KR102036292B1 - Evaporative condensation of refrigeration equipment - Google Patents

Abstract

According to the present invention, a refrigerant inlet header having a refrigerant inlet and a refrigerant outlet header having a refrigerant outlet are arranged up and down in an evaporative condenser of a refrigerating device, and are vertical to the refrigerant inlet header and the refrigerant outlet header. The plurality of refrigerant vertical circulation pipes connected to each other are formed at regular intervals, and the plurality of refrigerant vertical circulation pipes vertically installed to face each other while maintaining a constant interval for each of the plurality of refrigerant vertical circulation pipes are provided. In the evaporative condenser provided with a plurality of refrigerant horizontal circulation pipe connecting each of the plurality of refrigerant vertical circulation pipe and the plurality of refrigerant vertical circulation pipe,
The coolant inlet header having the coolant inlet and the coolant outlet header having the coolant outlet are laid up and down, and the plurality of coolant vertical circulation pipes connecting the coolant inlet header and the coolant outlet header are formed at regular intervals. And
A plurality of coolant vertical return pipes vertically installed to maintain a predetermined interval for each of the plurality of coolant vertical circulation pipes are formed, and a plurality of coolant connecting the plurality of coolant vertical circulation pipes and the plurality of coolant vertical return pipes. Each end of the horizontal circulation pipe is configured to penetrate the interior of each of the plurality of refrigerant horizontal circulation pipes and to pass through each of the plurality of coolant vertical circulation pipes and the coolant vertical flow pipes to connect to the plurality of coolant vertical circulation pipes and the coolant vertical flow pipes, respectively. It is an invention characterized by the above-mentioned.

Description

Evaporative condensation of refrigeration equipment

The present invention relates to an evaporative condenser of a refrigerating device, and more particularly, it is possible to reduce the volume of the evaporative condenser while reducing the overall volume of the refrigerating device by quickly and increasing the circulation rate and circulation of the refrigerant, Refrigeration efficiency relates to an evaporative condenser that has been improved to be able to increase.

In general, a refrigeration unit sends the vaporized gas refrigerant from the evaporator to the compressor, the compressor compresses the gas refrigerant to a high temperature and high pressure to send to the condenser, the condenser condenses to liquefy by the cooling action to cool the refrigerant compressed in the compressor, the condenser Liquid refrigerant condensed by condensation in the air is rapidly expanded in the expansion valve and sent to the evaporator in the mist state, in which the refrigerant expanded in the mist state takes heat away from the surrounding heat exchange medium (air or water, etc.). It is configured to heat exchange by repeating the circulation operation that is evaporated and sent back to the compressor.

Prior art evaporative condensers are installed by bending the condensing coils in a U-shape to connect the condensing coils formed of small diameter pipes in a zigzag form, or by welding adjacent pipes with U-shaped connecting bands. The condensing coil is installed in a zigzag shape. The condensing coil, which is installed in a zigzag shape, passes through the connecting portion repeatedly bent in a U-shape while the mist of refrigerant flowing from the inlet side is moved to the outlet side. Flow resistance is generated in the process, there is a problem that the flow of the refrigerant is slow.

As described above, when the condensing coil is manufactured using a small diameter pipe having a small cross-sectional area, the flow resistance of the refrigerant is increased, whereas the condensing coil is removed by using a large diameter pipe having a large cross-sectional area. In this case, the volume of the evaporative condenser increases and the weight becomes heavy.

Therefore, the condensing coil is made of a small diameter pipe having a relatively small cross-sectional area, but the condensing coil is produced as described above. However, as described above, the flow resistance of the refrigerant is generated at the bent portion of the U-shape and flows into the inlet of the condensing coil. It is pointed out that the refrigerant is not smoothly circulated to the outlet side, and thus the liquefaction of the refrigerant is not smooth and the heat exchange action is reduced.

Patent Registration No. 10-0784802 (December 14, 2007 notification) Patent Registration No. 10-1057338 (August 17, 2011)

The present invention has been proposed in view of the above-mentioned general matters, and the evaporative condenser cools the refrigerant by allowing the coolant to circulate inside and outside of the refrigerant circulation pipe through which the high temperature and high pressure refrigerant sent from the compressor circulates. This fast evaporative condenser is improved to improve the condensation efficiency of the refrigerant by increasing the circulation amount of the refrigerant and allowing the refrigerant to circulate quickly, while increasing the circulation of the refrigerant. It is invented for the purpose of providing.

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

The refrigerant inlet header with the refrigerant inlet and the refrigerant outlet header with the refrigerant outlet are arranged up and down.

The refrigerant inlet header and the refrigerant outlet header are provided with a plurality of refrigerant vertical circulation tubes which are vertically connected to each other at regular intervals.

Each of the plurality of refrigerant vertical circulation pipes is provided with a plurality of refrigerant vertical flow pipes vertically installed to face each other while maintaining a predetermined interval,

In the evaporative condenser provided with a plurality of refrigerant horizontal circulation tube connecting each of the plurality of refrigerant vertical circulation tube and the plurality of refrigerant vertical circulation tube,

The coolant inlet header with the coolant inlet and the coolant outlet with the coolant outlet are installed up and down.

The plurality of coolant vertical circulation pipes connecting the coolant inlet header and the coolant outlet header are formed at regular intervals,

A plurality of coolant vertical return pipe is installed in the vertical direction to maintain a predetermined interval for each of the plurality of coolant vertical circulation pipe,

Both ends of the plurality of cooling water horizontal circulation pipes connecting the plurality of cooling water vertical circulation pipes and the plurality of cooling water vertical circulation pipes respectively penetrate the inside of the plurality of refrigerant horizontal circulation pipes, respectively. It is characterized in that it is configured to pass through and connected to each of the plurality of cooling water vertical circulation pipe and the cooling water vertical return pipe.

In addition, two sheets of heat exchange panels having symmetrical grooves symmetrically formed at regular intervals may face each other on the outer circumference of the plurality of refrigerant horizontal circulation tubes through which the plurality of cooling water horizontal circulation tubes pass. It is characterized in that it is fixed by welding in a true state.

In addition, upper and lower partitions are formed in each of the plurality of refrigerant vertical circulation tubes at regular intervals, and intermediate partitions are formed in each of the plurality of refrigerant vertical return tubes, and the plurality of cooling water vertical circulation tubes Each partition is characterized in that one partition is formed.

In addition, a plurality of supports are formed at predetermined intervals in each of the plurality of refrigerant horizontal circulation tubes to fix the cooling water horizontal circulation tube so as not to contact the inner surface of the refrigerant horizontal circulation tube.

According to the present invention, the refrigerant flowing into the inlet of the refrigerant inlet header formed in the evaporative condenser includes a plurality of refrigerants along a plurality of refrigerant horizontal circulation tubes through a plurality of refrigerant vertical circulation tubes connecting the refrigerant inlet header and the refrigerant outlet header. Since the refrigerant is discharged through the vertical flow pipe to the refrigerant discharge header, the circulation speed of the refrigerant proceeds rapidly and the refrigerant circulating through the plurality of refrigerant horizontal circulation tubes is a cooling water circulating through the horizontal refrigerant pipe and the cooling water circulating through the refrigerant horizontal circulation tube. It is cooled and condensed by the heat exchange action that is dually cooled inside and outside by the cooling water flowing down to the heat exchange panel installed to be in close contact with the outer circumference of the refrigerant horizontal circulation pipe of the refrigerant, so the condensation efficiency of the refrigerant is improved, and the circulation speed of the refrigerant is high. By improving the condensation efficiency, it is possible to increase the cooling efficiency of the refrigerating unit. Invention.

1 is a perspective view of an evaporative condenser for explaining the present invention
2 is a front view of the evaporative condenser of the present invention.
3 is a plan view of the evaporative condenser of the present invention.
4 is a left side view of the evaporative condenser of the present invention.
5 is a cross-sectional view taken along the line AA of FIG.
6 is a cross-sectional view taken along the line BB of FIG.
7 is a cross-sectional view taken along line CC of FIG. 6.
8 is a cross-sectional view taken along the line DD of FIG. 6.
9 is a state of installation and use of the evaporative condenser of the present invention

Detailed embodiments of the evaporative condenser of a refrigerating device according to the present invention will be described in detail with reference to the accompanying drawings.

Reference numeral 1 denotes an evaporative condenser, and the evaporative condenser 1 includes a refrigerant inlet header 2a in which a fin inlet 21 is formed, and a refrigerant outlet header in which a refrigerant outlet 22 is formed. 2b) is arranged up and down, and each of the refrigerant inlet header 2a and the refrigerant outlet header 2b is provided with a plurality of refrigerant vertical circulation pipes 3a connected vertically at regular intervals. Refrigerant vertical circulation pipe (3a) of the plurality of refrigerant vertical circulation pipe (3b) which is vertically installed to face each other while maintaining a constant interval for each of the refrigerant vertical circulation pipe (3a) of the plurality of refrigerant vertical circulation pipe (3a) and Each of the plurality of coolant vertical flow tubes 3b is provided with a plurality of coolant horizontal circulation pipes 4 installed horizontally so as to be maintained at a predetermined interval up and down.

Both ends of each of the plurality of refrigerant horizontal circulation pipes 4 are fixedly installed in a structure connected by welding to the refrigerant vertical circulation pipe 3a and the refrigerant vertical return pipe 3b.

A characteristic of the present invention is a plurality of refrigerant vertical circulation pipe (3a) and a plurality of refrigerant vertical circulation pipe (3a) is connected to the two ends of the plurality of refrigerant horizontal circulation pipe (4) by welding while passing through each of the plurality of refrigerant horizontal circulation pipe (4) A plurality of cooling water horizontal circulation pipes 5 may be installed to penetrate through the refrigerant vertical return pipes 3b of the refrigerant to cool the refrigerant circulated into the plurality of refrigerant vertical circulation pipes 4 in the refrigerant horizontal circulation pipes 4. It's about having it.

To this end, a coolant inlet header 5a having a coolant inlet 51 formed at a lower side thereof is formed at one side (left side of the drawing) of the plurality of refrigerant vertical flow tubes 3b, and a coolant outlet 52 is formed at an upper side thereof. Cooling water outflow headers 5b are formed, and a plurality of cooling water vertical circulation pipes 6a connecting the cooling water inflow header 5a and the cooling water outflow header 5b vertically are formed at regular intervals.

In addition, at one side (right side in the drawing) of the plurality of coolant vertical circulation pipes 3a, a plurality of coolant vertical return pipes 6b which are arranged to face the plurality of coolant vertical circulation pipes 6 are formed vertically. Each end of each of the plurality of cooling water horizontal circulation pipes 7 connecting the plurality of cooling water vertical circulation pipes 6a and the plurality of cooling water vertical return pipes 6b to each other horizontally is the plurality of refrigerant horizontal circulation pipes 4. Penetrating through the interior of the plurality of refrigerant vertical circulation pipe (3a) and the plurality of refrigerant vertical circulation pipe (3b) and connected to each of the cooling water vertical circulation pipe (6a) and cooling water vertical return pipe (6b) by welding; It is configured to.

In addition, each of the plurality of refrigerant horizontal circulation tubes 4 configured to horizontally connect the plurality of refrigerant vertical circulation tubes 3a and the plurality of refrigerant vertical circulation tubes 3b to the outer circumference of each of the refrigerant horizontal circulation tubes 4 The cover portion 81a, 81b, which is formed in a semicircular cross section so as to be wrapped in close contact with both sides of the flat portion, in which the two heat exchange panels 8a, 8b, which are symmetrically formed at regular intervals, are in close contact with each other. 82a) and 82b are configured to be fixed by core welding or spot welding.

In addition, each of the cooling water horizontal circulation pipes 7 installed to penetrate the plurality of refrigerant horizontal circulation pipes 4 may vibrate inside the refrigerant horizontal circulation pipes 4, or the horizontal horizontal circulation of the refrigerant due to deflection. It is fixed to the inner center of the refrigerant horizontal circulation tube 4 by a plurality of supports (71) inserted into the refrigerant horizontal circulation tube (4) in order to prevent the inner surface of the tube (4) to contact or contact The plurality of support members 71 are provided at regular intervals.

In addition, upper and lower partitions 31 and 33 are formed at predetermined intervals in each of the plurality of coolant vertical circulation pipes 3a, and intermediate partitions are formed in each of the plurality of coolant vertical return pipes 3b. 32 is formed, and one partition 61 is formed inside each of the plurality of cooling water vertical circulation pipes 6a.

Although not shown in the drawing, each of the plurality of refrigerant horizontal circulation tubes 4 and the plurality of cooling water horizontal circulation tubes 7 may be configured as a one-pitch corrugated tube or a spiral corrugated tube to increase the heat transfer area.

On the other hand, the evaporative condenser (1) is installed in the condenser case (9) having a water tank (91) in which the coolant is stored at the bottom, and the water tank (91) on one side of the condenser case (9). The pump 92 for pumping the cooling water stored in the pump 92, and the cooling water pumped from the pump 92 is supplied to the plurality of sprinkling pipe 93 is installed in parallel to the inner upper portion of the condenser case (9) horizontally It is configured to cool by sprinkling with water flowing toward the lower evaporative condenser (1), the water droplets are sprayed into the water flowing to the plurality of water pipes 93, the upper, It is comprised so that it may flow through the both heat exchange panels 8a and 8b welded in the state which wrapped the some refrigerant horizontal circulation pipe 4 formed in the lower fixed space.

In addition, an upper portion of the condenser case 9 is provided with a cooling air circulation fan 94 so as to cool the evaporator condenser 1 while circulating the outside air into the condenser case 9.

The operation of cooling the evaporative condenser 1 in the configuration of the present invention configured as described above will be described.

The refrigerant supplied to the evaporative condenser 1 by being compressed at a high temperature and high pressure in the compressor of the refrigerating device is introduced into the refrigerant inlet header 2a through the refrigerant inlet 21 formed in the refrigerant inlet header 2a. The refrigerant flowing into the refrigerant inlet header 2a is supplied to the plurality of refrigerant vertical circulation tubes 3a while being distributed to the plurality of refrigerant vertical circulation tubes 3a, wherein each of the plurality of refrigerant vertical circulation tubes 3a is provided. The upper and lower partitions 31 and 32 are formed in the inner part, and the middle partition 32 is formed in the coolant vertical return pipe 3b, so that the coolant vertical circulation pipe is formed in the coolant inlet header 2a. The refrigerant supplied to 3a) is circulated in a zigzag fashion through the plurality of refrigerant horizontal circulation pipes 4 and the plurality of refrigerant vertical return pipes 3b by the upper and lower partitions 31 and 33 and the intermediate partition 32. do.

For convenience of description in that the refrigerant is circulated in a zigzag shape, the plurality of refrigerant vertical circulation tubes 3a and the plurality of refrigerant vertical circulation tubes 3b will be described below with reference to FIG. 6. Referring to the upper partition 31 shown in FIG. 6, the upper three refrigerant horizontal circulation tubes are referred to as 'first refrigerant horizontal circulation tubes 4-1', and the lower three refrigerant circulation tubes are referred to as 'first'. 2 refrigerant horizontal circulation tube (4-2), and the upper three refrigerant horizontal circulation tube is the 'third refrigerant horizontal circulation tube (4-3)', the lower 3 The two refrigerant horizontal circulation tubes will be described as 'fourth refrigerant horizontal circulation tube (4-4)' (However, the description will be described as a refrigerant horizontal circulation tube (4). ),

Based on the above description, when the refrigerant flowing into the refrigerant inlet header 2a is supplied to the plurality of refrigerant vertical circulation tubes 3a, the refrigerant is supplied to the first refrigerant horizontal circulation tube 4- by the upper partition 31. 1) the refrigerant is circulated to the refrigerant vertical flow pipe 3b, and the refrigerant flowing into the refrigerant vertical flow pipe 3b through the first refrigerant horizontal circulation pipe 4-1 is the refrigerant vertical circulation pipe 3b. Circulates through the second refrigerant horizontal circulation tube 4-2 by the intermediate partition 32 formed in the above, and the upper partition 31 and the lower portion through the second refrigerant horizontal circulation tube 4-2. The refrigerant flowing into the refrigerant vertical circulation pipe 3a between the partitions 33 flows into the lower side of the middle partition 32 of the refrigerant vertical flow pipe 3b through the third horizontal circulation pipe 4-3 and then again. Refrigerant through a lower side of the lower partition 33 formed in the coolant vertical circulation pipe 3a through a fourth coolant horizontal circulation pipe 4-4. Since the refrigerant flows into the outlet header 2b, the refrigerant flowing into the refrigerant inlet header 2a through the refrigerant inlet 21 may be the first to fourth refrigerant horizontal circulation tubes 4-1, 4-2, 4-3, 4-4) is sequentially circulated in a zigzag pattern and flows into the refrigerant discharge header 2b and is sent to the receiver or expansion valve of the refrigeration cycle through the refrigerant outlet 22.

As described above, the refrigerant flowing into the refrigerant inlet header 2a circulates through a plurality of refrigerant horizontal circulations 4 connecting the refrigerant vertical circulation tube 3a and the refrigerant vertical return tube 3b in a zigzag state. Since each of the plurality of refrigerant horizontal circulation tubes 4 is installed in a state where the cooling water horizontal circulation tube 7 penetrates, the cooling water circulating through the plurality of cooling water horizontal circulation tubes 7 and the plurality of refrigerant horizontal circulations. The refrigerants circulating in the tube 4 exchange heat with each other, and at the same time, they exchange heat with the cooling water flowing to both heat exchange panels 8a and 8b surrounding the outer circumference of the plurality of refrigerant horizontal circulation tubes 4.

That is, as shown in FIG. 9, the pump 92 installed at one side of the condenser case 9 pumps the coolant stored in the water tank 91 to supply the coolant inlet 51 to the coolant inlet 51. The coolant flowing into 5a and flowing into the coolant inlet header 5a is evenly distributed and supplied to the plurality of coolant vertical circulation pipes 6a, wherein the coolant is formed in each of the plurality of coolant vertical circulation pipes 6a. By the middle partition 32, the coolant is heat-exchanged with the refrigerant circulating through the plurality of refrigerant horizontal circulation pipes 4 while circulating through the plurality of cooling water horizontal circulation pipes 7 to the side of the coolant vertical return pipe 6b. In addition, the cooling water circulated from the cooling water vertical circulation pipe 6b to the plurality of cooling water horizontal circulation pipes 7 again performs heat exchange with the refrigerant circulating through the plurality of refrigerant horizontal circulation pipes 4. Cooling The cooling water discharged to the cooling outlet 52 of the cooling water outlet header 5b through the vertical circulation pipe 6a is provided in parallel with a plurality of spraying pipes 93 at a predetermined interval in parallel to the upper side of the evaporative condenser 1. Cooling water sprinkled by a thin stream of water flows down along the heat exchange panels 8a and 8b and exchanges heat with the refrigerant circulating through the plurality of refrigerant horizontal circulation tubes 4.

Accordingly, the inside of the refrigerant circulating in the plurality of refrigerant horizontal circulation tubes 4 exchanges heat with the cooling water circulating in the cooling water horizontal circulation tube 7, and the refrigerant circulating in the plurality of refrigerant horizontal circulation tubes 4 exchanges heat. Since heat is also exchanged with the cooling water flowing down the panels 8a and 8b, the refrigerant circulating in the plurality of refrigerant horizontal circulation pipes 4 eventually undergoes heat exchange with the cooling water circulating inside and outside. The condensation efficiency is improved by more than twice by the cooling action, and thus the cooling efficiency of the refrigerating device is also improved by more than twice.

In the evaporative condenser 1 of the present invention, since the plurality of refrigerant horizontal circulation tubes 4 are formed in a linear structure, the circulation speed of the refrigerant circulating in the zigzag phase of the plurality of refrigerant horizontal circulation tubes 4 is increased rapidly. It can be adjusted, and also can be densely installed in a configuration that narrows the installation interval of the plurality of refrigerant horizontal circulation pipe (4) it is possible to reduce the volume and weight of the evaporative condenser (1), thereby refrigerating device It can contribute to miniaturization.

The present invention described above is not intended to limit the embodiments shown in the drawings, and the invention that design changes are made within the scope not departing from the technical idea of the present invention should be construed as belonging to the scope of the present invention. .

1: evaporative condenser 2a: refrigerant inlet header
2b: refrigerant outflow header 21: refrigerant inlet
22: refrigerant outlet 3a: refrigerant vertical circulation tube
3b: refrigerant vertical return pipe 31: upper partition
32: middle partition 33: lower partition
4: horizontal refrigerant pipe 5a: cooling water inlet header
5b: Cooling water outlet header 51: Cooling water inlet
52: cooling water outlet 6a: cooling water vertical circulation pipe
6b: cooling water vertical flow pipe 61: partition
7: coolant horizontal circulation pipe 71: support
8a, 8b: Heat exchange panel 81a, 81b: Cover part
82a, 82b: flat part 9: condenser case
91: water tank 92: pump
93: water pipe

Claims (4)

The refrigerant inlet header 2a in which the refrigerant inlet 21 is formed, and the refrigerant outlet header 2b in which the refrigerant outlet 22 is formed are laid up and down,
The refrigerant inlet header 2a and the refrigerant outlet header 2b are provided with a plurality of refrigerant vertical circulation tubes 3a connected in a vertical manner at regular intervals.
The plurality of refrigerant vertical circulation pipe (3a) and the plurality of refrigerant vertical circulation pipe (3b) is formed with a plurality of refrigerant spherical circulation pipe (4) for connecting to each other,
Flat parts 82a and 82b welded to each other with the cover parts 81a and 81b installed to be in close contact with the plurality of refrigerant horizontal circulation pipes 4 are formed at regular intervals up and down. Two heat exchange panels (8a) and (8b) are provided to evaporate the refrigerant to be circulated to the plurality of refrigerant horizontal circulation tube (4) configured to exchange heat through the two heat exchange panels (8a) (8b) In the condenser,
The evaporative condenser,
A coolant inlet header 5b having a coolant inlet 51 and a coolant outlet 52 formed with a coolant inlet 52;
A plurality of cooling water vertical circulation pipes 6a formed at predetermined intervals so as to connect the cooling water inflow header 5a and the cooling water outlet header 5b;
The plurality of coolant vertical circulation pipes 6b are further formed at positions spaced at regular intervals from each of the plurality of coolant vertical circulation pipes 6a so as to be installed vertically with the plurality of coolant vertical circulation pipes 6a. It contains something
Here, it is configured to further include a plurality of cooling water horizontal circulation pipe (7) connecting the plurality of cooling water vertical circulation pipe (6a) and a plurality of cooling water vertical circulation pipe (6b),
The plurality of cooling water horizontal circulation pipes 7 are provided in close contact with the cover portions 81a and 81b of the heat exchange panels 8a and 8b in a state where the flat portions 82a and 82b are butt-welded. It is installed so as to penetrate the inside of each refrigerant horizontal circulation tube (4) without contacting the inner surface of each of the refrigerant horizontal circulation tube (4), both ends of the plurality of cooling water vertical circulation tube (6a) and the cooling water vertical circulation tube ( 6b) Evaporative condenser of the refrigerating device, characterized in that configured to connect in communication with each. delete delete delete

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