JP2014139505A - Heat exchanger device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a heat exchanger device capable of accelerating heat exchange between a high-temperature fluid and a low-temperature fluid, improving heat transfer efficiency, and attaining quick temperature reduction.SOLUTION: A heat exchanger device includes: at least two first cooling/condensation plates 2; at least two second cooling/condensation plates 3; at least two third cooling/condensation plates 4; and at least two fourth cooling/condensation plates 5. Each of the first cooling/condensation plates 2, each of the second cooling/condensation plates 3, each of the third cooling/condensation plates 4, and each of the fourth cooling/condensation plates 5 include: inlet holes 21, 31, 41, and 51; outlet holes 22, 32, 42, and 52; and notch ports 23, 33, 43, and 53, respectively. The adjacent notch ports 23, 33, and 43 arranged along an attachment path constitute an inlet notch groove, and the adjacent notch ports 33, 43, and 53 constitute an outlet notch groove. A high-temperature fluid flows into the heat exchanger device via the inlet notch groove, circulates along a heat flow circulation path, and flows out from the outlet notch groove. A low-temperature fluid flows into the heat exchanger device via the inlet groove 21, circulates along a cold flow circulation path, and flows out from the outlet hole 22.

Description

  The present invention relates to a heat exchange apparatus including a plurality of cooling condensing plates.

As the climate gets hotter, air conditioning systems are frequently used to lower the temperature, how to improve the efficiency of air conditioning systems and reduce power consumption. Achieving environmental protection effects is a goal of contractors.
For example, in Patent Document 1, a refrigerant, a pre-cooling device, a recuperation cooling device, and a refrigerant heat radiating device are operated, so that the refrigerant heat radiating device and the pre-cooling device are combined with the fan. Disclosed is a “heat radiator structure” that lowers the temperature until it becomes the same as room temperature by releasing heat energy and then cooling and reheating the heat energy in the radiator body together with the recuperation cooling device. ing.

Taiwan Utility Model Registration No. M438927 Specification

  The problem to be solved by the present invention is to provide a heat exchange device that can accelerate heat exchange between a high-temperature fluid and a low-temperature fluid, can improve heat conduction efficiency, and can achieve rapid temperature drop. It is in.

  The heat exchange apparatus of the present invention includes at least two first cooling condensing plates provided with at least one first inlet hole, at least one first outlet hole, and at least two first notches, and at least one second. At least two second cooling condensing plates provided with an inlet hole, at least one second outlet hole and at least two second notches, at least one third inlet hole, at least one third outlet hole and at least two At least two third cooling condensing plates provided with three third notches, at least two fourth cooling holes provided with at least one fourth inlet hole, at least one fourth outlet hole and at least two fourth notches. 4 cooling condenser plates. The first cooling condensing plate, the second cooling condensing plate, the third cooling condensing plate, and the fourth cooling condensing plate are disposed along the attachment path, and are adjacent to each other at the first notch opening, the second notching opening, and the third notching plate. The notch constitutes an inlet notch groove, the second notch, the third notch and the fourth notch adjacent to each other constitute an outlet notch, and a high-temperature fluid passes through the inlet notch and the heat exchange device Flows into the heat flow path, flows out from the outlet notch groove, and the low-temperature fluid flows into the heat exchange device through the inlet hole of the cooling condenser plate, And flows out from the outlet hole of the cooling condenser plate.

The following configuration may be adopted.
An upper plate and a lower plate are further provided, each of the first cooling condensing plate, the second cooling condensing plate, the third cooling condensing plate, and the fourth cooling condensing along the attachment path. Configuration provided on both sides of the combination with the plate.
The first cooling condensing plate, the second cooling condensing plate, the third cooling condensing plate, and the fourth cooling condensing plate are repeatedly arranged in this order along the attachment path.
The second cooling condensing plate is located between the first cooling condensing plate and the third cooling condensing plate, and the third cooling condensing plate includes the second cooling condensing plate, the fourth cooling condensing plate, The first cooling condensing plate and the fourth cooling condensing plate are positioned on both sides of the second cooling condensing plate and the third cooling condensing plate, respectively.

The first cooling condensing plate further includes at least one first circulation hole and at least one second circulation hole, and the second cooling condensing plate includes at least one third circulation hole and at least one one. A fourth circulation hole, and the third cooling condenser plate further comprises at least one fifth circulation hole and at least one sixth circulation hole, wherein the fourth cooling condenser plate is at least 1 The configuration further comprising one seventh flow hole and at least one eighth flow hole.
The inlet notch groove is positioned between the two adjacent fourth cooling condenser plates, and the outlet notch groove is positioned between the two adjacent first cooling condenser plates.
The fourth cooling condensing plate and the first cooling condensing plate are configured to be mirror-symmetrically rotated 180 degrees about the attachment path.
The third cooling condensing plate and the second cooling condensing plate are configured to be mirror-symmetrically rotated 180 degrees about the attachment path.

The first cooling condensing plate further includes at least one first opening, the second cooling condensing plate further includes at least one second opening, and the third cooling condensing plate includes at least one third opening. The fourth cooling condenser plate further includes at least one fourth opening.
The upper plate further includes at least one fifth inlet hole and at least one fifth outlet hole.
In this case, the projected areas of the fifth inlet hole, the first inlet hole, the second inlet hole, the third inlet hole, and the fourth inlet hole overlap.
The fifth outlet hole, the first outlet hole, the second outlet hole, the third outlet hole, and the fourth outlet hole have overlapping projection areas.

Projection regions of the first flow hole, the second flow hole, the third flow hole, and the fourth flow hole partially overlap, and the third flow hole and the fourth flow hole The projection area of the hole, the fifth flow hole, and the sixth flow hole partially overlaps, the fifth flow hole, the sixth flow hole, the seventh flow hole, and the Projection areas with the eighth flow holes partially overlap, and projection areas with the seventh flow holes, the eighth flow holes, the first flow holes, and the second flow holes are partially overlapped. Duplicate configuration.
Projection areas of the first opening and the second opening partially overlap, projection areas of the second opening and the third opening partially overlap, and the third opening and the A configuration in which a projection area with the fourth opening partially overlaps and a projection area with the fourth opening and the first opening partially overlaps.

A configuration in which the high-temperature fluid sequentially passes through the fourth cooling condensing plate, the third cooling condensing plate, the second cooling condensing plate, and the first cooling condensing plate along the heat flow flow path.
A configuration in which the low-temperature fluid sequentially passes through the first cooling condenser plate, the second cooling condenser plate, the third cooling condenser plate, and the fourth cooling condenser plate along the cold flow path.
The heat flow flow path and the cold flow flow path are perpendicular to each other.
The cold flow path and the attachment path are parallel to each other.

  According to the present invention, heat exchange between a high-temperature fluid and a low-temperature fluid is efficiently performed and rapid temperature reduction is possible, so that the operating efficiency of the air conditioning system can be improved, power consumption can be saved, and energy saving and Achieve carbon dioxide reduction and contribute to environmental protection.

It is a perspective view of the heat exchange apparatus which shows the Example of this invention. It is a perspective view of an upper board, a cooling condensation board, and a lower board concerning the example of the present invention. It is a top view of the upper board, cooling condensation board, and lower board concerning the example of the present invention. It is a schematic diagram which shows the state which the projection area | region of the exit hole of the upper plate, the 1st cooling condensation plate, and the 2nd cooling condensation plate which concerns on the Example of this invention, an entrance hole, a circulation hole, and an opening has overlapped. It is a principal part perspective view showing the flow state of the high temperature fluid of the heat exchange apparatus which shows the Example of this invention. It is AC sectional drawing of FIG. It is a principal part perspective view showing the flow state of the low temperature fluid of the heat exchange apparatus which shows the Example of this invention. It is BD sectional drawing of FIG.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.
1 is a perspective view of a heat exchange device, FIG. 2 is a perspective view showing an upper plate, a cooling condensing plate, and a lower plate of the heat exchanging device, and FIG. 3 is an upper plate, cooling condensing of the heat exchanging device. FIG. 4 is a plan view showing the plate and the lower plate, and FIG. 4 shows overlapping projection areas of the upper plate of the heat exchange device row, the outlet holes, the inlet holes, the flow holes and the openings of the first cooling condenser plate and the second cooling condenser plate. It is a schematic diagram which shows the state which is carrying out.

As shown in FIGS. 1 to 4, the heat exchange device 1 of the present invention includes at least two first cooling condensing plates 2, at least two second cooling condensing plates 3, and at least two third cooling plates. The condenser plate 4 and at least two fourth cooling condenser plates 5 are provided.
The first cooling condenser plate 2 is provided with at least one first inlet hole 21, at least one first outlet hole 22, and at least two first notches 23. The second cooling condenser plate 3 is provided with at least one second inlet hole 31, at least one second outlet hole 32, and at least two second notches 33. The third cooling condenser plate 4 is provided with at least one third inlet hole 41, at least one third outlet hole 42, and at least two third notches 43. The fourth cooling condenser plate 5 is provided with at least one fourth inlet hole 51, at least one fourth outlet hole 52, and at least two fourth notches 53.

  The second cooling condensing plate 3 is located between the first cooling condensing plate 2 and the third cooling condensing plate 4, and the third cooling condensing plate 4 includes the second cooling condensing plate 3, the fourth cooling condensing plate 5, and the like. The first cooling condensing plate 2 and the fourth cooling condensing plate 5 are located on both sides of the second cooling condensing plate 3 and the third cooling condensing plate 4, respectively, and the adjacent first notches 23, The second cutout 33 and the third cutout 43 constitute the inlet cutout groove 8, and the adjacent second cutout 33, the third cutout 43 and the fourth cutout 53 constitute the outlet cutout groove 9. . The inlet notch groove 8 is located between the two adjacent fourth cooling condenser plates 5, and the outlet notch groove 9 is located between the two adjacent first cooling condenser plates 2. The first cooling condensing plate 2, the second cooling condensing plate 3, the third cooling condensing plate 4 and the fourth cooling condensing plate 5 are repeatedly arranged in this order along the attachment path L1. The fourth cooling condensing plate 5 and the first cooling condensing plate 2 are arranged in mirror symmetry rotated by 180 degrees about the attachment path L1, and the third cooling condensing plate 4 and the second cooling condensing plate 3 are They are arranged mirror-symmetrically rotated 180 degrees around the attachment path L1.

  In the embodiment of the present invention, the first cooling condensing plate 2 further includes at least one first circulation hole 24 and at least one second circulation hole 25, and the second cooling condensing plate 3 includes at least one one. The third cooling hole 4 further includes a third flow hole 34 and at least one fourth flow hole 35, and the third cooling condenser plate 4 includes at least one fifth flow hole 44 and at least one sixth flow hole 45. The fourth cooling condenser plate 5 further includes at least one seventh circulation hole 54 and at least one eighth circulation hole 55. In the present embodiment, the first cooling condensing plate 2 further includes at least one first opening 26, the second cooling condensing plate 3 further includes at least one second opening 36, and the third cooling condensing plate 4 includes , At least one third opening 46 is further provided, and the fourth cooling condenser plate 5 is further provided with at least one fourth opening 56.

  In the embodiment of the present invention, the heat exchange device 1 further includes an upper plate 6 and a lower plate 7. The upper plate 6 includes at least one fifth inlet hole 61 and at least one fifth outlet hole 62. The upper plate 6 and the lower plate 7 are each a combination of the first cooling condensing plate 2, the second cooling condensing plate 3, the third cooling condensing plate 4 and the fourth cooling condensing plate 5 along the attachment path L1. The projection areas of the fifth inlet hole 61, the first inlet hole 21, the second inlet hole 31, the third inlet hole 41, and the fourth inlet hole 51 overlap, The overlapping area is an area for allowing fluid to pass through. Further, the projected areas of the fifth outlet hole 62, the first outlet hole 22, the second outlet hole 32, the third outlet hole 42, and the fourth outlet hole 52 are overlapped, and the overlapped area is This is a region for allowing fluid to pass through. Projection regions of the first flow hole 24, the second flow hole 25, the third flow hole 34, and the fourth flow hole 35 partially overlap, and the overlap region allows fluid to pass therethrough. It is an area. Projection areas of the third flow hole 34, the fourth flow hole 35, the fifth flow hole 44, and the sixth flow hole 45 partially overlap, and the overlap area allows fluid to pass therethrough. It is an area. Projection areas of the fifth flow hole 44, the sixth flow hole 45, the seventh flow hole 54, and the eighth flow hole 55 partially overlap, and the overlap area allows fluid to pass therethrough. It is an area. Projection regions of the seventh flow hole 54, the eighth flow hole 55, the first flow hole 24, and the second flow hole 25 partially overlap, and the overlap region allows fluid to pass therethrough. It is an area. The projection areas of the first opening 26 and the second opening 36 partially overlap, and the overlapping area is an area for allowing fluid to pass through. The projection areas of the second opening 36 and the third opening 46 partially overlap, and the overlapping area is an area for allowing fluid to pass therethrough. The projection areas of the third opening 46 and the fourth opening 56 partially overlap, and the overlapping area is an area for allowing fluid to pass therethrough. The projection areas of the fourth opening 56 and the first opening 26 partially overlap, and the overlapping area is an area for allowing fluid to pass therethrough.

  FIG. 5 is a perspective view showing the flow state of the high-temperature fluid in the heat exchange device, FIG. 6 is a cross-sectional view taken along the line AC of the heat exchange device showing the flow state of the high-temperature fluid, and FIG. FIG. 8 is a BD cross-sectional view of the heat exchange device showing the flow state of the cryogenic fluid.

  As shown in FIGS. 5 to 8, the high-temperature fluid F <b> 1 flows into the heat exchange device 1 through the inlet notch groove 8 along the heat flow path L <b> 2, and the fourth opening 56 and the first opening 26 partially Overlapping projection areas, partially overlapping projection areas of the third opening 46 and the fourth opening 56, partially overlapping projection areas of the second opening 36 and the third opening 46, the first opening 26 and the first opening. Passing through the projection area partially overlapping with the two openings 36, sequentially passing through the fourth cooling condenser plate 5, the third cooling condenser plate 4, the second cooling condenser plate 3 and the first cooling condenser plate 2, It flows out from the outlet notch groove 9.

  Further, the low-temperature fluid F2 flows into the heat exchange device 1 through the fifth inlet hole 61 of the upper plate 6 along the cold flow path L3, and the first inlet hole 21, the second inlet hole 31, and the third inlet. A partially overlapping projection region of the hole 41, the fourth inlet hole 51, the first flow hole 24, the second flow hole 25, the third flow hole 34, and the fourth flow hole 35, the third flow hole 34 A partially overlapping projection region of the fourth flow hole 35, the fifth flow hole 44, and the sixth flow hole 45, the fifth flow hole 44, the sixth flow hole 45, and the seventh flow hole 54. And the projection region partially overlapping with the eighth circulation hole 55, the seventh circulation hole 54, the eighth circulation hole 55, the first circulation hole 24, and the second circulation hole 25 partially overlapping. It passes through the projection area, the first outlet hole 22, the second outlet hole 32, the third outlet hole 42, and the fourth outlet hole 52 and reaches the lower plate 7, and the fourth cooling condenser plate 5 and the third Condensing plate 4, via a second cooling condenser plate 3 and the first cooling condenser plate 2 sequentially, and flows from the fifth outlet hole 62 of the upper plate 6.

  Since the high temperature fluid F1 and the low temperature fluid F2 cause heat exchange by heat conduction in the order of the first cooling condensing plate 2, the second cooling condensing plate 3, the third cooling condensing plate 4, and the fourth cooling condensing plate 5, the high temperature fluid F1. When the gas flows into the inlet notch groove 8 and flows out from the outlet notch groove 9, a temperature change can be caused. The heat flow path L2 and the cold flow path L3 are perpendicular to each other, and the cold flow path L3 and the attachment path L1 are parallel to each other.

1: heat exchange device 2: first cooling condenser plate 21: first inlet hole 22: first outlet hole 23: first notch 24: first circulation hole 25: second circulation hole 26: first opening 3: first 2 cooling condenser plate 31: second inlet hole 32: second outlet hole 33: second notch opening 34: third circulation hole 35: fourth circulation hole 36: second opening 4: third cooling condenser plate 41: third Inlet hole 42: Third outlet hole 43: Third notch 44: Fifth flow hole 45: Sixth flow hole 46: Third opening 5: Fourth cooling condenser plate 51: Fourth inlet hole 52: Fourth outlet hole 53: Fourth cutout 54: Seventh flow hole 55: Eighth flow hole 56: Fourth opening 6: Upper plate 61: Fifth inlet hole 62: Fifth outlet hole 7: Lower plate 8: Inlet cutout groove 9: Outlet notch groove F1: High temperature fluid F2: Low temperature fluid L1: Mounting path L2: Heat flow path L3: Cold flow path

Claims (18)

A heat exchange device,
At least two first cooling condensing plates provided with at least one first inlet hole, at least one first outlet hole and at least two first notches, at least one second inlet hole, at least one second. At least two second cooling condensing plates provided with an outlet hole and at least two second notches, at least one third inlet hole, at least one third outlet hole and at least two third notches are provided. And at least two third cooling condensing plates, and at least two fourth cooling condensing plates provided with at least one fourth inlet hole, at least one fourth outlet hole, and at least two fourth notches. ,
The first cooling condensing plate, the second cooling condensing plate, the third cooling condensing plate, and the fourth cooling condensing plate are disposed along the attachment path, and are adjacent to each other at the first notch opening, the second notching opening, and the third notching plate. The notch constitutes an inlet notch groove, the second notch, the third notch and the fourth notch adjacent to each other constitute an outlet notch, and a high-temperature fluid passes through the inlet notch and the heat exchange device Flows into the heat flow path, flows out from the outlet notch groove, and the low-temperature fluid flows into the heat exchange device through the inlet hole of the cooling condenser plate, The heat exchange device is characterized by flowing along the flow path and flowing out from the outlet hole of the cooling condensing plate.   An upper plate and a lower plate are further provided, each of the first cooling condensing plate, the second cooling condensing plate, the third cooling condensing plate, and the fourth cooling condensing along the attachment path. The heat exchange device according to claim 1, wherein the heat exchange device is provided on both sides of the combination with the plate.   The first cooling condenser plate, the second cooling condenser plate, the third cooling condenser plate, and the fourth cooling condenser plate are repeatedly arranged in this order along the attachment path. The heat exchange device according to claim 1.   The second cooling condensing plate is located between the first cooling condensing plate and the third cooling condensing plate, and the third cooling condensing plate includes the second cooling condensing plate, the fourth cooling condensing plate, The first cooling condenser plate and the fourth cooling condenser plate are located on both sides of the second cooling condenser plate and the third cooling condenser plate, respectively. The heat exchange apparatus as described.   The first cooling condensing plate further includes at least one first circulation hole and at least one second circulation hole, and the second cooling condensing plate includes at least one third circulation hole and at least one one. A fourth circulation hole, and the third cooling condenser plate further comprises at least one fifth circulation hole and at least one sixth circulation hole, wherein the fourth cooling condenser plate is at least 1 The heat exchange device according to claim 1, further comprising one seventh flow hole and at least one eighth flow hole.   The inlet notch groove is located between two adjacent fourth cooling condenser plates, and the outlet notch groove is located between two adjacent first cooling condenser plates. Item 2. The heat exchange device according to Item 1.   2. The heat exchange device according to claim 1, wherein the fourth cooling condensing plate and the first cooling condensing plate are disposed symmetrically about a mirror surface rotated by 180 degrees about the attachment path.   The heat exchange apparatus according to claim 1, wherein the third cooling condensing plate and the second cooling condensing plate are disposed in a mirror-symmetric manner rotated 180 degrees about the attachment path.   The first cooling condensing plate further includes at least one first opening, the second cooling condensing plate further includes at least one second opening, and the third cooling condensing plate includes at least one third opening. The heat exchange apparatus according to claim 1, further comprising: the fourth cooling condensing plate further including at least one fourth opening.   The heat exchange apparatus according to claim 2, wherein the upper plate further includes at least one fifth inlet hole and at least one fifth outlet hole.   The projected area of the fifth inlet hole, the first inlet hole, the second inlet hole, the third inlet hole, and the fourth inlet hole overlaps with each other. The heat exchange device according to 10.   The projected area of the fifth outlet hole, the first outlet hole, the second outlet hole, the third outlet hole, and the fourth outlet hole overlaps with each other. The heat exchange device according to 10.   Projection regions of the first flow hole, the second flow hole, the third flow hole, and the fourth flow hole partially overlap, and the third flow hole and the fourth flow hole The projection area of the hole, the fifth flow hole, and the sixth flow hole partially overlaps, the fifth flow hole, the sixth flow hole, the seventh flow hole, and the Projection areas with the eighth flow holes partially overlap, and projection areas with the seventh flow holes, the eighth flow holes, the first flow holes, and the second flow holes are partially overlapped. The heat exchange device according to claim 5, wherein the heat exchange device overlaps with each other.   Projection areas of the first opening and the second opening partially overlap, projection areas of the second opening and the third opening partially overlap, and the third opening and the The heat according to claim 9, wherein the projection area of the fourth opening partially overlaps, and the projection area of the fourth opening and the first opening partially overlaps. Exchange equipment.   The high temperature fluid sequentially passes through the fourth cooling condensing plate, the third cooling condensing plate, the second cooling condensing plate, and the first cooling condensing plate along the heat flow flow path. Item 2. The heat exchange device according to Item 1.   The low-temperature fluid sequentially passes through the first cooling condensing plate, the second cooling condensing plate, the third cooling condensing plate, and the fourth cooling condensing plate along the cold flow path. The heat exchange device according to claim 1.   The heat exchange device according to claim 1, wherein the heat flow flow path and the cold flow flow path are perpendicular to each other.   The heat exchange apparatus according to claim 1, wherein the cold flow path and the attachment path are parallel to each other.

Images