CN219551268U - Annular fin radiator - Google Patents

Abstract

The utility model relates to the technical field of fin radiators and discloses an annular fin radiator which comprises a mounting frame, wherein a pipeline assembly is arranged on the inner side of the mounting frame, a heat dissipation assembly is arranged on the inner side of the mounting frame, the pipeline assembly comprises a water outlet pipe fixedly connected to the left side of the mounting frame, a coiled pipe is fixedly arranged at the right end of the water outlet pipe, four supporting blocks are fixedly connected between the outer side of the coiled pipe and the inner side of the mounting frame, a booster pump is fixedly connected to the right end of the coiled pipe, a water inlet pipe is fixedly connected to the right side of the booster pump, four supporting feet which are uniformly distributed are fixedly connected to the bottom of the mounting frame, the heat dissipation assembly comprises ten heat conducting plates which are slidably connected to the outer side of the coiled pipe, and twenty annular sheets which are arranged at equal intervals are fixedly connected to the outer side of the heat conducting plates. This annular fin radiator can be convenient carry out effectual cleanness to the fin to the practicality of fin radiator has effectually been promoted.

Description

Annular fin radiator

Technical Field

The utility model relates to the technical field of fin radiators, in particular to an annular fin radiator.

Background

The fin radiator is the most widely used heat exchange equipment in the gas and liquid heat exchanger, the fin radiator performs heat exchange in an air convection mode, and the flow of media in the tube can enable the wall surfaces of the fins to reach the corresponding temperature, so that heat transfer is completed.

In order to keep the high efficiency of heat dissipation, the existing fin radiator is generally directly installed in the outside, so that the fin radiator can effectively exchange heat with surrounding air, and after long-time use, the outer side of the fin can be covered with a large amount of dust to influence the heat exchange, and the existing fin is generally fixedly installed on the outer side of a tube, meanwhile, the existing fin is inconvenient to effectively clean due to space limitation, and the dust needs to be cleaned by washing and brushing slowly, so that the time and labor required for cleaning the fin radiator are greatly increased, and the practicability of the existing fin radiator is required to be improved.

Disclosure of Invention

(one) solving the technical problems

Aiming at the defects of the prior art, the utility model provides the annular fin radiator which has the advantages of convenience in cleaning and the like, and solves the problem that the conventional fin radiator is inconvenient in effectively cleaning fins.

(II) technical scheme

In order to achieve the aim of conveniently cleaning, the utility model provides the following technical scheme: the annular fin radiator comprises a mounting frame, wherein a pipeline assembly is mounted on the inner side of the mounting frame, and a heat dissipation assembly is mounted on the inner side of the mounting frame;

the pipeline assembly comprises a water outlet pipe fixedly connected to the left side of the installation frame, a coiled pipe is fixedly arranged at the right end of the water outlet pipe, four supporting blocks are fixedly connected between the outer side of the coiled pipe and the inner side of the installation frame, a booster pump is fixedly connected to the right end of the coiled pipe, a water inlet pipe is fixedly connected to the right side of the booster pump, and four supporting feet which are uniformly distributed are fixedly connected to the bottom of the installation frame;

the heat dissipation assembly comprises ten heat conduction plates which are slidably connected to the outer side of a coiled pipe, twenty annular plates which are equidistantly arranged are fixedly connected to the outer side of each heat conduction plate, communication holes which are uniformly distributed are formed in the right side of each annular plate, ten positioning blocks are fixedly connected to the outer side of each coiled pipe, two positioning holes are formed in the top of each heat conduction plate correspondingly, ten sliding blocks are fixedly connected to the outer side of each coiled pipe, lifting blocks are fixedly connected to the bottoms of the sliding blocks correspondingly, two sliding holes are formed in the bottoms of the corresponding five heat conduction plates correspondingly, three butt joint blocks are fixedly connected to the front side and the back side of each heat conduction plate correspondingly, bolts are connected between the tops of the butt joint blocks in a threaded mode, and nuts are connected to the outer side of the bolts in a threaded mode.

Further, the front and the back of the mounting frame are communicated with the outside, and the bottom of the booster pump is fixedly connected with a placing plate fixedly connected with the right side of the mounting frame.

Further, the heat conducting plates are arc-shaped, and one side of each of the two opposite heat conducting plates is attached to the outer side of the coiled pipe.

Further, the two corresponding positioning blocks are positioned above the two corresponding sliding blocks, and the positioning blocks can be inserted into the inner sides of the corresponding positioning holes.

Further, the distance between the opposite sides of the two corresponding positioning blocks is equal to the distance between the opposite sides of the two corresponding positioning holes, and the back surfaces of the sliding holes are communicated with the outside.

Further, the sliding blocks can slide on the inner sides of the corresponding sliding holes, and the distance between the opposite sides of the corresponding two sliding blocks is equal to the distance between the opposite sides of the corresponding two sliding holes.

Further, a gasket is connected between two opposite sides of the butt joint blocks in a sliding manner, and a through hole for the corresponding bolt to penetrate is formed in the top of the gasket.

(III) beneficial effects

Compared with the prior art, the utility model provides the annular fin radiator which has the following beneficial effects:

this annular fin radiator uses through the cooperation between the inboard pipeline subassembly of installing frame and the radiator unit, can be convenient carry out effective cleanness to the fin, can not receive the restriction in space to can make the fin keep high-efficient stable radiating effect, very big reduction clean fin radiator required time and labour, thereby effectually promoted fin radiator's practicality.

Drawings

FIG. 1 is a schematic diagram of the structure of the present utility model;

FIG. 2 is a right side cross-sectional view of a connection structure of two corresponding heat conducting plates in the structure of the present utility model;

FIG. 3 is a front view of the structure of the present utility model;

fig. 4 is an enlarged partial schematic view of the portion a of the structure of the present utility model.

In the figure: 1 mounting frame, 200 pipeline components, 201 water outlet pipe, 202 coiled pipe, 203 supporting block, 204 booster pump, 205 water inlet pipe, 206 supporting leg, 300 heat dissipation component, 301 heat conducting plate, 302 annular plate, 303 communication hole, 304 positioning block, 305 positioning hole, 306 sliding block, 307 lifting block, 308 sliding hole, 309 butt joint block, 310 bolt and 311 nut.

Detailed Description

The technical solutions in the embodiments of the present utility model will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present utility model.

Referring to fig. 1-4, the present utility model provides a technical solution: the utility model provides an annular fin radiator, includes installing frame 1, pipeline subassembly 200 is installed to the inboard of installing frame 1, and radiator unit 300 is installed to the inboard of installing frame 1, uses through the cooperation between pipeline subassembly 200 and the radiator unit 300 of installing frame 1 inboard, can be convenient carry out effective cleanness to the fin, can not receive the restriction in space to can make the fin keep high-efficient stable radiating effect, very big reduction clean fin radiator required time and labour, thereby effectually promoted fin radiator's practicality.

The pipe assembly 200 in this embodiment is a structure for transporting a heat dissipation medium.

As shown in fig. 1 and 3, the pipe assembly 200 includes a water outlet pipe 201 fixedly connected to the left side of the installation frame 1, a coiled pipe 202 is fixedly connected to the right end of the water outlet pipe 201, four supporting blocks 203 are fixedly connected between the outer side of the coiled pipe 202 and the inner side of the installation frame 1, a booster pump 204 is fixedly connected to the right end of the coiled pipe 202, a water inlet pipe 205 is fixedly connected to the right side of the booster pump 204, and four supporting feet 206 which are uniformly distributed are fixedly connected to the bottom of the installation frame 1.

It should be noted that, the model of the booster pump 204 may be ISG100-160, and the front and the back of the mounting frame 1 are all connected with the outside, so that the whole has a good heat dissipation effect, and the bottom of the booster pump 204 is fixedly connected with a placing plate fixedly connected with the right side of the mounting frame 1, so as to support the booster pump 204.

The heat dissipating assembly 300 in this embodiment is a structure for dissipating heat and improving cleaning convenience.

As shown in fig. 1, fig. 2 and fig. 4, the heat dissipation assembly 300 includes ten heat conduction plates 301 slidingly connected to the outside of the coiled pipe 202, twenty annular plates 302 are fixedly connected to the outside of the heat conduction plates 301 and are arranged at equal intervals, communication holes 303 are uniformly distributed on the right sides of the annular plates 302, ten positioning blocks 304 are fixedly connected to the outside of the coiled pipe 202, two positioning holes 305 are formed at the tops of the corresponding five heat conduction plates 301, ten sliding blocks 306 are fixedly connected to the outside of the coiled pipe 202, lifting blocks 307 are fixedly connected to the bottoms of the sliding blocks 306, two sliding holes 308 are formed at the bottoms of the corresponding five heat conduction plates 301, three butt joint blocks 309 are fixedly connected to the front and the back of the heat conduction plates 301, bolts 310 are connected to the tops of the corresponding two butt joint blocks 309 in a threaded manner, and nuts 311 are screwed to the outer sides of the bolts 310.

It should be noted that, the heat conducting plates 301 are arc-shaped, and opposite sides of the two corresponding heat conducting plates 301 are attached to the outer sides of the serpentine tube 202, wherein the heat conducting plates 301 are aluminum alloy plates, so that the two corresponding heat conducting plates 301 can perform effective heat conduction.

In addition, the corresponding two positioning blocks 304 are located above the corresponding two sliding blocks 306, the positioning blocks 304 can be inserted into the inner sides of the corresponding positioning holes 305, and the distance between the opposite sides of the corresponding two positioning blocks 304 is equal to the distance between the opposite sides of the corresponding two positioning holes 305, so that the corresponding five heat conducting plates 301 can be conveniently installed.

Meanwhile, the back surfaces of the sliding holes 308 are communicated with the outside, the sliding blocks 306 can slide on the inner sides of the corresponding sliding holes 308, and the distance between the opposite sides of the corresponding two sliding blocks 306 is equal to the distance between the opposite sides of the corresponding two sliding holes 308, so that the corresponding five heat conducting plates 301 can all move between the outer sides of the corresponding two sliding blocks 306 under the action of the corresponding two sliding holes 308, and simultaneously the corresponding five heat conducting plates 301 can be supported under the action of the lifting blocks 307.

In addition, a gasket is slidably connected between opposite sides of the two corresponding butt-joint blocks 309, a through hole for the corresponding bolt 310 to penetrate is formed in the top of the gasket, the two corresponding butt-joint blocks 309 can be tightly attached under the action of the gasket, wherein hot water enters the inner side of the coiled pipe 202 under the action of the booster pump 204 through the water inlet pipe 205, heat is transferred to the inner side of the annular plate 302 under the action of the heat conducting plate 301, heat exchange is performed between the annular plate 302 and air under the action of the communication hole 303, so that the heat exchange effect is achieved, and the exchanged hot water is discharged through the water outlet pipe 201.

The working principle of the embodiment is as follows:

when the cleaning is needed after long-time use, the nuts 311 are rotated to separate the corresponding two butt joint blocks 309 from the outer sides of the corresponding bolts 310, the corresponding two heat conducting plates 301 are not connected and fixed by threads through the corresponding six bolts 310, the top second heat conducting plate 301 is detached from top to bottom in sequence, the top first heat conducting plate 301 is moved upwards to separate and clean the positioning block 304 from the inner side of the corresponding positioning hole 305, the top first heat conducting plate 301 is moved to the front side to be detached from the inner side of the mounting frame 1, the cleaning can be independently performed, simultaneously the top second heat conducting plate 301 is supported under the action of the corresponding two lifting blocks 307, the falling is prevented, the sliding blocks 306 are enabled to slide into the outside from the inner side of the corresponding sliding holes 308, the top second heat conducting plate 301 can be taken out, the ten heat conducting plates 301 are detached downwards in sequence according to the principle, after the cleaning is completed, the first heat conducting plate 301 is moved downwards to one side to be detached from the inner side of the corresponding positioning block 1, the two heat conducting plates 301 are sequentially installed from bottom to the inner side to the corresponding two heat conducting plates 307, the two heat conducting plates 301 are enabled to be stably connected to the corresponding two heat conducting plates 301 by rotating the corresponding two bolts 306, the two heat conducting plates 301 are enabled to be stably connected to the corresponding two heat conducting plates 310 by the corresponding two heat conducting plates 308, and the corresponding bolts 310 are enabled to be stably connected to move to the corresponding two heat conducting plates 301 to the corresponding two heat conducting plates 308 by the corresponding bolts 308, and the corresponding two heat conducting plates 301 are respectively and the corresponding to be stably connected to the corresponding heat conducting plates 301, the corresponding two heat conductive plates 301 can be fixed by the corresponding six bolts 310 and nuts 311.

Compared with the prior art, the annular fin radiator is matched with the pipeline assembly 200 and the radiating assembly 300 on the inner side of the mounting frame 1, so that the fins can be conveniently and effectively cleaned without being limited by space, the fins can be enabled to maintain efficient and stable radiating effect, the time and labor required for cleaning the fin radiator are greatly reduced, the practicality of the fin radiator is effectively improved, and the problem that the conventional fin radiator is inconvenient to effectively clean the fins is solved.

The electrical components appearing herein are all electrically connected with the master controller and the power supply, the master controller can be a conventional known device for controlling a computer and the like, and the prior art of power connection is not described in detail herein.

Although embodiments of the present utility model have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made therein without departing from the principles and spirit of the utility model, the scope of which is defined in the appended claims and their equivalents.

Claims (7)

1. An annular fin radiator, includes mounting frame (1), its characterized in that: the inner side of the installation frame (1) is provided with a pipeline assembly (200), and the inner side of the installation frame (1) is provided with a heat dissipation assembly (300);

the pipeline assembly (200) comprises a water outlet pipe (201) fixedly connected to the left side of the installation frame (1), a coiled pipe (202) is fixedly connected to the right end of the water outlet pipe (201), four supporting blocks (203) are fixedly connected between the outer side of the coiled pipe (202) and the inner side of the installation frame (1), a booster pump (204) is fixedly connected to the right end of the coiled pipe (202), a water inlet pipe (205) is fixedly connected to the right side of the booster pump (204), and four supporting legs (206) which are uniformly distributed are fixedly connected to the bottom of the installation frame (1);

the heat dissipation assembly (300) comprises ten heat conduction plates (301) which are slidably connected to the outer side of a coiled pipe (202), twenty annular plates (302) which are arranged at equal intervals are fixedly connected to the outer side of each heat conduction plate (301), communication holes (303) which are uniformly distributed are formed in the right side of each annular plate (302), ten positioning blocks (304) are fixedly connected to the outer side of each coiled pipe (202), two positioning holes (305) are formed in the top of each heat conduction plate (301) correspondingly, ten sliding blocks (306) are fixedly connected to the outer side of each coiled pipe (202), lifting blocks (307) are fixedly connected to the bottom of each sliding block (306), two sliding holes (308) are formed in the bottom of each corresponding five heat conduction plates (301), three butt joint blocks (309) are fixedly connected to the front face and the back of each heat conduction plate (301), bolts (310) are connected to the tops of the corresponding two butt joint blocks (309) through threads, and nuts (311) are connected to the outer sides of the bolts (310) through threads.

2. An annular fin heat sink as defined in claim 1, wherein: the front and the back of the mounting frame (1) are communicated with the outside, and a placing plate fixedly connected with the right side of the mounting frame (1) is fixedly connected to the bottom of the booster pump (204).

3. An annular fin heat sink as defined in claim 1, wherein: the heat conducting plates (301) are arc-shaped, and one sides of the two corresponding heat conducting plates (301) are attached to the outer sides of the coiled pipes (202).

4. An annular fin heat sink as defined in claim 1, wherein: the corresponding two positioning blocks (304) are positioned above the corresponding two sliding blocks (306), and the positioning blocks (304) can be inserted into the inner sides of the corresponding positioning holes (305).

5. An annular fin heat sink as defined in claim 1, wherein: the distance between the opposite sides of the corresponding two positioning blocks (304) is equal to the distance between the opposite sides of the corresponding two positioning holes (305), and the back surfaces of the sliding holes (308) are communicated with the outside.

6. An annular fin heat sink as defined in claim 1, wherein: the sliding blocks (306) can slide on the inner sides of the corresponding sliding holes (308), and the distance between the opposite sides of the two corresponding sliding blocks (306) is equal to the distance between the opposite sides of the two corresponding sliding holes (308).

7. An annular fin heat sink as defined in claim 1, wherein: a gasket is connected between opposite sides of the two corresponding butt joint blocks (309) in a sliding manner, and a through hole for the corresponding bolt (310) to penetrate is formed in the top of the gasket.