CN215638924U - Finned heat exchanger with high heat exchange efficiency - Google Patents

Abstract

The utility model provides a fin type heat exchanger with high heat exchange efficiency, which relates to the technical field of fin type heat exchangers and comprises a support assembly and a fin assembly, wherein a pipeline mechanism is supported at the side of the support assembly, the pipeline mechanism is provided with the sleeved fin assembly, the fin assembly comprises a copper pipe group and a water tank, the copper pipe group is arranged at the inner side of the fin assembly, the water tank is arranged below the copper pipe group, and an air cooling mechanism is arranged above the support assembly; the water pipe network with a net structure is mainly utilized, the driving action of the upper pump body is matched, so that the water body can flow quickly, the quick heat dissipation effect is achieved, the copper pipe group is installed on the outer side of the fin group, the heat of the water body can be absorbed quickly, the heat is led into cold water in the water tank, the secondary cooling effect is achieved, the driving action of the upper fan is matched, the heat exchange and heat dissipation efficiency of the equipment can be further enhanced, and the problem that the equipment cannot meet the requirement of high-strength heat dissipation is solved.

Description

Finned heat exchanger with high heat exchange efficiency

Technical Field

The utility model relates to the technical field of fin type heat exchangers, in particular to a fin type heat exchanger with high heat exchange efficiency.

Background

The finned heat exchanger is also called as a finned radiator, and is a heat exchange device which is most widely used in gas and liquid heat exchangers, the finned condenser achieves the purpose of strengthening heat transfer by additionally arranging fins on a common base pipe, and the base pipe can be made of a steel pipe; a stainless steel tube; copper tubes, etc., and the fins may be steel strips; stainless steel belts, copper belts, aluminum belts, and the like.

The prior finned heat exchanger has a good heat dissipation effect in the use process, but is difficult to adapt to the heat dissipation requirement with higher strength, so that the equipment cannot better achieve the heat dissipation effect and the like when dissipating heat for environmental equipment.

SUMMERY OF THE UTILITY MODEL

In order to solve the problems, the utility model provides a finned heat exchanger with high heat exchange efficiency, which mainly utilizes a water pipe network with a net structure to match with the driving action of an upper pump body, so that a water body can flow quickly to achieve a quick heat dissipation effect, a copper pipe group is arranged on the outer side of a fin group to quickly absorb heat of the water body, the heat is led into cold water in a water tank to achieve a secondary cooling effect, and the heat exchange and heat dissipation efficiency of equipment can be further enhanced by matching with the driving action of an upper fan, so that the problem that the equipment cannot adapt to the requirement of high-strength heat dissipation is solved.

In order to realize the purpose of the utility model, the utility model is realized by the following technical scheme: a finned heat exchanger with high heat exchange efficiency comprises a support assembly and a finned assembly, wherein a pipeline mechanism is supported by the side of the support assembly, and the pipeline mechanism is provided with the sleeved finned assembly;

the fin component comprises a copper pipe group and a water tank, the copper pipe group is arranged on the inner side of the fin component, the water tank is arranged below the copper pipe group, and an air cooling mechanism is arranged above the support component.

The support assembly comprises a damping frame, a side rod, a hanging ring, a bolt side plate and a thread clamping plate, wherein the side rod is arranged on the inner side of the damping frame, the hanging ring is arranged at the top end of the damping frame, the bolt side plate is arranged on one side of the side rod, and the thread clamping plate is arranged on the other side of the side rod.

The pipeline mechanism comprises a pump body, a water inlet pipe, a flow guide pipe, pipeline nodes, a transverse pipe, a side pipe network and a water outlet pipe, wherein the water body of the water inlet pipe is driven by the pump body to flow into the flow guide pipe, and the pipeline nodes are arranged at one end of the flow guide pipe.

The improved structure is characterized in that a transverse pipe is arranged on the inner side of the pipeline node, a side net pipe is arranged on the side of the transverse pipe, the transverse pipe and the side net pipe form a longitudinal and transverse framework, and a water outlet pipe is arranged at one end of the transverse pipe.

The further improvement is that the copper pipe groups are equidistantly and parallelly distributed by taking the central axis of the water tank as a symmetry axis.

The improved structure is characterized in that the air cooling mechanism comprises an air ring support, air ducts, fans and a circular mesh enclosure, four groups of air ducts are arranged above the air ring support, the fans are arranged on the inner side of the air ducts, and the circular mesh enclosure is arranged on the top side of the air ducts.

The utility model has the beneficial effects that:

the water pipe network with a net structure is mainly utilized, the driving action of the upper pump body is matched, so that the water body can flow quickly, the quick heat dissipation effect is achieved, the copper pipe group is installed on the outer side of the fin group, the heat of the water body can be absorbed quickly, the heat is led into cold water in the water tank, the secondary cooling effect is achieved, the driving action of the upper fan is matched, the heat exchange and heat dissipation efficiency of the equipment can be further enhanced, and the problem that the equipment cannot meet the requirement of high-strength heat dissipation is solved.

Drawings

FIG. 1 is a schematic perspective view of the present invention;

FIG. 2 is a schematic side-view perspective of the present invention;

FIG. 3 is a schematic perspective view of the cross tube and the side net tube according to the present invention;

fig. 4 is a schematic perspective view of the copper pipe set and the water tank according to the present invention.

Wherein: 1. a bracket assembly; 101. a shock-absorbing mount; 102. a side lever; 103. hanging a ring; 104. a bolt side plate; 105. a threaded snap-gauge; 2. a piping mechanism; 201. a pump body; 202. a water inlet pipe; 203. a flow guide pipe; 204. a pipe node; 205. a transverse tube; 206. a side network management; 207. a water outlet pipe; 3. a fin assembly; 301. a copper pipe set; 302. a water tank; 4. an air cooling mechanism; 401. a wind ring support; 402. an air duct; 403. a fan; 404. a circular mesh enclosure.

Detailed Description

In order to further understand the present invention, the following detailed description will be made with reference to the following examples, which are only used for explaining the present invention and are not to be construed as limiting the scope of the present invention.

As shown in fig. 1, 2, 3, and 4, the present embodiment provides a finned heat exchanger with high heat exchange efficiency, which includes a bracket assembly 1 and a fin assembly 3, wherein a pipeline mechanism 2 is supported by an edge of the bracket assembly 1, and the pipeline mechanism 2 is provided with the sleeved fin assembly 3;

fin assembly 3 includes copper nest of tubes 301 and basin 302, and the interior limit side of fin assembly 3 is provided with copper nest of tubes 301, and the below of copper nest of tubes 301 is provided with basin 302, and the top of bracket component 1 is provided with air-cooled mechanism 4.

Bracket component 1 includes shock attenuation frame 101, side lever 102, link 103, bolt side plate 104 and screw thread cardboard 105, the inboard of shock attenuation frame 101 is provided with side lever 102, the top of shock attenuation frame 101 is provided with link 103, one side of side lever 102 is provided with bolt side plate 104, the opposite side of side lever 102 is provided with screw thread cardboard 105, utilize bracket component 1 to support shock attenuation frame 101, play absorbing effect, can weld side lever 102 at the avris of shock attenuation frame 101, and set up link 103 in order to conveniently carry out the handling on the top side of shock attenuation frame 101, can set up bolt side plate 104 that the bolt was equipped in the one end of side lever 102, the avris of bolt side plate 104 sets up screw thread cardboard 105, in order that the convenience of customers dismantles and assembles.

The pipeline mechanism 2 comprises a pump body 201, an inlet pipe 202, a guide pipe 203, a pipeline node 204, a transverse pipe 205, a side net pipe 206 and an outlet pipe 207, the water body of the drive inlet pipe 202 of the pump body 201 flows into the guide pipe 203, the pipeline node 204 is arranged at one end of the guide pipe 203, the pump body 201 can be arranged in the pipeline mechanism 2, the inlet pipe 202 is arranged at one side of the pump body 201, hot water is guided to the guide pipe 203 to enter the pipeline node 204, and the flowing of the water body can be accelerated.

The inboard of pipeline node 204 is provided with violently pipe 205, and the avris of violently pipe 205 is provided with side net pipe 206, violently pipe 205 and side net pipe 206 constitution are moved about freely and quickly the framework, and the one end of violently pipe 205 is provided with outlet pipe 207, can distribute away the heat as far as possible after violently pipe 205 and side net pipe 206 fill, can set up the water exhaust apparatus after outlet pipe 207 will cool off in the one end of violently pipe 205 to increase the radiating efficiency of equipment.

Copper nest of tubes 301 uses the axis of basin 302 to be the equidistant parallel distribution of symmetry axis, and the fin subassembly 3 that cup joints, absorption heat that can be rapid for absorb the heat that the water gived off under copper nest of tubes 301's effect, the one end of copper nest of tubes 301 sets up basin 302 and makes and absorb the heat by the water, reaches the effect that promotes the cooling.

The air cooling mechanism 4 comprises an air ring support 401, air ducts 402, a fan 403 and a circular mesh enclosure 404, four groups of air ducts 402 are arranged above the air ring support 401, the fan 403 is arranged on the inner side of the air ducts 402, the circular mesh enclosure 404 is arranged on the top side of the air ducts 402, the air ring support 401 can support the four groups of air ducts 402, the hot air is blown to pass through the circular mesh enclosure 404 to be exhausted under the action of an output fan of the fan 403, the cooling effect is achieved, and the fluid of the air is accelerated.

The working principle of the finned heat exchanger with high heat exchange efficiency is as follows: as shown in fig. 1-4, firstly, a user can use the bracket assembly 1 to support the shock-absorbing frame 101 to play a role of shock absorption, the side rod 102 can be welded on the side of the shock-absorbing frame 101, the top side of the shock-absorbing frame 101 is provided with the hanging ring 103 for convenient lifting, one end of the side rod 102 is provided with the bolt side plate 104 with bolt equipment, the side of the bolt side plate 104 is provided with the thread snap-gauge 105 to form a role of supporting the pipeline mechanism 2, the pipeline mechanism 2 can be provided with the pump body 201, one side of the pump body 201 is provided with the water inlet pipe 202, hot water is guided to the guide pipe 203 to enter the pipeline node 204, so that the water body can radiate heat as far as possible after the horizontal pipe 205 and the side net pipe 206 are filled with the water body, one end of the horizontal pipe 205 is provided with the water outlet pipe 207 to discharge the cooled water body, because the fin assembly 3 is sleeved on the outer sides of the horizontal pipe 205 and the side net pipe 206, absorption heat that can be rapid, make the heat that absorbs the water and give off under copper pipe set 301's effect, copper pipe set 301's one end has set up basin 302 and has made the heat to be absorbed by the water, reach the effect that promotes the cooling, can set up forced air cooling mechanism 4 in the top of side lever 102, make circle support 401 can support four air ducts of group 402, make the output fan effect of fan 403 reach down and blow the steam and pass through circular screen panel 404 exhaust apparatus, reach the effect of cooling, therefore, accomplish a series of works.

The foregoing illustrates and describes the principles, general features, and advantages of the present invention. It will be understood by those skilled in the art that the present invention is not limited to the embodiments described above, which are described in the specification and illustrated only to illustrate the principle of the present invention, but that various changes and modifications may be made therein without departing from the spirit and scope of the present invention, which fall within the scope of the utility model as claimed. The scope of the utility model is defined by the appended claims and equivalents thereof.

Claims (6)

1. The utility model provides a finned heat exchanger that heat exchange efficiency is high, includes bracket component (1) and fin component (3), its characterized in that: a pipeline mechanism (2) is supported at the side of the bracket component (1), and a sleeved fin component (3) is arranged on the pipeline mechanism (2);

fin subassembly (3) are including copper nest of tubes (301) and basin (302), the interior limit side of fin subassembly (3) is provided with copper nest of tubes (301), just the below of copper nest of tubes (301) is provided with basin (302), the top of bracket component (1) is provided with forced air cooling mechanism (4).

2. The finned heat exchanger with high heat exchange efficiency as claimed in claim 1, wherein: the support assembly (1) comprises a damping frame (101), a side rod (102), a hanging ring (103), a bolt side plate (104) and a thread clamping plate (105), wherein the side rod (102) is arranged on the inner side of the damping frame (101), the hanging ring (103) is arranged on the top end of the damping frame (101), the bolt side plate (104) is arranged on one side of the side rod (102), and the thread clamping plate (105) is arranged on the other side of the side rod (102).

3. The finned heat exchanger with high heat exchange efficiency as claimed in claim 1, wherein: pipeline mechanism (2) are including the pump body (201), inlet tube (202), honeycomb duct (203), pipeline node (204), violently manage (205), side net pipe (206) and outlet pipe (207), the drive inlet tube (202) water of the pump body (201) flows into honeycomb duct (203), just the one end of honeycomb duct (203) is provided with pipeline node (204).

4. The finned heat exchanger with high heat exchange efficiency as claimed in claim 3, wherein: the inner side of the pipeline node (204) is provided with a transverse pipe (205), the side of the transverse pipe (205) is provided with a side net pipe (206), the transverse pipe (205) and the side net pipe (206) form a longitudinal and transverse framework, and one end of the transverse pipe (205) is provided with a water outlet pipe (207).

5. The finned heat exchanger with high heat exchange efficiency as claimed in claim 1, wherein: the copper pipe groups (301) are distributed in parallel at equal intervals by taking the central axis of the water tank (302) as a symmetry axis.

6. The finned heat exchanger with high heat exchange efficiency as claimed in claim 1, wherein: the air cooling mechanism (4) comprises an air ring support (401), air ducts (402), fans (403) and a circular mesh enclosure (404), wherein four groups of air ducts (402) are arranged above the air ring support (401), the fans (403) are arranged on the inner side of the air ducts (402), and the circular mesh enclosure (404) is arranged on the top side of the air ducts (402).

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