CN221055612U - Buckling type radiator - Google Patents

Abstract

The utility model discloses a buckling type radiator, and relates to the technical field of radiators. The heat conducting plate comprises a heat conducting plate, contact plates, rotating strips and an inserting frame, wherein fixing plates are fixed on two sides of the heat conducting plate, one end of each fixing plate is fixedly provided with a fixing block, the two fixing blocks are symmetrical with each other in a central mode through the center of the heat conducting plate, a heat conducting silica gel pad is fixed at the center of the bottom of the heat conducting plate, the contact plates are fixed at the bottoms of the heat conducting silica gel pads, the rotating strips are arranged above each fixing plate, the two rotating strips are symmetrical with each other in the central mode through the center of the heat conducting plate, and the inserting frame is arranged outside one side, far away from the fixing plate, of each fixing plate. The utility model solves the problems that when the buckling type radiator works, gaps are easily generated between the radiator and a structure needing heat radiation because of material deformation, and the radiator is easy to be bounced because of linkage of two connecting rods, so that the radiator needs to be realigned because of the linkage of the two connecting rods.

Description

Buckling type radiator

Technical Field

The utility model belongs to the technical field of radiators, and particularly relates to a buckling type radiator.

Background

The radiator is a collective name of a series of devices for conducting and releasing heat, the radiator at present mainly comprises a heating radiator and a computer radiator, wherein the heating radiator can be divided into a plurality of types according to materials and working modes, the computer radiator can be divided into a plurality of types according to purposes and installation methods, wherein the buckling type radiator can be well pressed on a structure needing heat radiation, so that when working, the radiator can well conduct heat radiation of a jointing element, but the radiator still has the following defects in actual use:

when the buckling type radiator works, the hard plate is directly adopted for extrusion, and in the extrusion process, gaps are easily generated between the radiator and a structure needing heat dissipation due to deformation of materials, so that the heat dissipation efficiency is affected;

When the buckling type radiator works, the buckling type radiator is directly extruded by adopting a pressed structure, and when the buckling type radiator is extruded, the operation is easy to cause in the working process, the operation is carried out by hands, and the radiator is easy to spring because of the linkage of the two connecting rods, so that the radiator needs to be realigned, and the operation is inconvenient.

Disclosure of utility model

The utility model aims to provide a buckling type radiator, which solves the problems that when the buckling type radiator works, gaps are easily generated between the radiator and a structure needing heat radiation because of material deformation and the radiator is easily required to be realigned because of the linkage of two connecting rods by arranging a heat conducting plate, a contact plate, a rotating bar and an inserting frame.

In order to solve the technical problems, the utility model is realized by the following technical scheme:

The utility model relates to a buckling type radiator which comprises a heat conducting plate, contact plates, rotating strips and inserting frames, wherein fixing plates are fixed on two sides of the heat conducting plate, one end of each fixing plate is fixedly provided with a fixing block, the two fixing blocks are symmetrical with each other in the center of the heat conducting plate, a heat conducting silica gel pad is fixed at the center of the bottom of the heat conducting plate, the contact plates are fixed at the bottoms of the heat conducting silica gel pads, the rotating strips are arranged above each fixing plate, the centers of the two rotating strips are symmetrical in the center of the heat conducting plate, the inserting frames are arranged outside one side, away from the fixing plates, of each fixing plate, when the buckling type radiator works, heat is transferred onto the heat conducting silica gel pad through the structure of heat dissipation, and then transferred onto the heat conducting plate through a plate spring on the rotating strips, and the contact plates are well limited through the inserting frames.

Further, a plurality of cooling fins are longitudinally fixed on the top of the heat conducting plate, the distances between the adjacent cooling fins are equal, and the heat conducting plate dissipates heat through the cooling fins.

Further, the outside of heat conduction silica gel pad is fixed with fixed frame, the bottom at the heat-conducting plate is fixed at the top of fixed frame, fixed frame sets up in the top of contact plate, and heat conduction silica gel pad passes through fixed frame protection heat conduction silica gel pad.

Further, the bottom mouth has been seted up to the bottom of changeing the strip, the end mouth internal fixation has the leaf spring, the bottom butt of leaf spring is at the top of fixed plate, changes the strip and is at the during operation, fixes the leaf spring above that through the end mouth, compresses tightly through the leaf spring.

Further, one end of the rotating bar is fixed with a rotating column, the bottom ends of the two rotating columns are respectively connected to the tops of the two fixing blocks in a rotating mode, two rotating bars are fixed with connecting plates at the edges of the short sides of the rotating bars, which are far away from one side of the heat conducting plate and far away from the rotating column, side inserting blocks are fixed on one side, close to the heat conducting plate, of the connecting plates below the rotating bars, the rotating bars are connected to the fixing blocks in a rotating mode through the rotating columns, and the side inserting blocks on the connecting plates are movably connected with the inserting frames.

Further, two side inserts are respectively inserted into two insert frames, bottom welding plates are fixed at the bottoms of the insert frames, the bottoms of the insert frames are welded on the outer sides of proper equipment, and the installation of the heat conducting plates and the contact plates is assisted.

The utility model has the following beneficial effects:

The heat conducting plate and the contact plate are arranged, so that the problem that gaps are easily generated between the radiator and the structure needing heat dissipation due to material deformation when the buckled radiator works is solved, the bottom of the contact plate is abutted against the structure needing heat dissipation after the heat conducting plate is installed when the buckled radiator works, heat on the structure needing heat dissipation is transferred to the heat conducting silica gel pad through the contact plate and then transferred to the heat conducting plate through the heat conducting silica gel pad, and when the buckled radiator works, the heat on the heat radiating plate is taken away through air when the air passes through the heat radiating plate, and the gaps generated between the radiator and the structure needing heat dissipation are smaller when the buckled radiator works.

The utility model solves the problem that the radiator needs to be realigned due to the fact that the radiator is easy to spring because of the linkage of the two connecting rods when the buckling radiator works by arranging the heat conducting plate, the rotating strip and the inserting frame, the bottom of the contact plate is placed on a structure needing heat dissipation, the rotating strip is rotated immediately, the rotating strip is rotated to the top of the fixed plate, and in the process, the side inserting block on the connecting plate is inserted into the inserting frame, so that the heat conducting plate and the contact plate are arranged outside the structure needing heat dissipation when the buckling radiator works, and therefore deflection is prevented when the buckling radiator is arranged when the buckling radiator works.

Drawings

FIG. 1 is a perspective view of an assembly structure of a clip-on radiator;

FIG. 2 is a perspective view of a heat conducting plate structure;

FIG. 3 is a perspective view of a partially cut-away structure of a contact plate;

FIG. 4 is a perspective view of a rotating bar structure;

fig. 5 is a perspective view of a plug frame structure.

Reference numerals:

1. A heat conductive plate; 101. a fixing plate; 102. a fixed block; 103. a heat sink; 2. a contact plate; 201. a thermally conductive silicone pad; 202. a fixed frame; 3. rotating the strip; 301. a rotating column; 302. a bottom opening; 303. a leaf spring; 304. a connecting plate; 305. a side plug block; 4. inserting a frame; 401. and (5) a bottom welding plate.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

Detailed description of the preferred embodiments

Referring to fig. 1-5, the present utility model is a withhold type radiator, which comprises a heat conducting plate 1, a contact plate 2, rotating strips 3 and an inserting frame 4, wherein both sides of the heat conducting plate 1 are fixed with a fixing plate 101, when the heat conducting plate 1 works, heat on the heat conducting silica gel pad 201 is transferred to the heat radiating plate 103 for radiating, one end of each fixing plate 101 is fixed with a fixing block 102, the two fixing blocks 102 are centered with the center of the heat conducting plate 1, so that the two rotating strips 3 can be connected with both sides of the heat conducting plate 1 in a centered manner, the bottom center of the heat conducting plate 1 is fixed with the heat conducting silica gel pad 201, the bottom of the heat conducting silica gel pad 201 is fixed with the contact plate 2, the bottom of the contact plate 2 is abutted to a proper structural position for conducting heat, the heat on the material contacted on the contact plate 2 is conducted to the heat conducting plate 1 through the heat conducting silica gel pad 201, the upper part of each fixing plate 101 is provided with the rotating strips 3, the centers of the two rotating strips 3 are centered with the heat conducting plate 1, the two rotating strips 3 are centered with the heat conducting plate 1 and are centered and connected with both sides of the fixing plate 101 after the rotating strips 1 are pressed onto the fixing plate 101, the bottom of the heat conducting plate 101 is mounted, and the inserting frame 4 is provided, and one side of the heat conducting plate 101 is far from the outside is limited.

Specifically, a plurality of cooling fins 103 are longitudinally fixed on the top of the heat conducting plate 1, the distances between the adjacent cooling fins 103 are equal, and the heat conducting plate 1 dissipates heat through the cooling fins 103.

Further, a fixing frame 202 is fixed on the outer side of the heat-conducting silica gel pad 201, the top of the fixing frame 202 is fixed on the bottom of the heat-conducting plate 1, the fixing frame 202 is arranged above the contact plate 2, and after the heat-conducting silica gel pad 201 passes through a gap between the heat-conducting silica gel pad and the fixing frame 202, the heat-conducting plate 1 is installed on a proper structure and then is pressed on a corresponding structure, so that heat on the corresponding structure is transferred to the contact plate 2.

The operation process of the embodiment is as follows: when the heat conducting plate 1 works, after the heat conducting plate is installed, the bottom of the contact plate 2 is abutted to a structure needing heat dissipation, at the moment, heat on the structure needing heat dissipation is transferred to the heat conducting silica gel pad 201 through the contact plate 2, then is transferred to the heat conducting plate 1 through the heat conducting silica gel pad 201, and is transferred to the heat dissipation fins 103 through the heat plate, so that when the heat conducting plate works, the heat on the heat dissipation fins 103 is taken away when the air passes through the heat dissipation fins 103, and the heat dissipation is carried out rapidly.

Second embodiment

Referring to fig. 1, 2, 4 and 5, in the first embodiment, a bottom opening 302 is formed at the bottom of the rotating bar 3, a plate spring 303 is fixed in the bottom opening 302, the bottom of the plate spring 303 is abutted against the top of the fixing plate 101, and when the rotating bar 3 works, the plate 101 is fixed through the bottom opening 302 and is abutted against the top of the fixing plate 101 through the plate spring 303, so that the heat conducting plate 1 and the contact plate 2 are installed on a proper structure.

Specifically, one end of the rotating bar 3 is fixed with a rotating post 301, the bottom ends of the two rotating posts 301 are respectively connected to the tops of the two fixed blocks 102 in a rotating mode, a connecting plate 304 is fixed at the edge of the short side, away from the heat conducting plate 1, of the two rotating bars 3, a side inserting block 305 is fixed at the side, close to the heat conducting plate 1, of the connecting plate 304 below the rotating bar 3, the rotating bar 3 is connected to the top of the fixed block 102 in a rotating mode through the rotating post 301, the side inserting block 305 on the connecting plate 304 is inserted into the inserting frame 4, and the heat conducting plate 1 and the contact plate 2 are installed.

Further, two side plug blocks 305 are respectively inserted into two plug frames 4, the bottom of each plug frame 4 is fixed with a bottom welding plate 401, and when the heat conduction plate 1 and the contact plate 2 are installed by inserting the side plug blocks 305 into the plug frames 4, the bottom of the external heat dissipation structure is required by welding the bottom welding plates 401, and the plug frames 4 are installed on the corresponding structures.

The operation process of the embodiment is as follows: when the heat radiation device works, firstly, the bottom of the contact plate 2 is placed on a structure needing heat radiation, then the rotating strip 3 is rotated, so that the rotating strip 3 is rotated to the top of the fixed plate 101, and in the process, the side plug blocks 305 on the connecting plate 304 are inserted into the plug frame 4, so that when the heat radiation device works, the heat conduction plate 1 and the contact plate 2 are arranged on the outer side of the structure needing heat radiation.

In the description of the present specification, the descriptions of the terms "one embodiment," "example," "specific example," and the like, mean that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the present utility model. In this specification, schematic representations of the above terms do not necessarily refer to the same embodiments or examples. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples.

The preferred embodiments of the utility model disclosed above are intended only to assist in the explanation of the utility model. The preferred embodiments are not exhaustive or to limit the utility model to the precise form disclosed. Obviously, many modifications and variations are possible in light of the above teaching. The embodiments were chosen and described in order to best explain the principles of the utility model and the practical application, to thereby enable others skilled in the art to best understand and utilize the utility model. The utility model is limited only by the claims and the full scope and equivalents thereof.

Claims (6)

1. The utility model provides a withhold formula radiator, includes heat-conducting plate (1), contact plate (2), changeing strip (3) and inserts frame (4), its characterized in that: both sides of heat conduction board (1) all are fixed with fixed plate (101), every the one end of fixed plate (101) all is fixed with fixed block (102), two fixed block (102) are central symmetry with the center of heat conduction board (1), the bottom central authorities of heat conduction board (1) are fixed with heat conduction silica gel pad (201), the bottom of heat conduction silica gel pad (201) is fixed with contact plate (2), every the top of fixed plate (101) all is provided with changes strip (3), two change strip (3) are central symmetry with heat conduction board (1) center, every the outside that fixed plate (101) were kept away from fixed plate (101) one side all is provided with plug frame (4).

2. A clip-on heat sink as defined in claim 1, wherein: a plurality of radiating fins (103) are longitudinally fixed at the top of the heat conducting plate (1), and the distances between every two adjacent radiating fins (103) are equal.

3. A clip-on heat sink as defined in claim 1, wherein: the heat conduction silica gel pad is characterized in that a fixing frame (202) is fixed on the outer side of the heat conduction silica gel pad (201), the top of the fixing frame (202) is fixed at the bottom of the heat conduction plate (1), and the fixing frame (202) is arranged above the contact plate (2).

4. A clip-on heat sink as defined in claim 1, wherein: the bottom opening (302) has been seted up to the bottom of changeing strip (3), bottom opening (302) internal fixation has leaf spring (303), the bottom butt of leaf spring (303) is at the top of fixed plate (101).

5. A clip-on heat sink as defined in claim 4, wherein: one end of the rotating bar (3) is fixed with a rotating column (301), the bottoms of the two rotating columns (301) are respectively connected to the tops of the two fixing blocks (102) in a rotating mode, the two rotating bars (3) are away from one side of the heat conducting plate (1) and are away from the edge of the short side of the rotating column (301), connecting plates (304) below the rotating bars (3) are fixed with side inserting blocks (305) on one side, close to the heat conducting plate (1), of the connecting plates (304).

6. A clip-on heat sink as defined in claim 5, wherein: the two side plug blocks (305) are respectively inserted into the two plug frames (4), and bottom welding plates (401) are fixed at the bottom of each plug frame (4).