KR20190128408A - Heat exahanging device - Google Patents

Abstract

The present invention relates to a heat exchanger for a refrigeration device, which comprises: a liquid receiver temporarily storing a high-temperature and high-pressure refrigerant condensed in and supplied from a condenser of the refrigeration device, and supplying the refrigerant to an expansion valve; and a liquid separator temporarily storing a refrigerant evaporated in an evaporator, and transferring the evaporated refrigerant to a compressor, the liquid separator being inserted and provided in the liquid receiver. The liquid receiver is provided with a refrigerant inlet through which the refrigerant discharged from the condenser flows in and a refrigerant outlet through which the liquid refrigerant is discharged to the expansion valve. The liquid separator is provided with a refrigerant inlet portion through which the gas refrigerant supplied from the evaporator flows in and a refrigerant outlet portion through which the gas refrigerant is transferred to the compressor. The liquid separator is composed of an inner tube having a small diameter inserted and provided in the liquid receiver, and an outer tube formed with a diameter smaller than the liquid receiver but larger than the inner tube. The outer tube is formed in a double tube structure to surround the inner tube, and both ends of the inner tube are opened to communicate with the inside of the liquid receiver. One side and the other side sealing plates for sealing both ends of each of the inner and outer tubes are welded between the inner and outer tubes to form a refrigerant circulation passage formed in a cylindrical shape so that the gas refrigerant flowing into the refrigerant inlet portion is circulated to the refrigerant outlet portion.

Description

Heat extruder of refrigeration unit

The present invention relates to a liquid heater of a refrigerating device, and more particularly, in order to achieve a heat exchange effect between a high temperature refrigerant stored in a receiver and a low temperature refrigerant stored in a liquid separator, a liquid separator is installed inside the receiver. In order to improve the structure of the liquid separator, the receiver is designed to be inserted and installed, and the receiver can increase the storage space therein to increase the refrigerant storage capacity and at the same time reduce the volume thereof. The liquid separator inserted therein is a configuration in which the inner and outer pipes are formed in a double tube structure, and thus the high temperature refrigerant flowing into the fluid receiver is stored in the state flowing into the inner tube of the liquid separator. It is possible to increase the storage amount of the refrigerant, and the high temperature refrigerant stored in the receiver is the same as the inner and outer tubes of the liquid separator. The heat exchange action of the liquid in the refrigerating device to maximize the freezing efficiency of the refrigerating device by allowing the heat exchange action between the low-temperature refrigerant flowing into the liquid separator and the high-temperature refrigerant stored in the receiver is active. It's about heat.

In general, a refrigeration cycle of a refrigerating device using a refrigerant includes a compressor for compressing a low temperature low pressure gas refrigerant evaporated in an evaporator to a high temperature and high pressure, a condenser for condensing the liquid refrigerant of a high temperature and high pressure compressed in the compressor, and condensing in the condenser. A receiver for temporarily storing the high temperature and high pressure liquid refrigerant, an expansion valve for rapidly expanding the liquid refrigerant supplied from the receiver and supplying the liquid refrigerant at low temperature and low pressure, and a refrigerant in the mist state supplied from the expansion valve. An evaporator that vaporizes by heat exchange to take heat away from an external heat exchange medium (air, water, etc.), and a liquid separation that temporarily stores evaporated gas (gas refrigerant) supplied by evaporating by heat exchange from the evaporator to a compressor, Compression of the low-temperature gas refrigerant supplied from the liquid separation at high temperature and high pressure to discharge to the condenser As described above, the refrigeration cycle of the refrigerating device is configured to repeat the operation of circulating the refrigerant compressed by the high temperature and high pressure in the compressor to the condenser → liquid → expansion valve → evaporator → liquid separator → compressor. .

In the prior art, a liquid receiver for temporarily storing a high temperature and high pressure liquid refrigerant condensed in a condenser condensed with a high temperature and high pressure liquid refrigerant discharged from a compressor, and a liquid separator for temporarily storing a gas refrigerant evaporated in an evaporator, respectively Since the refrigerant pipes are installed in the refrigerant circulation line, the piping structure of the refrigeration circulation line becomes complicated. In addition, the refrigerant condensed in the condenser may not easily flow to the receiver side, and may not be vaporized in the evaporator. Since there is a problem that the refrigerant in the fog state is introduced into the compressor through the liquid separator occurs to solve this problem, the present inventors registered Utility Model No. 20-0359861, Patent No. 10-0666920, Patent No. 10- Prior arts such as 1059396 and 10-1289664 have been proposed.

The above prior arts each have a structure in which a liquid separator is inserted into and installed in the receiver, so that the high temperature and high pressure liquid refrigerant stored in the receiver and the low temperature and low pressure gas refrigerant stored in the liquid separator exchange heat with each other. The receiver receives the heat from the low temperature and low pressure refrigerant stored in the liquid separator by the high temperature and high pressure refrigerant stored therein so that the pressure is lowered, so that the refrigerant condensed in the condensation flows well to the fluid side, and the liquid separator is stored therein. The refrigerant in the fog state is configured to supply gaseous refrigerant to the compressor by evaporating heat from the high temperature refrigerant stored in the receiver, and the above-mentioned prior arts are applied to the high temperature liquid refrigerant and the liquid separator stored in the receiver. Low-temperature gas refrigerants are stored in heat exchange Looking at the following. In other words,

Prior Art Registration Utility Model No. 20-0359861 is a structure that is formed so that a plurality of inner and outer heat dissipation pipes are densely arranged in each of the inside and the outside of the liquid separator inserted into the receiver, which is a high temperature stored in the receiver The refrigerant of circulates the plurality of external heat dissipation pipes densely arranged outside the liquid separator to exchange heat with the low temperature refrigerant stored in the liquid separator, and the low temperature refrigerant introduced into the liquid separator is stored in the plurality of internal heat dissipation pipes. It is configured to exchange heat with the high temperature refrigerant stored in the receiver while circulating.

The prior art Patent No. 10-0666920 is formed by radially forming a plurality of inner and outer heat sink fins at predetermined intervals in each of the inside and the outside of the liquid separator inserted into the receiver, by the plurality of inner and outer heat sink fins. The heat exchange area is enlarged so that the heat exchange action can be well performed between the high temperature refrigerant stored in the receiver and the low temperature refrigerant stored in the liquid separator.

The prior art Patent No. 10-1059396 is a refrigerant inlet tube formed with a plurality of coolant outlet holes at a predetermined interval on the outer side of the liquid separator is inserted into the infusion of the sap, and a plurality of coolant inlet holes are formed at regular intervals on the other side And a plurality of internal and external heat exchange plates formed at predetermined intervals in each of the inner and outer parts of the liquid separator, and the high temperature flowing into the receiver through the refrigerant inlet tube and stored therein. Through the outlet line of the evaporator connected to the refrigerant and the liquid separator of the low-temperature refrigerant flowing into the liquid separation is configured so that the heat exchange action can be made well with each other.

Prior art Patent No. 10-1289664 has a receiver and the liquid separator is composed of a double pipe structure, the liquid separator is installed on the outside, the receiver is composed of a structure inserted into the liquid separator, In the receiver, an additional heat exchange tube or a heat exchange spiral tube penetrating the inside of the receiver is formed, and then a part of the refrigerant supplied to the expansion valve side through the outlet of the receiver is stored in the inlet through the inlet of the receiver. Through the heat exchange tube or the heat exchange spiral tube through the heat exchange tube through the heat exchange spiral tube through the heat exchange action with the high-temperature refrigerant stored in the receiver and then discharged to the heat exchange tube or heat exchange spiral tube Is combined with the low temperature refrigerant supplied from the evaporator to the liquid separator flows into the liquid separator to the receiver A refrigerant and a heat exchange action of the high temperature section and then is adapted to be supplied to the compressor.

However, the above-mentioned prior arts are formed in a double pipe structure in which a liquid separator in which a low temperature refrigerant is stored is inserted into an inside of a receiver where a high temperature refrigerant is stored, so that the low temperature refrigerant stored in the receiver is stored in the liquid separator. Since the heat is deprived from the low temperature refrigerant, the pressure of the high temperature refrigerant introduced into and stored in the receiver decreases, so that the high temperature refrigerant condensed in the condenser can flow to the receiver side, and the liquid separator can be expected. The low-temperature refrigerant introduced into and stored in the evaporator is well evaporated by removing heat from the high-temperature refrigerant stored in the receiver, so that only the gas refrigerant can be supplied to the compressor. The inner space of the receiver, that is, the refrigerant, is The disadvantage is that the internal cross-sectional area for storage is reduced.

In addition, in order to solve the above disadvantages, when the size of the receiver is greatly enlarged in order to increase the internal cross-sectional area of the receiver by the volume of the liquid separator inserted into the receiver, the volume of the receiver is increased. As a result, the volume of the liquid column eventually becomes considerably large, which causes the refrigeration cycle not to be compactly constructed. Also, the heat exchange between the refrigerant and the refrigerant stored in each of the liquid separators is achieved. It is pointed out that the manufacturing cost increases due to the complicated structure and the addition of various configurations.

Utility Model Registration No. 20-0359861 (August 21, 2004) Patent Registration No. 10-0666920 (January 11, 2007) Patent Registration No. 10-10593962011. 08. 29. Announcement) Patent Registration No. 10-1289664 (July 26, 2013)

The present invention has been proposed in view of the above-mentioned problems in the prior art, and is configured to insert and separate a liquid separator into a receiver in which a high temperature refrigerant supplied from a condenser is stored, and a high temperature refrigerant stored in the receiver. The low temperature refrigerant stored in the liquid separator may be configured to exchange heat with each other, but the refrigerant storage capacity stored in the receiver increases, while the volume of the receiver is reduced, and at the same time, the low temperature refrigerant stored in the liquid separator is introduced. The liquid crystal and the liquid separator have a compact structure so that the heat exchange action with the high temperature refrigerant stored in the liquid receiver is reduced, thereby reducing the installation area of the refrigeration cycle and simplifying the assembly structure of the liquid receiver and the liquid separator. To reduce the manufacturing cost of the heater It is invented for the purpose of providing a liquid heater.

The present invention as a means for pursuing the above object,

A receiver for temporarily storing the high temperature and high pressure refrigerant condensed and supplied to the expansion valve and supplying it to the expansion valve, and a liquid separator for temporarily storing the vaporized refrigerant in the evaporator and sending it to the compressor are installed in the receiver. The receiver has a refrigerant inlet through which a refrigerant discharged from a condenser flows in and a refrigerant outlet through which a liquid refrigerant is discharged through an expansion valve. The liquid separator includes a refrigerant inlet and a compressor into which a gas refrigerant supplied from an evaporator flows. In the liquid heater of the refrigerating device is configured so that each of the refrigerant outlet for sending gas refrigerant is formed,

The liquid separator is composed of an inner tube having a small diameter inserted into the receiver, and an outer tube formed smaller than the receiver but larger in diameter than the inner tube.

The outer tube is formed in a double tube structure to surround the inner tube so that both ends of the inner tube is open to communicate with the inside of the receiver,

One side and the other sealing plate for sealing both ends of each of the inner and outer tubes are welded between the inner and outer pipes so that a refrigerant circulation passage formed in a cylindrical shape is formed so that the gas refrigerant flowing into the refrigerant inlet is circulated to the refrigerant outlet. Characterized in that it is configured to be.

In addition, a plurality of diaphragms formed at a predetermined interval between the refrigerant inlet and the refrigerant outlet are formed in a C-shape in the refrigerant circulation passage formed in a cylindrical shape between the inner and outer tubes of the liquid separator. The magnetic diaphragm and the inverted C-shaped diaphragm, which are alternately installed at 180 °, are alternately formed so that the refrigerant flowing into the refrigerant circulation passage flows in the refrigerant inlet side and circulates in a zigzag direction toward the refrigerant outlet side. It is characterized by.

In addition, one side of the receiver is characterized in that the refrigerant storage pocket for storing the liquid refrigerant is formed so that the suction end of the refrigerant outlet is immersed in the liquid refrigerant stored in the receiver.

According to the present invention, the liquid separator inserted into the receiver of the heat receiver is formed by combining an inner tube having a diameter smaller than the receiver and an outer tube having a diameter larger than the inner tube in a double pipe structure and inserted into the receiver. The structure of the liquid separator is improved so that the refrigerant flowing into the receiver can be stored in the inner tube of the separator so that the liquid heater can be manufactured compactly, and the volume of the receiver can be reduced. The storage capacity of the refrigerant stored in the receiver is effective to increase.

In addition, by allowing the liquid separator inserted into the receiver of the heat receiver to be manufactured in a simple structure, the high temperature refrigerant stored in the sap and the low temperature refrigerant stored in the separator are actively exchanged with each other. There is an effect to increase the heat exchange efficiency between the high temperature refrigerant and the low temperature refrigerant inlet and stored in each of the receiver and the liquid separator.

In addition, since the refrigerant storage pocket in which the liquid refrigerant is stored is formed in the receiver of the liquid heater, there is an effect of smoothly supplying the liquid refrigerant to the expansion valve side through the refrigerant outlet.

1 is a perspective view of a liquid heater of one embodiment for explaining the present invention,
2 is a cross-sectional view of a liquid heater of one embodiment of the present invention,
3 is a cross-sectional view taken along the line AA of FIG.
4 is a cross-sectional view taken along line BB of FIG.
5 is a perspective view showing an installation state of a plurality of diaphragms formed in the liquid separator of the liquid heater of the present invention,
6 is a cross-sectional view of a liquid heater according to another embodiment of the present invention.

Referring to the accompanying drawings, a specific embodiment of a liquid heater of a refrigerating device according to the present invention will be described in detail.

Reference numeral 1 denotes a heat sink of one embodiment configured as a horizontal type, and 1a denotes a heat sink of another embodiment configured as a vertical shape.

A heat sink 1 of one embodiment configured horizontally is shown in FIGS. 1 and 2, and a heat sink 1a of another embodiment configured vertically is shown in FIG. 6.

First, a description will be given of the liquid-heater 1 of an embodiment configured in a horizontal type.

Although not shown in the drawing, the liquid heater 1 includes a receiver 2 which temporarily stores a high temperature refrigerant supplied from a condenser that condenses the refrigerant discharged by being compressed at a high temperature and high pressure in a compressor of a refrigeration cycle, and sends it to an expansion valve. In the refrigeration cycle, the liquid separator 3 which temporarily stores the refrigerant evaporated and evaporated by heat exchange with the heat exchange medium and sends the refrigerant to the compressor is formed in a double pipe structure.

In other words, the liquid heater 1 has a structure in which the liquid separator 3 is inserted into the receiver 2.

As shown in FIGS. 1 and 2, the heat receiver 1 has a high-temperature, high-pressure refrigerant discharged from a condenser (not shown) on one side (see the left part in the drawing) of the receiver 2 formed in a horizontal shape. A refrigerant inlet 21 for inflow is formed, and a refrigerant outlet 22 for supplying a refrigerant to an expansion valve (not shown) is formed at the other side of the receiver 2 (see the right part in the drawing). It is.

In addition, the liquid heater 1 is a compressor (not shown) and a refrigerant inlet 31 and a refrigerant into which the refrigerant supplied from an evaporator (not shown) flows into the liquid separator 3 inserted into the receiver 2. Refrigerant outlets 32 for sending to the air are formed respectively.

A characteristic of the present invention is to improve the structure of the liquid separator 3 inserted into the receiver 2 of the heat receiver 1 so that the refrigerant flowing into the receiver 2 is stored in the liquid separator 3. The volume of the receiver 2 can be reduced while the storage capacity of the refrigerant stored in the receiver 2 is increased by being configured to be stored inside.

To this end, the liquid separator (3) inserted into the receiver 2 is composed of inner and outer tubes (3a) (3b) smaller than the diameter of the receiver, the outer tube (3b) is an inner tube ( 3a) is formed to have a larger diameter than the inner tube 3a so as to be assembled to surround the inner tube 3a to form a refrigerant circulation passage 33 formed in a cylindrical shape with the inner tube 3a.

In addition, both ends of each of the inner and outer tubes 3a and 3b are sealed at both ends of the refrigerant circulation passage 33 formed in a cylindrical shape between the inner tube 3a and the outer tube 3b. One side and the other side sealing plates 34 and 35 are respectively welded.

In addition, cold inner circulation formed in a cylindrical shape between the inner and outer tubes (3a) (3b) by one side and the other side sealing plates (34) (35) welded to both ends of the inner and outer tubes (3a) (3b). Since both sides of the passage 33 are in a sealed state, the refrigerant flowing into the refrigerant inlet 31 of the liquid separator 3 is circulated along the refrigerant circulation passage 33 to be discharged through the refrigerant outlet 32.

As described above, the liquid separator 3 inserted into the receiver 2 is installed at both ends of the inner tube 3a so as to communicate with the receiver 2. The refrigerant introduced into and stored in 2) flows into the inner tube 3a of the liquid separator 3 to be stored and circulated, and the refrigerant stored in the receiver 2 is stored in the outer tube (3) of the liquid separator 3. 3b) is stored in contact with the outside.

Therefore, the refrigerant introduced into and stored in the receiver 2 exchanges heat with the inner surface of the inner tube 3a of the liquid separator 3 and also exchanges heat with the outer surface of the outer tube 3b. The heat exchange action between the high temperature refrigerant introduced into and stored in 2) and the low temperature refrigerant introduced into and stored in the liquid separator 3 is actively performed by the internal and external tubes 3a and 3b.

In addition, the refrigerant circulation passage 33 formed in a cylindrical shape between the inner and outer tubes 3a and 3b of the liquid separator 3 flows into the refrigerant inlet 31 and circulates toward the refrigerant outlet 32. While delaying the flow of the refrigerant, a plurality of diaphragms are formed at regular intervals so that heat exchange with the high temperature refrigerant stored in the receiver 2 can be performed well.

As shown in FIG. 5, the plurality of diaphragms 36 and the inverted C-shaped diaphragms 37 which are formed to be shifted at an angle of 180 ° with respect to the C-shaped diaphragm 36 are each spaced apart from each other. It is configured to be installed alternately.

Therefore, the low-temperature refrigerant flowing into and circulating through the refrigerant circulation passage 33 formed in a cylindrical shape between the inner and outer tubes 3a and 3b of the liquid separator 3 is formed at a predetermined interval with a C-shaped diaphragm. By the 36 and the inverted C-shaped diaphragm 37, the refrigerant circulation passage 33 circulates in a zigzag shape, so that heat exchange with the high temperature refrigerant stored in the receiver 2 is performed well.

And a plurality of installed in a state in close contact with the bottom portion of the refrigerant circulation passage 33 of the plurality of diaphragm provided at a predetermined interval in the cylindrical refrigerant circulation passage 33 formed in the liquid heater 1 of the above embodiment. The C-shaped diaphragm 36 of the coolant flow passage 38 for flowing the coolant flows to the bottom of the refrigerant circulation passage 33 is formed (see Fig. 5), the refrigerant is accumulated in the refrigerant circulation passage 33 The phenomenon does not occur.

Meanwhile, each of the refrigerant inlet 31 and the refrigerant outlet 32 of the liquid separator 3 is welded to be connected to penetrate one side and the other side of the outer tube 3b of the liquid separator 3, respectively. Each of the coolant inlet 31 and the coolant outlet 32 is installed in a state of protruding to the outside through the receiver 2.

Therefore, the low temperature refrigerant flowing into the refrigerant circulation passage 33 formed between the inner and outer tubes 3a and 3b through the refrigerant inlet 31 connected to the liquid separator 3 is the refrigerant circulation. Since the coolant circulates in a zigzag shape toward the coolant outlet port 32 along the passage 33, low-temperature coolant circulating in the coolant circulation passage 33 in a zigzag shape flows into the receiver 2 and is stored at a high temperature. Heat exchange with the high temperature refrigerant through the inner surface (3a) of the liquid separator exposed to the refrigerant and the outer surface of the outer tube (3b), and thus the high-temperature refrigerant and the liquid flowing into the receiver 2 The heat exchange effect with the low temperature refrigerant circulating through the refrigerant circulation passage 33 of the separator 3 is well made to increase the heat exchange efficiency.

In the exemplary embodiment, the liquid heater 1 includes a refrigerant storage pocket 4 formed at a lower side of the receiver 2 (see the right part in the drawing), and the refrigerant storage pocket 4 is a condenser. The liquid refrigerant condensed into the liquid phase when the high-temperature refrigerant supplied from (not shown) flows into the receiver 2 through the refrigerant inlet 21 of the receiver 2 is the inner bottom of the receiver 2. The refrigerant in the gaseous state, which is accumulated and does not condense, flows in the upper portion of the receiver 2, and the liquid refrigerant accumulated on the inner bottom of the receiver 2 is stored in the refrigerant storage pocket 4. As a result, even when the amount of storage of the liquid refrigerant that accumulates on the inner bottom of the receiver 2 becomes small, the refrigerant storage pocket 4 can maintain the liquid refrigerant at all times.

In addition, since the suction end 22a of the refrigerant outlet 22 is inserted into the refrigerant storage pocket 4, a liquid refrigerant can always be supplied to an expansion valve (not shown) through the refrigerant outlet 22. (See Figure 2).

Next, a description will be given of the heat sink 1a of another embodiment configured as a vertical shape.

The heat sink 1a of the other embodiment is installed vertically as shown in FIG. 6, and the heat sink 1a has the same name and the same reference numerals for the same configuration as that of the horizontal heat sink 1 described above. It will be described using.

Although not shown in the drawings, the heat receiver 1a of the other embodiment also includes a receiver for temporarily storing a high temperature refrigerant supplied from a condenser that condenses the refrigerant discharged by being compressed at a high temperature and high pressure in a compressor of a refrigeration cycle and sending it to an expansion valve ( 2) and the liquid separator 3 which temporarily stores the refrigerant evaporated and evaporated by the heat exchange action with the heat exchange medium in the evaporator of the refrigeration cycle and sends it to the compressor.

As shown in FIG. 6, the heat receiver 1a is configured to introduce a high-temperature, high-pressure refrigerant discharged from a condenser (not shown) to one side (see the upper portion in the drawing) of the receiver 2 formed in a shape. Refrigerant inlet 21 is formed, and the other side (refer to the lower portion of the drawing) of the receiver 2 is configured to have a structure in which the refrigerant outlet 22 for supplying the refrigerant to the expansion valve (not shown) is formed have.

The liquid separator 1a is also inserted into and installed in the receiver 2, the refrigerant inlet 31 through which the refrigerant supplied from the evaporator flows in, and the refrigerant outlet 32 for sending the refrigerant to the compressor. Are formed respectively.

The cooler 1a also improves the structure of the liquid separator 3 inserted into the receiver 2 so that the refrigerant flowing into the receiver 2 may be stored in the liquid separator 3. It is characterized in that it is configured to reduce the volume of the receiver 2 while increasing the storage capacity of the refrigerant stored in the receiver 2.

And the column 1a is composed of a receiver 2 and the liquid separator (3) is inserted into the installation therein, the liquid separator 3 is composed of an inner, outer tube (3a) (3b), Both sides of the refrigerant circulation passage 33 formed in a cylindrical shape between the inner and outer tubes 3a and 3b are welded to seal one side (see the upper portion in the drawing) with one side sealing plate 34, and the refrigerant And welding the other side of the circulation passage 33 (see lower part in the drawing) to the other sealing plate 35 so as to seal the refrigerant circulation passage 33 with a C-shaped diaphragm 36 and an inverted C-shaped diaphragm 37 ) Are installed alternately at regular intervals.

Referring to the operation of each of the heat sink 1 of the embodiment of the present invention configured as described above and each of the heat sink 1a of the other embodiment as follows.

First, a description will be given of the operation on the liquid heater 1 of the embodiment formed in a horizontal shape.

The high temperature refrigerant supplied from the condenser 1 is introduced through the refrigerant inlet 21 as illustrated in FIG. 2, and the high temperature refrigerant introduced into the refrigerant inlet 21 is transferred from the condenser. A liquid refrigerant condensed into a liquid phase and a gaseous refrigerant not condensed flow into a mixed state, wherein the high temperature liquid refrigerant condensed is stored in a standing state on the inner bottom of the receiver 2 and is not condensed. The gaseous refrigerant is stored in a state of flowing above the receiver 2.

Therefore, the high temperature refrigerant flowing into the receiver 2 is stored in contact with the inner surface of the inner tube 3a and the outer surface of the outer tube 3b of the liquid separator 3 and thus stored in the receiver 2. The heat exchange between the high temperature refrigerant and the low temperature refrigerant circulating along the refrigerant circulation passage 33 of the liquid separator 3 is simultaneously performed in the inner tube 3a and the outer tube 3b. The high temperature refrigerant stored in the heat sink is deprived of heat from the low temperature refrigerant circulating through the refrigerant circulation passage 33 of the liquid separator 3 so that the high temperature refrigerant stored in the receiver 2 is a condenser (not shown). Since the temperature is lower than the internal temperature and the pressure, the condenser can smoothly supply a high-temperature refrigerant to the receiver 2, whereas the liquid separator 3 has a low-temperature refrigerant supplied from an evaporator (not shown). While circulating the refrigerant circulation passage 33 and the inner tube (3a) Since the heat is removed from the high temperature refrigerant stored in the receiver 2 through the outer tube 3b, the refrigerant flowing into the refrigerant circulation passage 33 of the liquid separator 3 is not evaporated from the evaporator. Since the evaporation is effected by taking away the gas, the gas refrigerant is supplied to the compressor (not shown) through the refrigerant outlet 32 of the liquid separator 3.

Next, the operation of the liquid heater 1a of another embodiment formed in a vertical shape will be described.

The high temperature refrigerant supplied from the condenser (not shown) is also introduced through the refrigerant inlet 21 as illustrated in FIG. 6, and the high temperature refrigerant introduced into the refrigerant inlet 21 is transferred from the condenser. A liquid refrigerant condensed into a liquid phase and a gaseous refrigerant not condensed are introduced in a mixed state.

Therefore, the hot refrigerant concealed in the liquid state is stored in a state of being accumulated in the lower side of the receiver 2, and the non-condensed gaseous refrigerant is stored in a state of flowing above the inside of the receiver 2.

In addition, the high temperature refrigerant stored in the receiver 2 is in direct contact with the inner surface of the inner tube 3a of the liquid separator 3 and the outer surface of the outer tube 3b so that the refrigerant circulation passage of the liquid separator 3 ( The low temperature refrigerant circulating along the refrigerant circulation passage 33 of the liquid separator 3 is heat-exchanged with the low temperature refrigerant circulating along the 33. Since the heat exchange action to take out is actively made, only the gas refrigerant flows out through the refrigerant outlet 32, and the high temperature refrigerant stored in the receiver 2 is the refrigerant circulation passage 33 of the liquid separator 3. Since the heat is taken away from the low temperature refrigerant circulating through, the refrigerant of the condenser is smoothly supplied to the receiver 2 side.

As described above, in the present invention, the liquid separator (1) (1a) is composed of the receiver (2) and the liquid separator (3) in a dual structure, the liquid separator (3) is the inner tube (3a) and the outer tube (3b) is configured in a double pipe structure, the inner tube (3a) of the liquid separator (3) is configured to communicate with the receiver 2 so that the high temperature refrigerant flowing into the receiver (2) is a liquid separator Since the structure is improved to be stored in the inner tube (3a) of the inner surface of (3), the liquid separator (3) is inserted into the receiver 2, the high-temperature refrigerant is introduced into the receiver 2 is stored inside Heat exchange between the entire inner surface of the tube 3a and the entire outer surface of the outer tube 3b causes heat exchange between the high temperature refrigerant flowing into the receiver 2 and the low temperature refrigerant circulating into the liquid separator 3 and circulating. In order to achieve a good function, the high-temperature refrigerant flowing into the receiver 2 is stored in the separator 3. Since it can be stored inflow into the secondary pipe (3a) it is possible to reduce the volume of the receiver (2) as much as possible to increase the cold storage capacity of the receiver (2) so that the compactor (2) can be compactly configured It is effective.

In addition, the present invention can be configured to assemble the receiver 2 and the liquid separator (3) constituting the liquid heater (2) in a simple structure is an invention that has the effect of reducing the production cost.

1,1a: Heater 2: Fluid receiver
21: refrigerant inlet 22: refrigerant outlet
3: liquid separator 3a: inner tube
3b: external pipe 31: refrigerant inlet
32: refrigerant outlet 33: refrigerant circulation passage
34: one side sealing plate 35: the other side sealing plate
36: C plate 37: Inverted C plate
4: refrigerant storage pocket

Claims (3)

A receiver for temporarily storing the high temperature and high pressure refrigerant condensed and supplied to the expansion valve and supplying it to the expansion valve, and a liquid separator for temporarily storing the vaporized refrigerant in the evaporator and sending it to the compressor are installed in the receiver. The receiver has a refrigerant inlet through which a refrigerant discharged from a condenser flows in and a refrigerant outlet through which a liquid refrigerant is discharged through an expansion valve. The liquid separator includes a refrigerant inlet and a compressor into which a gas refrigerant supplied from an evaporator flows. In the liquid heater of the refrigerating device is configured so that each of the refrigerant outlet for sending gas refrigerant is formed,
The liquid separator is composed of an inner tube having a small diameter inserted into the receiver, and an outer tube formed smaller in diameter than the inner tube but larger than the inner tube.
The outer tube is formed in a double tube structure to surround the inner tube so that both ends of the inner tube is open to communicate with the inside of the receiver,
One side and the other sealing plate for sealing both ends of each of the inner and outer tubes are welded between the inner and outer pipes so that a refrigerant circulation passage formed in a cylindrical shape is formed so that the gas refrigerant flowing into the refrigerant inlet is circulated to the refrigerant outlet. Liquid heater of the refrigerating device, characterized in that configured to be.
The method of claim 1,
In the refrigerant circulation passage formed in a cylindrical shape between the inner and outer pipes of the liquid separator, a plurality of diaphragms formed at a predetermined interval between the refrigerant inlet and the refrigerant outlet are formed in a C shape, and the plurality of diaphragms are C-shaped diaphragms. And the inverted C-shaped diaphragm alternately formed at 180 ° with the C-shaped diaphragm are alternately formed so that the refrigerant flowing into the refrigerant circulation passage flows from the refrigerant inlet side and circulates zigzag toward the refrigerant outlet side. A liquid heater of a refrigerating device, characterized in that configured to be.
The method of claim 1,
And a refrigerant storage pocket formed at one side of the receiver for storing the liquid refrigerant such that the suction end of the refrigerant outlet is immersed in the liquid refrigerant stored in the receiver.

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