KR101727914B1 - Heat exchanger - Google Patents

Abstract

The heat exchanger of the present invention comprises: a case having a space formed therein; A top cover coupled to an upper portion of the case; A lower cover coupled to a lower portion of the case; A cooling water inflow pipe having an outlet end for guiding the cooling water flowing into the space and discharging the cooling water; A tube through which the refrigerant that is heat-exchanged with the cooling water passes; And a cooling water discharge pipe for guiding the cooling water flowing out of the space and having an inlet end through which the cooling water flows, wherein the tube includes a spiral tube portion wound in a spiral shape and the inlet end is separated from the top cover on the lower side of the top cover The height of the inlet end is higher than the height of the upper end of the spiral tube portion and the height between the outlet end and the lower cover is lower than the height between the inlet end and the lower cover to enable compactness while minimizing installation space, There is an advantage that can be.

Description

Heat exchanger

The present invention relates to a heat exchanger in which a tube is installed in a shell, and more particularly to a heat exchanger having a spiral tube portion in which a tube is spirally wound plural times.

Generally, a heat exchanger is a device for moving heat between two fluids, and is widely used for cooling, heating, and hot water supply.

The heat exchanger functions as a waste heat recovering heat exchanger for recovering the waste heat or as a cooler for cooling the hot fluid or as a condenser for condensing the vapor or as an evaporator for evaporating the coolant fluid .

Various types of heat exchangers may be used, including a tube through which the first fluid passes, a finned tube heat exchanger with the fin provided on the tube, a shell through which the first fluid passes, and a second fluid through which heat exchange with the first fluid passes A dual tube heat exchanger having an inner tube through which the first fluid passes and a second fluid that undergoes heat exchange with the first fluid and surrounds the inner tube and has an outer tube; And a plate heat exchanger in which the fluid passes through the heat transfer plate.

 In the shell-type heat exchanger of the heat exchanger, a shell may be formed long in the horizontal direction, a plurality of tubes may be arranged in the longitudinal direction in the shell, and the first fluid as cooling water may flow into the shell and then out of the shell And the second fluid, which is a refrigerant, can be cooled by the cooling water while passing through the tube. The shell may be formed such that a cooling water inflow portion into which the cooling water flows into the shell is protruded to the outside and a cooling water inflow passage that guides the cooling water to the cooling water inflow portion may be connected to the cooling water inflow portion. The shell may have a cooling water outlet portion through which the cooling water is discharged to the outside of the shell, and a cooling water discharge passage that guides the cooling water discharged from the cooling water discharge portion may be connected to the cooling water discharge portion.

KR 10-2011-0128709 A (2011.11.30)

 The heat exchanger according to the related art is arranged long in the horizontal direction to occupy a large space for installation, and a plurality of tubes having straight tubes are provided to have a large number of tubes and a separate tube sheet for fixing a plurality of tubes is required, There is a problem that it can not be converted.

According to an aspect of the present invention, there is provided a heat exchanger including: a case having a space therein; A top cover coupled to an upper portion of the case; A lower cover coupled to a lower portion of the case; A cooling water inflow pipe having an outlet end for guiding cooling water flowing into the space and discharging cooling water; A tube through which the refrigerant that is heat-exchanged with the cooling water passes; And a cooling water discharge pipe through which the cooling water flowing out of the space is guided and having an inlet end through which cooling water flows, the tube including a spiral tube portion spirally wound in the space, and the inlet end is provided on the lower side of the top cover Wherein the height of the inlet end is higher than the height of the upper end of the spiral tube portion and the height between the outlet end and the lower cover is lower than the height between the inlet end and the lower cover.

The height between the inlet end and the top cover may be 0.1 to 0.2 times the case height.

The height between the inlet end and the top cover may be 0.1 to 0.15 times the case height.

The cooling water inflow pipe, the cooling water outflow pipe and the tube may extend through the lower cover and extend to the lower side of the lower cover.

 The spiral tube portion may be located between the coolant discharge tube and the shell and may have a vertical central axis.

The vertical center axis may be located at a portion of the cooling water discharge pipe located inside the shell.

The plurality of tubes may be arranged in the shell, and the plurality of tubes may have different distances from the vertical center axis to the spiral tube.

And one of the plurality of tubes may be in contact with the cooling water discharge pipe.

The height of the outlet end may be lower than the height of the lower end of the spiral tube portion.

The case may be long in the vertical direction.

The present invention has the advantage that the space can be made compact while minimizing the installation space and the cooling water can be heat-exchanged with the spiral tube portion of the tube as much as possible.

In addition, there is an advantage that the freezing of the cooling water can be minimized and the heat transfer amount between the cooling water and the coolant can be increased.

 In addition, there is an advantage that the tube can be cleaned after the top cover and the case are separated, and the tube can be easily cleaned without separating the cooling water inflow pipe and the cooling water discharge pipe and the tube.

FIG. 1 is a schematic view of an air conditioner to which a heat exchanger according to an embodiment of the present invention is applied.
FIG. 2 is a side view showing an appearance of a heat exchanger according to an embodiment of the present invention,
Figure 3 is a view of the interior of one embodiment of a heat exchanger according to the present invention,
Fig. 4 is a bottom view of the shell shown in Fig. 2,
Fig. 5 is a perspective view of the pedestal shown in Fig. 2,
6 is a plan view showing the inside of a heat exchanger according to an embodiment of the present invention,
FIG. 7 is a graph showing a heat transfer amount according to the height between the inlet end and the top cover shown in FIG. 3 and the height ratio of the case.

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

1 is a block diagram of an air conditioner to which a heat exchanger according to an embodiment of the present invention is applied.

The air conditioner shown in Fig. 1 may include a compressor 2, a first heat exchanger 4, an expansion mechanism 6, and a second heat exchanger 8. [ The first heat exchanger (4) is capable of exchanging heat between the cooling water and the refrigerant. The cooling water can function as a cooling fluid that absorbs the heat of the refrigerant. The air conditioner includes a compressor 2 in which a refrigerant is compressed, a first heat exchanger 4 in which refrigerant is heat-exchanged with cooling water, an expansion mechanism 6 in which refrigerant expands, and a second heat exchanger 8).

The refrigerant can pass through the compressor (2), the first heat exchanger (4), the expansion mechanism (6), and the second heat exchanger (8) in this order. That is, the refrigerant compressed in the compressor 2 may be configured to be passed through the first heat exchanger 4, the expansion mechanism 6, and the second heat exchanger 8 in sequence and then recovered to the compressor 2 have. In this case, the first heat exchanger 4 can function as a condenser for condensing the refrigerant, the second heat exchanger 8 can function as an evaporator for evaporating the refrigerant, It is possible to absorb heat of the heat source.

The air conditioner may further include a flow switching valve (not shown) for sending the refrigerant compressed in the compressor 2 to the first heat exchanger 4 or the second heat exchanger 8. The air conditioner is configured such that the refrigerant compressed in the compressor 2 sequentially passes through the flow path switching valve, the first heat exchanger 4, the expansion mechanism 6, the second heat exchanger 8 and the flow path switching valve And a first circulation circuit that is recovered to the compressor (2). The air conditioner is a system in which the refrigerant compressed in the compressor 2 is supplied to the first heat exchanger 4, the second heat exchanger 8, the expansion mechanism 6, the first heat exchanger 4, And the second circulation circuit which is recovered to the compressor 2 after passing through the second circulation circuit. The first circulation circuit can be a circuit in the cooling operation in which the room is cooled by the second heat exchanger 8. The first heat exchanger 4 can function as a condenser for condensing the refrigerant, The unit 8 can function as an evaporator for evaporating the refrigerant. The second circulation circuit can be a circuit in the heating operation in which the room is heated by the second heat exchanger 8 and the second heat exchanger 8 can function as a condenser for condensing the refrigerant, The unit (4) can function as an evaporator for evaporating the refrigerant.

 The cooling water can be composed of a liquid fluid such as water or an antifreeze liquid, and the refrigerant can be usually composed of various refrigerants such as a freon refrigerant and a carbon dioxide refrigerant used in an air conditioner.

The compressor (2) may be composed of various compressors for compressing the refrigerant, and may be various compressors such as a rotary compressor, a scroll compressor, a screw compressor and the like. The compressor (2) may be connected to the first heat exchanger (4) and the compressor outlet flow path (3).

The first heat exchanger (4) may be constituted by a shell tubular heat exchanger. The first heat exchanger (4) may include a shell through which cooling water such as water or an antifreeze passes, and a tube through which the refrigerant passes. The first heat exchanger (4) may be connected to the expansion mechanism (6) and the first heat exchanger expansion device connection flow path (5). The first heat exchanger 4 will be described later in detail.

The expansion mechanism (6) may be a capillary tube or an electronic expansion valve in which the refrigerant expands. The expansion mechanism (6) may be connected to the second heat exchanger (8) and the expansion mechanism second heat exchanger connecting flow path (7).

The second heat exchanger 8 may be constituted by a fin tube type heat exchanger or a coil type heat exchanger through which the refrigerant passes. The second heat exchanger 8 may include a tube that exchanges heat with indoor air while passing the refrigerant. The second heat exchanger 8 may further include a fin which is a heat transfer member coupled with the tube. The second heat exchanger (8) can be connected to the compressor (2) and the compressor suction passage (9).

The air conditioner may include a heat treatment unit (10) connected to the first heat exchanger (4). The heat treatment unit 10 may be configured as a cooler for cooling the cooling water when the first heat exchanger 4 functions as a condenser for condensing the refrigerant. When the heat treatment unit 10 is configured as a cooler, the heat treatment unit 10 may include a cooling tower for cooling the cooling water. The heat treatment unit 10 can be connected to the first heat exchanger 4 and the water pipes 12 and 14. The first heat exchanger 4 can be connected to the heat treatment unit 10 and the water outlet pipe 12 and the cooling water of the first heat exchanger 4 can be discharged to the heat treatment unit 10 through the water outlet pipe 12 have. The first heat exchanger 4 can be connected to the heat treatment unit 10 and the intake pipe 14 and the cooling water of the heat treatment unit 10 can be supplied to the first heat exchanger 4 through the intake pipe 14 have. At least one of the heat treatment unit 10, the water outflow pipe 12 and the water intake pipe 14 may be provided with a circulation mechanism such as a pump for circulating the cooling water to the heat treatment unit 10 and the first heat exchanger 4.

The air conditioner may further include an indoor fan (16) for circulating air in the room to the second heat exchanger (8) and then discharging the air to the room again.

The compressor 2, the first heat exchanger 4, the expansion mechanism 6, the second heat exchanger 8, and the indoor fan 16 can be installed in one air conditioning unit, To the second heat exchanger (8), and then discharged back to the room through a duct or the like. The heat treatment unit 10 may be installed in addition to one air conditioning unit and may be connected to one air conditioning unit by water pipes 12 and 14. [

The compressor 2, the first heat exchanger 4, the expansion mechanism 6, the second heat exchanger 8 and the indoor fan 16 may be installed in a distributed manner in a plurality of air conditioning units I . The first heat exchanger 4 and the indoor fan 16 can be installed together in the indoor unit I and the compressor 2 and the first heat exchanger 4 can be installed together in the compression unit O Can be installed. The expansion mechanism (6) may be installed in at least one of the indoor unit (I) and the compression unit (O). The expansion mechanism (6) can be provided with one expansion mechanism in the indoor unit (I) or the compression unit (O). It is possible that a plurality of expansion mechanisms 6 may be provided, the first expansion mechanism may be installed in the indoor unit I, and the second expansion mechanism may be installed in the compression unit O. The first expansion mechanism may function as an outdoor expansion mechanism which is installed closer to the first heat exchanger (4) of the first heat exchanger (4) and the second heat exchanger (8). The second expansion mechanism can function as an indoor expansion mechanism that is installed closer to the first heat exchanger (4) and the second heat exchanger (8) of the second heat exchanger (8). The indoor unit I may be installed indoors. The compression unit (O) may be installed in a machine room, a basement or the like of a building or on the roof. The compression unit (O) can be connected to the heat treatment unit (10) by the water pipes (12) and (14).

 Hereinafter, the first heat exchanger 4 will be referred to as a heat exchanger.

FIG. 2 is a side view showing an outer appearance of a heat exchanger according to an embodiment of the present invention, FIG. 3 is an interior view of a heat exchanger according to the present invention, FIG. 4 is a bottom view And Fig. 5 is a perspective view of the pedestal shown in Fig.

The heat exchanger (4) comprises a shell (20); A cooling water inflow pipe (30) for guiding the cooling water (W) into the shell (20); A cooling water discharge pipe (40) through which the cooling water (W) is guided out of the shell (20); And a tube 70 through which the refrigerant that is heat-exchanged with the cooling water W passes.

The shell 20 may have a space 18 formed therein. In the space 18, the cooling water W can be chaotic and the tube 70 can be accommodated.

The shell (20) has a case (21) in which a space (18) is formed; And a top cover 22 coupled to an upper portion of the case 21. The shell 20 may include a lower cover 23 coupled with a lower portion of the case 21. [

 The case 21 can be vertically arranged vertically. The case 21 is not formed integrally with at least one of the top cover 22 and the lower cover 23 and is manufactured separately from the top cover 22 and the lower cover 23, (Not shown). The inner surface of the case 21 and the bottom surface of the top cover 22 and the top surface of the lower cover 23 are easily painted when the case 21, the top cover 22, . When the case 21 is integrally formed with one of the top cover 22 and the lower cover 23, the coating fluid may not easily flow uniformly over the entire inner wall of the case 21. [ On the other hand, when the case 21 is constructed separately from the top cover 22 and the lower cover 23, the coating fluid can be coated while the entire inner wall of the case 21 is uniformly flowing. The shell 20 is attached to the case 21, the top cover 22 and the lower cover 23 after the inner circumferential surface of the case 21, the bottom surface of the top cover 22 and the upper surface of the lower cover 23 are painted, Lt; / RTI >

The case 21 includes a hollow cylinder 21a in which a space 18 is formed, a first engaging portion 21b engaged with the top cover 22, and a second engaging portion 21b engaged with the lower cover 23 21c.

The hollow cylinder 21a may be formed in a hollow cylindrical shape.

The first coupling portion 21b may protrude from the upper end of the hollow cylinder 21a in a flange shape and may be formed with a coupling hole to be coupled to the top cover 22 by a coupling member 22a such as a bolt.

The second engaging portion 21c may protrude in a flange shape at the lower end of the hollow cylinder 21a and may be formed with a fastening hole that is fastened to the lower cover 23 by a fastening member 23a such as a bolt.

The top cover 22 may be formed of a plate, and may be formed in a disc shape. The top cover 22 is formed with a fastening hole corresponding to the fastening hole of the first fastening portion 21b and can be coupled with the first fastening portion 21b by a fastening member 22a such as a bolt. The top cover 22 may cover the upper opening surface of the case 21.

 The lower cover 23 may be formed as a plate, and may be formed in a disk shape. The lower cover 23 is formed with a coupling hole corresponding to the coupling hole of the second coupling portion 21c and can be coupled to the second coupling portion 21c by a coupling member 23a such as a bolt. The lower cover 22 can close the opening face of the lower side of the case 21.

The shell 20 can be formed with a space 18 between the case 21 and the top cover 22 and the lower cover 23 and the cooling water W is introduced into the space 18 ). ≪ / RTI > The cooling water W can be heat-exchanged with the tube 70 while flowing in the space 18.

The shell 20 may be provided with a cooling water inflow pipe through hole 24 through which the cooling water inflow pipe 30 passes. The shell 20 may be formed with a cooling water discharge pipe through-hole 25 through which the cooling water discharge pipe 40 passes. The shell 20 may be provided with a tube through hole 26 through which the tube 70 passes. The number of the tube through holes 26 may be the same as the number of the tubes 70.

The cooling water inflow pipe 30 guides the cooling water W flowing into the space 18 and an outlet end 32 through which the cooling water W is discharged into the space 18 can be formed. The cooling water inflow pipe 30 can penetrate the shell 20 such that the outlet end 32 is located inside the shell 20. The cooling water inflow pipe 30 is formed such that the height L1 between the outlet end 32 and the lower cover 23 is greater than the height L2 between the inlet end 42 and the lower cover 23, ≪ / RTI > The cooling water W flowing into the inside of the shell 20 through the cooling water inflow pipe 30 can be choked from the inner lower side of the shell 20. [ The cooling water inflow pipe 30 may be disposed so that the outlet end 32 is located at the inner lower portion of the shell 20. [ The cooling water inflow pipe 30 may be connected to the inlet pipe 14 shown in FIG. 1 at a portion of the cooling water inflow pipe 30 located outside the shell 20.

The cooling water discharge pipe 40 is guided by the cooling water W flowing out of the space 18 and may be formed with an inlet end 42 into which the cooling water W of the space 18 enters. The inlet end 42 can pass through the shell 20 with the shell 20 positioned inside. The cooling water W positioned at the inner lower portion of the shell 20 is not discharged through the cooling water discharge pipe 40 40, respectively. The inlet end 42 may be located on the inside upper side of the shell 20. The cooling water discharge pipe 40 may be connected to the water discharge pipe 12 shown in FIG. The inlet end 42 may be located on the underside of the top cover 22. The inlet end 42 may be positioned away from the top cover 22. The inlet end 42 may be spaced apart from the top cover 22 in the vertical direction. The cooling water W can flow into the cooling water discharge pipe 40 through the inlet end 42 when the water level inside the shell 20 is higher than the inlet end 42, An air layer A as an air receiving space may be formed. The heat exchanger 4 does not have a separate air vent for extracting air from the air layer A and the top cover 22 can cover the entire upper opening of the space 18. [ The height of the air layer A between the cooling water W and the shell 20 becomes higher as the height L3 between the inlet end 42 and the top cover 22 becomes higher and the height of the inlet end 42 The height of the air layer A between the cooling water W and the shell 20 becomes lower as the height L3 between the upper cover 22 and the top cover 22 is lower. When the height of the air layer (A) is lower than the proper range, it is difficult to secure sufficient free space in freezing the cooling water (W), and the internal pressure in the shell (20) On the other hand, if the height of the air layer A is higher than the proper range, the material ratio due to the height increase of the shell 20 can be increased. The cooling water W may leak between the case 21 and the top cover 22 due to vibration of the heat exchanger 4. [ The height L3 between the inlet end 42 and the top cover 22 of the heat exchanger 4 may be the height of the air layer A. [

The cooling water inflow pipe 30 and the cooling water discharge pipe 40 and the tube 70 may be arranged to pass through one of the case 21 and the top cover 22 and the lower cover 23. When the cooling water inflow pipe 30, the cooling water discharge pipe 40 and the tube 70 are arranged to pass through the lower cover 23, the heat exchanger 4 can be easily cleaned. The heat exchanger 4 can be separated from the case 21 in a state in which the cooling water inflow pipe 30, the cooling water discharge pipe 40 and the tube 70 are fixed to the lower cover 23, The case 21 can be separated from the lower cover 23. In a state in which the top cover 2 and the case 21 are separated and the cooling water inflow pipe 30, the cooling water discharge pipe 40 and the tube 70 are fixed to the lower cover 23, the operator inserts the heat exchanger 4 It can be easily cleaned. It is preferable that the cooling water inflow pipe 30 and the cooling water discharge pipe 40 and the tube 70 are arranged to pass through the lower cover 23 when considering the cleanability of the heat exchanger 4.

The heat exchanger (4) may include a pedestal (50) for supporting the shell (20). The pedestal 50 may include a fastening portion 52 to which the shell 20 is fastened. The fastening portions 52 may be formed in the shape of a plate, and may be disposed horizontally. The shell 20 can be lifted up to the fastening portion 52 and can be engaged with the fastening portion 52.

The fastening part 52 may be formed with a fastening hole 54 in which the shell 20 is fastened by a fastening member 23a such as a bolt. The fastening part 52 may be formed with a through hole 55 through which at least one of the cooling water inflow pipe 30 and the cooling water inflow pipe 40 passes. The through hole 55 of the fastening portion 52 can be formed of a cooling water inflow pipe through hole through which the cooling water inflow pipe 30 passes and a cooling water discharge pipe through hole through which the cooling water discharge pipe 40 passes. One through hole 55 is formed in the fastening portion 52 and the cooling water inflow pipe 30 and the cooling water discharge pipe 40 can be passed through one through hole 55 together. When one through hole 55 is formed in the fastening portion 52, one through hole 55 may be formed long in the horizontal direction. One through hole 55 may be formed to be open at the side of the fastening portion 52. One through hole 55 may be formed to open the lower side of the cooling water inflow pipe through hole 24 of the shell 20 and the lower side of the cooling water discharge pipe through hole 25 of the shell 20. The fastening part 52 may be formed with a tube through hole 56 through which the tube 70 passes. The pedestal 50 may include a support for supporting the fastening portion 52. The support may include a plurality of legs 57, 58, 59, 60 that support the fastening portion 52. A part of the cooling water inflow pipe 30, a part of the cooling water discharge pipe 40 and a part of the tube 70 are positioned below the fastening plate 52 when the heat exchanger 4 is put on the fastening part 52 . The heat exchanger 4 can extend both the cooling water discharge pipe 30 and the cooling water discharge pipe 40 and the tube 70 to the lower portion of the shell 20. [

The tube 70 may include a helical tube portion 74 positioned in the space 18 and helically wound. A clearance 73 may be formed between the turn 71 and the turn 72 in the spiral tube portion 74. The helical tube portion 74 may be formed in a coil shape as a whole. The spiral tube portion 74 may be positioned between the cooling water discharge tube 40 and the shell 20 and may have a vertical central axis VX. The vertical center axis VX may be located at a portion of the cooling water discharge pipe 40 located inside the shell 20. [ The vertical center axis VX may coincide with the center axis of the portion of the cooling water discharge pipe 40 located inside the shell 20. [ The plurality of turns 71 and 72 can be wound with the same distance L5 from the vertical center axis VX. The spiral tube portion 74 may have at least ten turns. The spiral tube portion 74 can be wound continuously in the clockwise direction or wound continuously in the counterclockwise direction. The plurality of turns (71) and (72) can be wound to be spaced apart in the vertical direction, and a gap (73) can be formed between the plurality of turns (71) and (72). The cooling water W flows through the gap 73 in the space between the shell 20 and the spiral tube portion 74 and flows into the space inside the spiral tube portion 74 or the gap 73 in the space inside the spiral tube portion 74 And may flow into the space between the shell 20 and the spiral tube portion 74.

The cooling water W entering the inlet end 42 without minimizing the heat exchange with the spiral tube portion 74 can be minimized when the height of the upper end of the spiral tube portion 74 is lower than the inlet end 42 of the cooling water discharge pipe 40 And the height L5 between the upper end of the spiral tube portion 74 and the lower cover 23 is preferably lower than the height L2 between the inlet end 42 and the lower cover 23. [ That is, the height of the inlet end 42 may be higher than the height of the upper end of the spiral tube portion 74. The spiral tube portion 74 may be installed such that a portion thereof is positioned above the outlet end 32 of the cooling water inflow pipe 30. [ The outlet end 32 may be located below the spiral tube portion 74. The height of the outlet end 22 may be lower than the height of the lower end of the spiral tube portion 74.

 The tube 70 may include a straight tube portion 75 extending from the helical tube portion 74 and formed in a straight tube shape. The straight pipe portion 75 may be formed by bending at the lowermost turn among the spiral pipe portions 74. The straight pipe portion 75 may be formed by bending in a turn located on the uppermost side of the spiral pipe portion 74. The straight pipe portion 74 may be disposed parallel to the vertical center axis VX.

FIG. 6 is a plan view showing the inside of a heat exchanger according to an embodiment of the present invention.

The plurality of tubes 70A and 70B may be disposed inside the shell 20. [ The plurality of tubes 70A and 70B may have different distances from the vertical center axis VX to the spiral tube portion 74. [ It is possible for the tube 70 to be connected in series with a pair of tubes 70A and 70B having different distances from the vertical center axis VX. The tube 70 can be connected to the connection tube 70C by a pair of tubes 70A and 70B having different distances from the vertical center axis VX. The connection tube 70C may be formed in a U-shape. The connection tube 70c may be installed at a height at least partially immersed in the cooling water W. The pair of tubes 70A and 70B and the connecting tube 70C can constitute one heat transfer tube P. [ The refrigerant is sequentially passed through the straight pipe portion 75 and the helical pipe portion 74 of one of the pair of tubes 70A and 70B and then flows to the connecting tube 70C, And then flows out of the shell 20 after sequentially passing through the spiral tube portion 74 and the straight pipe portion 75 of the other one of the first and second end portions 70A and 70B. The refrigerant is heat-exchanged with the cooling water W while passing through one of the pair of tubes 70A and 70B and then exchanged with the cooling water W while passing through the connection tube 70C, It is possible to exchange heat with the cooling water W while passing through the other one of the heat exchanging tubes 70A and 70B. It is possible for the tube 70 to be provided with a plurality of pairs of tubes 70A and 70B having different distances from the vertical center axis VX and connected in series.

The spiral tube portion 74 of one of the plurality of tubes 70A and 70B can be fixed to the cooling water discharge tube 40. [ The plurality of tubes 70A and 70B can be fixed to the cooling water discharge pipe 40 while the tubes closest to the cooling water discharge pipe 40 are in contact with the cooling water discharge pipe 40. [ The tube closest to the cooling water discharge pipe 40 may be disposed so as to surround the cooling water discharge pipe 40. The plurality of tubes 70A and 70B may be such that the tube closest to the shell 20 is not in contact with the inner surface of the shell 20.

FIG. 7 is a graph showing a heat transfer amount according to the height between the inlet end and the top cover shown in FIG. 3 and the height ratio of the case.

7 is a graph illustrating the heat transfer performance of the heat exchanger according to the height ratio change with respect to the height ratio having the optimal heat transfer performance, in a non-dimensional manner.

The heat exchanger 4 has a structure in which the cooling water inflow pipe 30 has a water flow rate of 2.7 m / sec, a water mass flow rate of 1.6 kg / sec and a water volume flow rate of 96 LPM, And the heat transfer amount of the refrigerant can be measured. In this case, when the height ratio X is approximately 0.13, the highest heat transfer performance is obtained. When the height ratio X is 0.13, , It can be shown as shown in FIG.

The height L3 between the inlet end 42 and the top cover 22 of the heat exchanger 4 may be 0.1 to 0.2 times the height L4 of the case 21. [ That is, the height L3 between the inlet end 42 and the top cover 22 and the height ratio (X = L3 / L4) of the case 21 can be 0.1 to 0.2.

 When the height L3 between the inlet end 42 and the top cover 22 is less than 0.1 times the height L4 of the case 21, the heat transfer amount decreases as the height ratio is lowered. When the height ratio X is less than 0.8 The region can be a high-frequency wave region A in which the height of the air layer A is too low. When the height L3 between the inlet end 42 and the top cover 22 is greater than 0.2 times the height L4 of the case 21, the heat transfer amount may be reduced to 90% or less of the maximum heat transfer amount, The height L3 between the top cover 42 and the top cover 22 is preferably 0.1 to 0.2 times the height L4 of the case 21. [

The height L3 between the inlet end 42 and the top cover 22 can maintain 97% or more of the heat transfer amount relative to the maximum heat transfer amount when the height L4 is 0.1 to 0.15 times the height L4 of the case 21, The height L3 between the top cover 22 and the top cover 22 is most preferably set between 0.1 and 0.15 times the height L4 of the case 21. [

Hereinafter, the operation of the present invention will be described.

First, the refrigerant can pass through the tube (70) and can be heat-exchanged with the cooling water while passing through the tube (70). The refrigerant can be discharged to the outside of the heat exchanger 4 after sequentially passing through the plurality of tubes 70A and 70B.

The cooling water may flow into the inner lower portion of the shell 20 through the cooling water inflow pipe 30 and may flow while rising inside the shell 20. The cooling water flowing into the space 18 through the outlet end 32 of the cooling water discharge pipe 30 is lifted up inside the shell 20 and flows into the gap 73 between the turn 71 and the turn 72 of the spiral tube portion 74 And can be heat exchanged with the tube 70. The cooling water can be exchanged with the entire spiral tube portion 74 while being raised to a level higher than the upper end of the spiral tube portion 74 and then introduced into the inlet end 42 of the cooling water discharge tube 40 at a position higher than the spiral tube portion 74 The cooling water can be discharged to the outside of the heat exchanger 4 through the cooling water discharge pipe 40. The cooling water passing through the cooling water discharge pipe (40) can heat-exchange a tube in contact with the cooling water discharge pipe (40) while being in contact with the tube in contact with the cooling water discharge pipe (40).

The heat exchanger 4 can heat-exchange the cooling water and the refrigerant while maintaining the optimal heat transfer amount, and the freezing of the cooling water can be prevented by the appropriate height of the air layer A even if freezing of the cooling water occurs due to low temperature.

The heat exchanger 4 can be detached from the lower cover 23 for the case 70 to clean the case. The operator does not remove the tube 70 from the lower cover 23 while separating the case 21 from the lower cover 23 without separating the cooling water inflow pipe 30 and the cooling water discharge pipe 40 and the tube 70 from the lower cover 23. [ It can be cleaned with a washing machine such as a brush.

4: Heat exchanger 20: Shell
21: Case 22: Top cover
23: Lower cover 30: Cooling water inflow pipe
32: outlet end 40: cooling water outlet pipe
42: inlet end 70: tube
74: Spiral tube

Claims (11)

A case having a space therein;
A top cover coupled to an upper portion of the case;
A lower cover coupled to a lower portion of the case;
A cooling water inflow pipe having an outlet end through which the cooling water flows out into the space;
A tube through which the refrigerant that is heat-exchanged with the cooling water passes;
And a cooling water discharge pipe having an inlet end through which the cooling water flowing out of the space flows,
The tube having a spiral tube portion positioned in the space and wound in a spiral shape; A straight tube portion extending from the helical tube portion and formed into a straight tube shape,
The cooling water inflow pipe, the cooling water discharge pipe, and the tube extend through the lower cover to the lower side of the lower cover,
Wherein the inlet end is positioned below the top cover to be spaced apart from the top cover,
The height of the inlet end is higher than the height of the upper end of the spiral tube portion,
The height between the outlet end and the lower cover is lower than the height between the inlet end and the lower cover,
The height of the outlet end is lower than the height of the lower end of the spiral tube portion,
Wherein the straight pipe portion is formed by bending in a turn located at the lowermost side of the spiral pipe portion,
Wherein the height between the inlet end and the top cover is 0.1 to 0.2 times the height of the case. delete The method according to claim 1,
And the height between the inlet end and the top cover is 0.1 to 0.15 times the case height. delete The method according to claim 1,
Further comprising a shell including the case, the top cover, and the lower cover,
The spiral tube portion being located between the cooling water discharge tube and the shell and having a vertical central axis. 6. The method of claim 5,
And the vertical center axis is located at a portion of the cooling water discharge tube located inside the shell. 6. The method of claim 5,
Wherein a plurality of the tubes are disposed inside the shell and a plurality of tubes have different distances from the vertical center axis to the spiral tube portions. 8. The method of claim 7,
And one of the plurality of tubes is in contact with the cooling water discharge pipe. delete The method according to claim 1,
The case is a vertically long heat exchanger. delete

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