CN219511330U

CN219511330U - Fin spliced combined radiator

Info

Publication number: CN219511330U
Application number: CN202320822424.0U
Authority: CN
Inventors: 徐长荣
Original assignee: Taicang Xinggang Metal Material Co ltd
Current assignee: Taicang Xinggang Metal Material Co ltd
Priority date: 2023-04-14
Filing date: 2023-04-14
Publication date: 2023-08-11
Anticipated expiration: 2033-04-14

Abstract

The utility model relates to the technical field of radiators, and discloses a fin spliced combined radiator, which comprises two U-shaped plates, wherein a splicing assembly is arranged between the inner sides of the two U-shaped plates, and spring assemblies which are arranged at equal intervals are connected to the opposite sides of the two U-shaped plates; the splicing assembly comprises two insertion blocks fixedly connected with the left side of a right U-shaped plate, slots for inserting the insertion blocks are formed in the right side of the U-shaped plate, bolts penetrating through the slots and the insertion blocks in sequence are inserted into the top of the U-shaped plate, copper pipes which are arranged at equal distances are inserted between the opposite sides of the U-shaped plate, U-shaped insertion pipes are inserted between the left ends and the right ends of the copper pipes, and fins are fixedly mounted on the outer surfaces of the copper pipes. The fin spliced combined radiator can be spliced and assembled rapidly according to the use requirement of people, is simple and convenient to install, is convenient to produce and manufacture, and improves the practicability of the fin radiator.

Description

Fin spliced combined radiator

Technical Field

The utility model relates to the technical field of radiators, in particular to a fin spliced combined radiator.

Background

The fin type radiator is a heat exchange device which is most widely used in gas and liquid heat exchangers, and the heat transfer enhancement purpose is achieved by adding fins on a common base pipe, wherein the base pipe can be made of steel pipes, stainless steel pipes, copper pipes and the like, and the fins can also be made of steel belts, stainless steel belts, copper belts, aluminum belts and the like.

Although the appearance of fin formula radiator has been convenient people's daily use, still there is certain defect in current fin formula radiator when using, for example current fin formula radiator is generally with welded mode fixed connection, need install with the help of external equipment, and very time consuming and manpower are easy to appear damaging after long-time use fin formula radiator simultaneously, if not in time tear down the maintenance, can influence fin formula radiator's work efficiency, but welded structure is unfavorable for the maintenance of fin, can not satisfy people's user demand, has reduced fin formula radiator's practicality.

Disclosure of Invention

Technical problem to be solved

Aiming at the defects of the prior art, the utility model provides a fin-spliced combined radiator which has the advantages of being capable of being rapidly spliced and assembled for overhauling and the like, and solves the problem that the existing fin radiator cannot be spliced and assembled.

Technical proposal

In order to achieve the purpose of rapid splicing and assembly for overhauling, the utility model provides the following technical scheme: a fin spliced combined radiator comprises two U-shaped plates, wherein a splicing assembly is arranged between the inner sides of the two U-shaped plates, and spring assemblies which are arranged at equal distances are connected to the opposite sides of the two U-shaped plates;

the splicing assembly comprises two insertion blocks fixedly connected with the left side of a right U-shaped plate, a slot for the insertion blocks to be inserted is formed in the right side of the U-shaped plate on the left side, bolts which sequentially penetrate through the slot and the insertion blocks are inserted into the top of the U-shaped plate, copper pipes which are arranged at equal distances are inserted between the opposite sides of the two U-shaped plates, U-shaped insertion pipes are inserted between the left ends and the right ends of the upper and lower adjacent two copper pipes, and fins are fixedly arranged on the outer surfaces of the copper pipes;

the spring assembly comprises an annular connecting pipe which is inserted into the left end and the right end of a copper pipe, a rubber ring is fixedly connected to the inner side of the annular connecting pipe, a connecting rod which is arranged at equal distances is fixedly connected to one side of the U-shaped plate opposite to the other side of the U-shaped plate, a spring box body is fixedly connected to one side of the connecting rod opposite to the other side of the U-shaped plate, two telescopic columns are fixedly connected to the inner top wall of the spring box body, a T-shaped inserting rod is inserted into the inner side of the spring box body, a limiting plate is fixedly connected to the outer surface of the T-shaped inserting rod, a spring which is sleeved on the outer surface of the telescopic column is fixedly connected to the inner top wall of the spring box body, and an L-shaped clamping block which is fixedly connected with the U-shaped inserting pipe is inserted into the outer side of the T-shaped inserting rod.

Further, the telescopic column comprises a fixed loop bar and a sliding bar which is connected to the inner side of the fixed loop bar in a sliding way, the sum of the heights of the sliding bar and the fixed loop bar is larger than the height of the spring box body, and the bottom of the sliding bar is fixedly connected with the top of the limiting plate.

Further, the bottom end of the T-shaped inserted link sequentially penetrates through the corresponding spring box body, the limiting plate, the L-shaped clamping block and the copper pipe and extends to the interior of the corresponding annular connecting pipe to be spliced with the shape connecting pipe.

Furthermore, both ends of the U-shaped insertion tube are fixedly connected with the annular connecting tube, and the U-shaped insertion tube is spliced with the copper tube through the annular connecting tube.

Further, the copper pipe and the U-shaped insertion pipe are spliced to form a snake shape, and the length and the width of the insertion block are respectively equal to those of the insertion groove.

Further, the limiting plate is located inside the spring box body, the annular connecting pipe is T-shaped and is composed of the annular connecting pipe and an annular plate fixedly connected with one side of the U-shaped insertion pipe, and the outer diameter of the annular connecting pipe is equal to the inner diameter of the copper pipe.

Further, through holes for inserting copper pipes are formed in the opposite sides of the two U-shaped plates, and the fins are spiral.

Advantageous effects

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

this fin concatenation combination formula radiator uses through the mutually supporting of U shaped plate, splice assembly and spring assembly, can be according to the quick concatenation equipment of going on of demand that people used, and simple installation is convenient, can practice thrift a large amount of manpowers and time, and the maintenance after being favorable to the long-time use in later stage overhauls work and clean work of dust on the clean fin etc. guarantees the effective heat dissipation of fin, has satisfied people's user demand, has promoted the practicality of fin formula radiator.

Drawings

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

FIG. 2 is an enlarged schematic view of part A of the structure of the present utility model;

fig. 3 is an enlarged partial schematic view of the B part of the structure of the present utility model.

In the figure: 1U shaped plate, 300 splicing component, 301 inserting block, 302 inserting slot, 303 inserting pin, 304 copper pipe, 305U shaped inserting pipe, 306 fin, 400 spring component, 401 annular connecting pipe, 402 rubber ring, 403L shaped clamping block, 404 limiting plate, 405 connecting rod, 406 spring, 407 spring box, 408 telescopic column, 409T shaped inserting rod.

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. 1-3, the present utility model provides a technical solution: the utility model provides a fin concatenation combination formula radiator, including two U shaped plates 1, install splice assembly 300 between the inboard of two U shaped plates 1, one side that two U shaped plates 1 are opposite to each other all is connected with equidistant spring assembly 400 of arranging, through U shaped plate 1, splice assembly 300 and spring assembly 400's the use of mutually supporting, can splice the equipment fast according to the demand that people used, simple installation is convenient, can practice thrift a large amount of manpowers and time, the manufacturing of being convenient for, and be favorable to the maintenance after the long-time use of later stage to overhaul work and clean dust cleaning work etc. on the fin, guarantee the effective heat dissipation of fin, the user demand of people has been satisfied, fin formula radiator's practicality has been promoted.

The splice assembly 300 in this embodiment is a structure for splicing radiator bodies.

As shown in fig. 1, fig. 2 and fig. 3, the splicing assembly 300 comprises two insertion blocks 301 fixedly connected with the left side of the right side U-shaped plate 1, a slot 302 for inserting the insertion blocks 301 is formed in the right side of the left side U-shaped plate 1, a plug pin 303 penetrating through the slot 302 and the insertion blocks 301 in sequence is inserted at the top of the U-shaped plate 1, copper pipes 304 which are arranged at equal distances are inserted between the opposite sides of the two U-shaped plates 1, a U-shaped insertion pipe 305 is inserted between the left ends and the right ends of the upper and lower adjacent copper pipes 304, and fins 306 are fixedly arranged on the outer surfaces of the copper pipes 304.

It should be noted that, the copper tube 304 and the U-shaped insertion tube 305 are spliced to form a "snake" shape, so that the heat energy can circulate, and the length and width of the insertion block 301 are equal to the length and width of the insertion slot 302, respectively, so as to ensure that the insertion block 301 can be tightly attached to the insertion slot 302.

In addition, through holes for inserting copper pipes 304 are formed in the opposite sides of the two U-shaped plates 1, so that the U-shaped insertion pipes 305 can be conveniently inserted, and the fins 306 are spiral, so that heat energy can be uniformly emitted.

The spring assembly 400 in this embodiment is a structure for splicing the copper tube 304 and the U-shaped cannula 305.

As shown in fig. 1 and 2, the spring assembly 400 includes an annular connecting pipe 401 inserted into both left and right ends of the copper pipe 304, a rubber ring 402 is fixedly connected to the inner side of the annular connecting pipe 401, connecting rods 405 arranged at equal distances are fixedly connected to opposite sides of the U-shaped plates 1 on the left and right sides, a spring box 407 is fixedly connected to opposite sides of the connecting rods 405, two telescopic columns 408 are fixedly connected to the inner top wall of the spring box 407, a T-shaped inserting rod 409 is inserted into the spring box 407, a limiting plate 404 is fixedly connected to the outer surface of the T-shaped inserting rod 409, a spring 406 sleeved on the outer surface of the telescopic column 408 is fixedly connected between the inner top wall of the spring box 407 and the top of the corresponding limiting plate 404, and an L-shaped clamping block 403 fixedly connected with the U-shaped inserting pipe 305 is inserted into the outer side of the T-shaped inserting rod 409.

It should be noted that, the telescopic column 408 is composed of a fixed loop bar and a sliding bar slidingly connected inside the fixed loop bar, the sum of the heights of the sliding bar and the fixed loop bar is greater than the height of the spring box 407, so as to ensure that the fixed loop bar and the sliding bar cannot fall off, the bottom of the sliding bar is fixedly connected with the top of the limiting plate 404, and the limiting plate 404 is convenient to squeeze the sliding bar and the spring 406.

In addition, the bottom end of the T-shaped inserting rod 409 sequentially penetrates through the corresponding spring box 407, the limiting plate 404, the L-shaped clamping block 403 and the copper pipe 304 and extends into the corresponding annular connecting pipe 401 to be inserted into the annular connecting pipe 401, so that the bottom of the T-shaped inserting rod 409 can be inserted into the annular connecting pipe 401, deflection is prevented, two ends of the U-shaped inserting pipe 305 are fixedly connected with the annular connecting pipe 401, and the U-shaped inserting pipe 305 can be spliced and combined with the copper pipe 304.

Meanwhile, the U-shaped insertion tube 305 is inserted into the copper tube 304 through the annular connection tube 401, the U-shaped insertion tube 305 is communicated with the copper tube 304 through the annular connection tube 401, the butt joint communication is facilitated, the limiting plate 404 is located in the spring box 407, the sliding rod and the spring 406 are conveniently extruded, the annular connection tube 401 is T-shaped and is composed of the annular connection tube 401 and an annular plate fixedly connected with one side close to the U-shaped insertion tube 305, the easy detachment is conveniently prevented by the convenient splicing, the outer diameter of the annular connection tube 401 is equal to the inner diameter of the copper tube 304, the insertion is conveniently performed, and liquid leakage or air leakage is prevented.

The working principle of the embodiment is as follows: when the fin splicing combined radiator is required to be assembled, firstly, copper tubes 304 are sequentially inserted between through holes on the left side and the right side of two U-shaped plates 1, then an insertion block 301 of the right side U-shaped plate 1 is inserted into a slot 302 of the left side U-shaped plate 1, secondly, a bolt 303 is inserted into the U-shaped plate 1, the slot 302 and the insertion block 301 to be fixed, the two U-shaped plates 1 are spliced and fixed, a T-shaped inserting rod 409 is pulled upwards until the bottom of a spring box 407 is reached, so that a limiting plate 404 is driven to move upwards, a spring 406 and a telescopic column 408 can be compressed in the spring box 407, then annular connecting tubes 401 at the two ends of the U-shaped inserting tubes 305 are aligned with two adjacent copper tubes 304 and are inserted, meanwhile, the L-shaped clamping blocks 403 are driven to be inserted between the corresponding spring box 407 and the copper tubes 304, then the T-shaped inserting rod 409 is released, under the elastic restoring action of the spring 406, the T-shaped inserting rod 409 is pushed by the spring 406 to move downwards, so that the T-shaped inserting rod 409 penetrates through the L-shaped clamping blocks 403 and the copper tubes 304 and is spliced into the annular connecting tubes 401, and the U-shaped inserting tubes 401 are spliced and assembled.

Compared with the prior art, this fin concatenation combination formula radiator uses through the mutually supporting of U-shaped board 1, splice assembly 300 and spring assembly 400, can be according to the quick concatenation equipment of going on of demand that people used, the installation is simple convenient, can practice thrift a large amount of manpowers and time, the production of being convenient for is manufactured, and be favorable to maintenance work after long-time use and clean work of dust etc. on the clean fin later stage, guarantee the effective heat dissipation of fin, satisfied people's user demand, promoted the practicality of fin formula radiator, solved the problem that current fin formula radiator can not splice the equipment.

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

1. The utility model provides a fin concatenation combination formula radiator, includes two U-shaped boards (1), its characterized in that: a splicing assembly (300) is arranged between the inner sides of the two U-shaped plates (1), and spring assemblies (400) which are arranged at equal intervals are connected to one sides of the two U-shaped plates (1) which are opposite to each other;

the splicing assembly (300) comprises two insertion blocks (301) fixedly connected with the left side of a right U-shaped plate (1), slots (302) for the insertion blocks (301) to be inserted are formed in the right side of the U-shaped plate (1) on the left side, bolts (303) penetrating through the slots (302) and the insertion blocks (301) in sequence are inserted into the tops of the U-shaped plate (1), copper pipes (304) which are arranged at equal distances are inserted between the opposite sides of the two U-shaped plates (1), U-shaped insertion pipes (305) are inserted between the left ends and the right ends of the upper adjacent copper pipes (304) and the lower adjacent copper pipes, and fins (306) are fixedly arranged on the outer surfaces of the copper pipes (304);

the spring assembly (400) comprises an annular connecting pipe (401) which is inserted into the left end and the right end of a copper pipe (304), a rubber ring (402) is fixedly connected to the inner side of the annular connecting pipe (401), connecting rods (405) which are arranged at equal distances are fixedly connected to the opposite sides of the U-shaped plate (1), spring boxes (407) are fixedly connected to the opposite sides of the connecting rods (405), two telescopic columns (408) are fixedly connected to the inner top wall of each spring box (407), T-shaped inserting rods (409) are inserted into the spring boxes (407), limiting plates (404) are fixedly connected to the outer surfaces of the T-shaped inserting rods (409), springs (406) which are sleeved on the outer surfaces of the telescopic columns (408) are fixedly connected between the inner top wall of each spring box (407) and the top of the corresponding limiting plate (404), and L-shaped clamping blocks (403) which are fixedly connected with the U-shaped inserting tubes (305) are inserted into the outer sides of the T-shaped inserting rods (409).

2. The fin-splice modular heat sink of claim 1 wherein: the telescopic column (408) consists of a fixed loop bar and a sliding bar which is connected to the inner side of the fixed loop bar in a sliding way, the sum of the heights of the sliding bar and the fixed loop bar is larger than the height of the spring box body (407), and the bottom of the sliding bar is fixedly connected with the top of the limiting plate (404).

3. The fin-splice modular heat sink of claim 1 wherein: the bottom end of the T-shaped inserting rod (409) sequentially penetrates through the corresponding spring box body (407), the limiting plate (404), the L-shaped clamping block (403) and the copper pipe (304) and extends the inside of the corresponding annular connecting pipe (401) to be inserted into the corresponding annular connecting pipe (401).

4. The fin-splice modular heat sink of claim 1 wherein: both ends of the U-shaped insertion pipe (305) are fixedly connected with the annular connecting pipe (401), and the U-shaped insertion pipe (305) is spliced with the copper pipe (304) through the annular connecting pipe (401).

5. The fin-splice modular heat sink of claim 1 wherein: the copper pipe (304) and the U-shaped insertion pipe (305) are spliced to form a snake shape, and the length and the width of the insertion block (301) are respectively equal to those of the insertion groove (302).

6. The fin-splice modular heat sink of claim 1 wherein: the limiting plate (404) is positioned in the spring box body (407), the annular connecting pipe (401) is T-shaped and is composed of the annular connecting pipe (401) and an annular plate fixedly connected with one side close to the U-shaped insertion pipe (305), and the outer diameter of the annular connecting pipe (401) is equal to the inner diameter of the copper pipe (304).

7. The fin-splice modular heat sink of claim 1 wherein: two U-shaped plates (1) are provided with through holes for inserting copper pipes (304) on one sides opposite to each other, and fins (306) are spiral.