CN217818223U - Condensing system and condensing device thereof - Google Patents

Abstract

The condensing device comprises a cylinder part, two end covers connected with the cylinder part, a heat exchange part penetrating in the cylinder part, a cyclone ring part arranged between one end cover and the heat exchange part and used for generating vortex, and at least one condensing unit arranged on the end cover unit. Each of the end caps includes two openings. The heat exchange element comprises a pipeline which defines a first flow passage with each end cover and a vortex chamber which defines a second flow passage with each end cover. The condensing unit includes a chiller wafer module. The refrigeration wafer module has a heat absorbing panel facing the end cap unit and for absorbing heat energy, and a heat releasing panel opposite the end cap unit and for releasing heat energy. Borrow this, reach the purpose of heat dissipation and cooling down by a wide margin, and can be with the modularized design, according to a plurality of condensing equipment of user demand arbitrary series connection or parallelly connected.

Description

Condensing system and condensing device thereof

Technical Field

The utility model relates to a heat sink especially relates to a condensing system and condensing equipment thereof.

Background

Referring to fig. 1, a conventional heat exchange device 1 disclosed in taiwan patent No. TWI577960B mainly comprises a cylindrical member 11, a top end cap 12 and a bottom end cap 12 'detachably closing the cylindrical member 11, and a duct assembly 13 installed between the cylindrical member 11 and the top end cap 12 and the bottom end cap 12'. The top end-cap 12 and the bottom end-cap 12' each include an air inlet 121, 121' and an air outlet 122, 122'.

Thereby, the gas inlet 121 'of the bottom end cap 12' and the gas outlet 122 of the top end cap 12 are used for guiding high temperature gas to enter and exit the barrel 11, the gas inlet 121 of the top end cap 12 and the gas outlet 122 'of the bottom end cap 12' are used for guiding low temperature gas to enter and exit the barrel 11, and during the gas flowing process, part of the low temperature gas is mixed with the high temperature gas in the barrel 11 through one contact 131 of the flow guide pipe set 13, so as to reduce the temperature of the gas finally discharged from the gas outlet 122 of the top end cap 12.

Although the high-temperature gas is cooled by mixing with the low-temperature gas, the cooling amplitude depends on the amount of the low-temperature gas which can be mixed with the high-temperature gas, so that the cooling effect still has a space which can be improved, and the required amount of the original low-temperature gas can be influenced when a large amount of low-temperature gas is used for cooling.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a condensing system and condensing equipment that can cool down by a wide margin.

Condensing equipment, contain section of thick bamboo piece, end cover unit, heat exchange element, whirlwind ring spare, and at least one condensing unit.

The cartridge includes two opposing ends.

The end cap unit includes two end caps detachably connected to the end portions, each of the end caps having two openings.

The heat exchange piece is arranged in the barrel and comprises a pipe wall and a plurality of fins, the pipe wall surrounds the axis and defines a pipeline, the fins extend from the pipe wall, the pipe wall and the barrel further define a vortex chamber, the pipeline and one opening of each end cover define a first flow passage suitable for fluid to pass through, the vortex chamber and the other opening of each end cover define a second flow passage suitable for fluid to pass through, and the fins are suitable for exchanging heat with the fluid.

The cyclone ring piece surrounds the axis and is arranged between one end cover and the heat exchange element, and comprises a plurality of blades which are formed on the outer surface and are suitable for guiding the fluid to generate vortex in the second flow passage.

The at least one condensing unit is mounted to the end cover unit and includes a chiller wafer module having a heat absorption panel facing the end cover unit and for absorbing heat energy, and a heat release panel opposite the end cover unit and for releasing heat energy.

Condensing equipment, each the end cover still has and centers on the axis just defines out the body part in pore, and centers on the body part just with the body part defines out the somatic part of return circuit, the pore with pipeline, each one of them opening of end cover defines out jointly first runner, the return circuit with swirl chamber, each another opening of end cover defines out jointly the second runner.

Condensing equipment, at least one condensing unit still including contact in the heat release module of heat release panel, heat release module has the heat release flow path that is applicable to the confession fluid and passes through.

Condensing equipment, at least one condensing unit still including contact in the heat absorption module of heat absorption panel, the heat absorption module is injectd to have and is applicable to the heat absorption flow path that supplies the fluid to pass through.

Condensing equipment, condensing equipment contain two condensing unit, each condensing unit is installed at the end cover that corresponds separately, and each the noumenon portion of end cover still defines the opening orientation the heat absorption flow path that the heat absorption panel just is applicable to the guide fluid and passes through.

Condensing equipment, exothermic flow path communicate in the second runner, endothermic flow path communicate in first runner.

Condensing equipment, the barrel part the end cover heat exchange piece with the whirlwind ring spare is made by metal material respectively.

Condensing equipment, the fin respectively by the internal surface and the surface orientation of pipe wall opposite to the direction of pipe wall extends.

The condensing system of the present invention comprises a plurality of condensing units and a connecting device.

The connecting device comprises a plurality of engaging groups, and each engaging group can be selectively and detachably connected with two adjacent condensing devices.

The condensing system of the utility model comprises at least one condensing device, a connecting device and at least one filtering device.

The at least one filter device is used for filtering the passing fluid to capture moisture, oil mist, dust or particles in the fluid.

The connecting means comprises a plurality of engaging sets, each of the engaging sets being selectively and detachably connectable to the at least one condensing means and the at least one filtering means.

The beneficial effects of the utility model reside in that: through the design of vortex and different runners, under the condition that does not reduce and lose fluid flow, the extension fluid with the time that heat exchange was carried out to the heat exchange piece, and through condensing unit reduces holistic temperature, reaches the purpose of heat dissipation and cooling down by a wide margin.

Drawings

Other features and advantages of the present invention will become apparent from the following description of the embodiments with reference to the accompanying drawings, in which:

FIG. 1 is a cross-sectional view illustrating a prior art heat exchange device disclosed in Taiwan patent No. TWI 577960B;

fig. 2 is an exploded perspective view illustrating an embodiment of the condensing unit of the present invention;

FIG. 3 is a perspective view of the embodiment;

FIG. 4 is a cross-sectional view of the embodiment;

FIG. 5 is a cross-sectional view taken along line V-V in FIG. 4;

FIG. 6 is a cross-sectional view taken along line VI-VI in FIG. 4;

FIG. 7 is a perspective view illustrating another aspect of the embodiment;

FIG. 8 is a cross-sectional view of another version of the embodiment;

FIG. 9 is a perspective view illustrating embodiments connected in series by connecting means and forming a condensing system:

FIG. 10 is a perspective view illustrating a plurality of embodiments connected in parallel by the connecting means and constituting another condensing system;

FIG. 11 is a cross-sectional view illustrating the embodiment attached to a filtration device; and

FIG. 12 is a cross-sectional view illustrating the embodiment connected to multiple filtration devices.

Detailed Description

Referring to fig. 2, 3 and 4, an embodiment of the condensing device of the present invention includes a hollow cylinder 2, an end cover unit 3, a heat exchange element 4, a cyclone ring 5, and two condensing units 6.

The cartridge 2 comprises two opposite ends 21.

The end cap unit 3 comprises two end caps 31. The end caps 31 are detachably connected to the corresponding end portions 21 of the cartridge 2 along an axis X, and each end cap 31 has a body portion 312 surrounding the axis X and defining a hole 311, and a body portion 314 surrounding the body portion 312 and defining an annular channel 313 with the body portion 312. The body portion 314 defines an outwardly opening heat sink flow path 315 for fluid flow therethrough and has two opposing rims 316. Each rim 316 defines an opening 317. One of the openings 317 is connected to the hole 311, and the other opening 1317 is connected to the loop 313. The hole 311 is not communicated with the ring 313.

Referring to fig. 2, 4 and 5, the heat exchange element 4 is disposed in the cylinder 2 along the direction of the axis X, is connected to the tube body 312 of the end cap 31, and includes a tube wall 42 surrounding the axis X and defining a tube 41, and a plurality of fins 43 extending from the tube wall 42. The tube wall 42 and the cartridge 2 also define a swirl chamber 44. The conduit 41 and the bore 311 and the corresponding opening 1317 of each end cap 31 define a first flow path adapted for fluid flow therethrough. The swirl chamber 44 and the ring 313 and corresponding opening 317 of each end cap 31 define a second flow path adapted for the passage of fluid. In the present embodiment, the fins 43 extend along a curve from the inner surface and the outer surface of the tube wall 42 in the opposite direction to the tube wall 42.

Referring to fig. 2, 4 and 6, the cyclone ring 5 surrounds the axis X and is installed between the heat exchange element 4, the cylinder 2 and one of the end covers 31, and includes a plurality of vanes 51 formed on an outer surface and adapted to guide the fluid to generate a vortex flow in the second flow channel.

Referring to fig. 2 and 4, in the present embodiment, each of the condensing units 6 is mounted on the body portion 314 of the corresponding end cap 31, and includes a chilling wafer module 61 and a heat releasing module 62. The chilling wafer module 61 has a heat absorbing panel 611 facing the body portion 314 for absorbing heat, a heat discharging panel 612 opposite to the body portion 314 for discharging heat, and a chilling wafer 613 interposed between the heat absorbing panel 611 and the heat discharging panel 612. The heat releasing modules 62 are connected to the heat releasing panel 612 without contacting the respective end caps 31, and define a heat releasing flow path 621 opened toward the heat releasing panel 612 and adapted to pass a fluid therethrough.

It should be noted that the fluid may be a liquid, a gas, a mixture of a liquid and particles, a mixture of a gas and particles, or a mixture of a liquid, a gas and particles. The mixing of the liquid with the gas has the advantage that the flow velocity of the liquid can be increased by the gas pressure.

In addition, in the present embodiment, the cylindrical member 2, the end cap 31, the heat exchange member 4, the cyclone ring 5 and the heat releasing module 62 are made of aluminum material or other metal material with high heat conductivity, such as: copper material.

Referring to fig. 4, 5 and 6, when the condensing unit 6 is powered on with dc power, the heat absorption panel 611 absorbs heat energy and the heat release panel 612 releases heat energy through Peltier Effect (Peltier Effect) of each of the refrigeration wafer modules 61, so that the heat transfer to the corresponding end cap 31 can be reduced and delayed in case that the heat release panel 612 is not in contact with the end cap 31 or the cartridge 2. Therefore, the heat energy of the end cap 31 and the heat energy of the fluid passing through the heat absorption flow path 315 are absorbed by the heat absorption panel 611 of the refrigeration wafer module 61, so that the end cap 31 is greatly cooled, and meanwhile, the cylinder 2 and the heat exchange member 4 directly contacting the end cap 31 and the cyclone ring 5 directly contacting the heat exchange member 4 and the cylinder 2 are also greatly cooled due to the heat energy dissipation.

At this time, the heat releasing panel 612 of the chilling wafer module 61 releases heat energy to the outside, and in this embodiment, the released heat energy can exchange heat with the heat releasing module 62 and the fluid passing through the heat releasing flow path 621, so as to achieve the effect of reducing the temperature.

When the high temperature fluid enters and exits the condensing apparatus of the present invention from the second flow passage as shown by the hollow arrows in dotted lines, it first passes through the cyclone ring 5, and a vortex is generated in the vortex chamber 44, and flows around the heat exchange element 4 following the fins 43 on the outer surface of the heat exchange element 4. Therefore, high-temperature fluid exchanges heat with the cylinder 2, the end cover 31, the heat exchange part 4 and the cyclone ring 5, and the aim of quickly and greatly reducing the temperature is fulfilled.

When a low-temperature fluid or a high-temperature fluid is introduced into or discharged from the first flow passage as shown by the solid arrows, the low-temperature fluid or the high-temperature fluid contacts the end cover 31 and the fins 43 on the inner surface of the heat exchange element 4 during the flowing process, in addition to the heat absorption panel 611 of the condensing unit 6. Thereby, the fluid in the first flow channel exchanges heat with the heat absorbing panel 611, the end cover 31 and the fins 43 on the inner surface of the heat exchange element 4, and at this time, if the solid arrow indicates a low temperature fluid, the temperature of the fluid in the first flow channel can be further reduced, and if the solid arrow indicates a high temperature fluid, the purpose of reducing the temperature can be achieved as well.

It should be noted that, since the temperature of the fluid is greatly reduced, when the fluid is a gas, the gas can be condensed into water, and the humidity of the gas can be reduced.

It should be noted that the number of the condensation units 6 is not limited to 2, and the design of each end cover 31 is not limited to a cylinder, and in other variations of this embodiment, as shown in fig. 7 and 8, only one condensation unit 6 may be installed in one of the end covers 31, and the heat absorption flow path 315 shown in fig. 4 is omitted from the one of the end covers 31, and the condensation unit 6 further includes a heat absorption module 63 disposed between the refrigeration wafer module 61 and the one of the end covers 31 and in contact with the heat absorption panel 611. The heat absorption module 63 defines a heat absorption flow path 631 adapted for the passage of fluid therethrough. Therefore, the effects of heat absorption and heat release can be achieved.

Referring to fig. 9 and 10, the present invention can form a condensing system by using a plurality of condensing units and a connecting device 7.

The connecting device 7 comprises a plurality of engagement sets 71. Each of the engagement sets 71 is selectively and detachably connected to two adjacent condensing units. In this embodiment, each of the engaging sets 71 is composed of a pipe and at least one C-shaped fastener, or other components capable of connecting two adjacent condensing units. Additional details will not be set forth in order to provide those skilled in the art with a understanding of the above description.

Therefore, during assembly, the condensing device can be connected in series through the connection group 71 as shown in fig. 9, or the condensing device can be connected in parallel through the connection group 71 as shown in fig. 10, so that the temperature of the fluid is further reduced.

It should be noted that the condensing devices of the present invention are not limited to be connected in series or in parallel, and in other variations of this embodiment, as shown in fig. 11 and 12, more than one filtering device 8 may be connected in series through the connecting set 71 to capture moisture, oil mist, or dust, or particles in the fluid. The filter device 8 may be a cyclone filter module disclosed in taiwan patent No. TWI589344B or a cyclone filter device disclosed in taiwan patent No. TW 201912230A. Since they are not technical features of the present disclosure and since the details of expansion can be deduced by those skilled in the art from the above description, they will not be described in further detail.

Therefore, the utility model discloses a condensing system can the wide application in the cooling field, or filter field, or processing field to connect a vacuum machine (not shown) and a mould unit (not shown), and use and jet out as the example in vacuum extrusion, vacuum forging, vacuum casting, vacuum, the utility model discloses a condensing system except can reaching the effect of cooling fluid or mould, can also discharge the water after the condensation, promotes fluidic aridity, and promotes fluidic cleanliness factor, and each off-the-shelf quality is better in the messenger processing procedure.

With the above description, the advantages of the foregoing embodiments can be summarized as follows:

1. the utility model discloses can pass through the design of vortex and different runners, under the situation that does not reduce and decrease fluid flow, the extension fluid with heat exchange piece 4 carries out the time of heat exchange.

2. Just the utility model discloses can pass through 6 special space designs of condensation unit reduce holistic temperature, reach the purpose of heat dissipation and cooling by a wide margin.

3. Additionally, the utility model discloses can be with the modularized design, the wide application not only can reach cooling fluid's effect in cooling field, or filtration field, or processing field, and can promote fluidic cleanliness factor and dryness factor, and promote each off-the-shelf quality in the processing procedure.

The above description is only an example of the present invention, and the scope of the present invention should not be limited thereby, and all the simple equivalent changes and modifications made according to the claims and the description of the present invention are still within the scope of the present invention.

Claims (10)

1. A condensing unit, comprising:

a cartridge comprising two opposing ends;

an end cap unit comprising two end caps detachably connected to the end portions, each of the end caps having two openings;

a heat exchange element disposed in the cartridge and including a tube wall surrounding an axis and defining a tube, the tube wall and the cartridge further defining a vortex chamber, the tube and one of the openings of each of the end caps defining a first flow passage adapted for passage of fluid, the vortex chamber and another of the openings of each of the end caps defining a second flow passage adapted for passage of fluid;

a cyclone ring surrounding the axis and mounted between one of the end caps and the heat exchange member, and including a plurality of vanes formed on an outer surface thereof and adapted to guide a fluid to generate a vortex flow in the second flow path; and

the method is characterized in that:

the heat exchange element further comprises a plurality of fins extending from the tube wall, the fins being adapted to exchange heat with a fluid;

the condensing unit also includes at least one condensing unit mounted at the end cover unit and including a chilling wafer module having a heat absorbing panel facing the end cover unit and for absorbing heat energy, and a heat releasing panel opposite the end cover unit and for releasing heat energy.

2. A condensing unit according to claim 1, characterized in that: each end cap also has a body portion surrounding the axis and defining an orifice, and a body portion surrounding the body portion and defining an annulus with the body portion, the orifice and the conduit, one of the openings of each end cap defining the first flow passage, the annulus and the swirl chamber, the other opening of each end cap defining the second flow passage.

3. A condensing unit according to claim 2, characterized in that: the at least one condensing unit further includes a heat emitting module in contact with the heat emitting panel, the heat emitting module having a heat emitting flow path adapted for passage of a fluid.

4. A condensing unit according to claim 3, characterized in that: the at least one condensing unit further includes a heat absorption module contacting the heat absorption panel, the heat absorption module defining a heat absorption flow path adapted for passage of a fluid.

5. A condensing unit according to claim 3, characterized in that: the condensing device comprises two condensing units, each condensing unit is arranged on a corresponding end cover, and the body part of each end cover further defines a heat absorption flow path which is opened towards the heat absorption panel and is suitable for guiding fluid to pass through.

6. A condensation device according to claim 4 or 5, characterized in that: the heat release flow path is communicated with the second flow path, and the heat absorption flow path is communicated with the first flow path.

7. A condensing unit according to claim 1, characterized in that: the cylinder part, the end cover, the heat exchange part and the cyclone ring part are made of metal materials respectively.

8. A condensing unit according to claim 1, characterized in that: the fins extend from the inner surface and the outer surface of the tube wall in a direction opposite to the tube wall.

9. A condensing system, comprising:

the connecting device comprises a plurality of connecting groups;

the method is characterized in that:

the condensing system further comprises a plurality of condensing units according to claim 1;

each of the engagement groups is selectively and detachably connected to two adjacent condensing devices.

10. A condensing system, comprising:

at least one filter device for filtering the passing fluid to capture moisture, or oil mist, or dust, or particles in the fluid;

a connecting device, comprising a plurality of connecting groups; and

the method is characterized in that:

the condensing system further comprises at least one condensing apparatus according to claim 1;

each of the plurality of engagement sets is selectively and detachably connectable to the at least one condensing unit and the at least one filtering unit.

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