is formed on the other side of the inside of the tube body so as to face the direction changing unit, and the defrosting refrigerant is changed in direction by the direction changing unit and flows to the other side of the inside of the tube body. Of one side, a reflux unit for refluxing back to the front of the direction conversion unit,
The direction changer
Forming an inclined surface convexly protruding from one side of the inside of the tube body to a predetermined height to form an inclined surface that changes the direction of the refrigerant for defrosting from one side of the inside of the tube body to the other side of the inside of the tube body with protrusions,
It protrudes from the upper part of the inclined plane protrusion toward the other inner side of the pipe body in the form of a plate having a predetermined width, and the refrigerant for defrosting is converted by the inclined plane protrusion to the other inner side of the pipe body. An inclined surface extension plate for inducing flow;
It is formed in the form of a curved surface recessed to a predetermined depth formed on the front side of the inclined surface forming protrusion, the front surface of the inclined surface forming protrusion, and the front surface of the inclined surface extension plate among one side of the inside of the pipe body. A reflux receiving hole for changing the direction of the refrigerant for defrosting so that the refluxed refrigerant flows along one side of the inside of the tube body;
By passing through the inclined surface forming protrusion so that the rear surface of the inclined surface forming protrusion and the reflux receiving hole communicate with each other, a portion of the refrigerant for defrosting rising along the inclined surface forming protrusion is bypassed and introduced into the reflux receiving hole. Including the pass pipe,
The reflux part
Among the other side surfaces of the inside of the tube body, it is formed in a curved shape that is recessed with a predetermined curvature outward from the portion facing the distal end of the inclined surface extension plate, and the refrigerant for defrosting flows along one side of the inside of the tube body. A mixed flow induction curved surface body that flows along one side of the inside of the pipe body of the refrigerant for defrosting and the rest of the refrigerant for defrosting and then changes direction by the inclined surface extension plate to flow while mixing with each other;
A reflux reversal curved surface extending from the mixed flow induction curved body and curved with a predetermined curvature toward the reflux receiving hole so that the mixed refrigerant for defrosting while flowing along the mixed flow inducing curved surface is refluxed toward the reflux receiving hole;
Some of the defrosting refrigerant diverted by the reflux reversing curved body is not directed toward the reflux receiving hole, but is separated from the reflux reversing curved body and flows along the central portion of the inside of the tube body so that it gradually rises Defrost cycle device for the evaporator of the refrigeration cycle, characterized in that it comprises an upwardly inclined body. According to claim 1,
The defrost evaporator is provided in a storage compartment in which at least one of refrigeration and refrigeration is required, and at least one of refrigeration and refrigeration for the storage compartment can be performed by the defrost evaporator. . delete delete

Images