CN221429128U - Graphene high-temperature radiator convenient for increasing temperature stability - Google Patents

Abstract

The utility model discloses a graphene high-temperature radiator convenient for increasing temperature stability, which belongs to the technical field of graphene high-temperature radiators and comprises a heat outlet panel, wherein a heat outlet hole is formed in one side of the heat outlet panel, a shell is arranged on the other side of the heat outlet panel, an annular groove is formed in one side of the heat outlet panel and at a position corresponding to the shell, the bottom end of the shell is in sliding connection with the inner wall of the annular groove, a clamping assembly is arranged between the heat outlet panel and the shell, and the bottom end of the shell is fixedly arranged in the annular groove through the clamping assembly; according to the radiator, the shell is inserted into the annular groove formed in the surface of the heat-out panel through the arrangement of the annular groove and the clamping assembly, and the clamping assembly is used for fixing the shell, so that an operator can conveniently install or detach the shell and the heat-out panel, the operator can conveniently overhaul the radiator, and the working efficiency is improved.

Description

Graphene high-temperature radiator convenient for increasing temperature stability

Technical Field

The utility model relates to the technical field of graphene high-temperature radiators, in particular to a graphene high-temperature radiator convenient for increasing temperature stability.

Background

The graphene heating principle is based on the characteristic of single-layer graphene, and firstly, the graphene is the material with the highest heat conductivity coefficient so far and has very good heat conductivity. The existing graphene high-temperature radiator is inconvenient to install or detach, and is troublesome when overhauling the radiator.

The Chinese patent with the application number of CN202021335755.4 discloses an infrared radiation warmer for heating high-temperature graphene, which comprises a molding frame welded by T-shaped sections, wherein a back cover is arranged on the molding frame, an installation chamber is formed between the back cover and the molding frame, a partition plate formed by the T-shaped sections is arranged in the installation chamber, the partition plate divides the installation chamber into a heating area and a temperature display area, a graphene heating element and a heat preservation component are arranged in the heating area, and a temperature display element is arranged in the temperature display area; the graphene heating element comprises microcrystalline glass arranged in a heating area, the microcrystalline glass is coated with a graphene heating layer in a back direction, and conductive electrodes are respectively arranged on two sides of the graphene heating layer; the heat preservation component comprises a protective cover, and a heat insulation mica plate covered on the graphene heating element and an asbestos heat preservation block clung to the heat insulation mica plate are arranged in the protective cover.

The graphene high-temperature radiator in the above patent also has the problem of inconvenient disassembly, and operators are affected to overhaul the radiator, so that the graphene high-temperature radiator convenient for increasing the temperature stability is required.

Disclosure of utility model

The utility model aims to provide a graphene high-temperature radiator with the advantage of being convenient for increasing temperature stability, which is provided with a structure convenient for mounting and dismounting the graphene high-temperature radiator so as to solve the problems in the background art.

In order to achieve the above purpose, the present utility model provides the following technical solutions: the utility model provides a graphite alkene high temperature radiator convenient to increase temperature stability, includes out hot panel, one side that goes out hot panel is provided with out the hot hole, the opposite side that goes out the hot panel is provided with the casing, one side that goes out the hot panel just is located the casing corresponds the department and is provided with the ring channel, the bottom of casing with the inner wall sliding connection of ring channel, go out the hot panel with be provided with the joint subassembly between the casing, the bottom of casing pass through joint subassembly fixed mounting in the inside of ring channel.

Preferably, the clamping assembly is provided with four groups, and four groups the clamping assembly is all distributed in the four corners of going out the hot panel, the clamping assembly is including locating go out the through-hole of hot panel one end, the inside looks adaptation of through-hole is provided with the gag lever post, the gag lever post with through-hole sliding connection, the one end of gag lever post runs through out the hot panel and extends to the ring channel inside and be provided with the fixture block.

Preferably, the clamping assembly further comprises a channel formed in the inner wall of the annular groove, the channel is in adaptive arrangement with the clamping block, the clamping block is in sliding connection with the inner wall of the channel, a telescopic spring is arranged in the channel, one end of the telescopic spring is fixedly mounted on the inner wall of one end of the channel, and the other end of the telescopic spring is fixedly connected with one end of the clamping block.

Preferably, the clamping assembly further comprises a limiting groove formed in the inner wall of one end of the shell, the inside of the limiting groove is in fit with the clamping block, and the surface of the clamping block is in sliding connection with the inner wall of the limiting groove.

Preferably, fixing plates are arranged at two ends of one side of the heat-out panel, two groups of fixing plates are distributed on the inner side of the annular groove, and heating components are arranged between the two groups of fixing plates.

Preferably, the heating component comprises a graphene heating layer fixedly mounted on the inner side of the heat-emitting panel, one side of the graphene heating layer is connected with a heat insulation layer, one side of the heat insulation layer is provided with a heat insulation structure, and the outer side of the heat insulation structure is provided with a fixing component.

Preferably, the fixed subassembly is including seting up in the spacing hole in fixed plate outside both ends, the inside looks adaptation in spacing hole is provided with the installation pole, the surface of installation pole with the inner wall sliding connection in spacing hole.

Preferably, the fixed subassembly is still including locating the installation shell in the insulation construction outside, the both ends of installation shell both sides all are provided with the mounting hole, the mounting hole with the installation pole is looks adaptation setting, the bottom of installation pole with the inner wall threaded connection of mounting hole.

Compared with the prior art, the utility model has the beneficial effects that:

According to the radiator, the shell is inserted into the annular groove formed in the surface of the heat-out panel through the arrangement of the annular groove and the clamping assembly, and the clamping assembly is used for fixing the shell, so that an operator can conveniently install or detach the shell and the heat-out panel, the operator can conveniently overhaul the radiator, and the working efficiency is improved.

Drawings

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

FIG. 2 is a schematic cross-sectional view of the present utility model in plan view;

FIG. 3 is a schematic view of a three-dimensional cross-sectional structure of the present utility model;

FIG. 4 is an enlarged schematic view of the structure of FIG. 3A according to the present utility model;

Fig. 5 is a schematic perspective view of a heat panel according to the present utility model.

In the figure: 1. a heat-out panel; 2. a housing; 3. a heat outlet hole; 4. a limit rod; 5. a fixing plate; 6. a mounting shell; 7. a thermal insulation structure; 701. a first asbestos insulation block; 702. a second asbestos insulation block; 8. a thermal insulation layer; 9. a graphene heating layer; 10. a mounting hole; 11. a limiting hole; 12. a mounting rod; 13. a telescopic spring; 14. a channel; 15. a clamping block; 16. a limit groove; 17. an annular groove; 18. and a through hole.

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.

Referring to fig. 1-5, the present utility model provides a technical solution: the graphene high-temperature radiator convenient for increasing the temperature stability comprises a heat outlet panel 1, wherein a heat outlet hole 3 is formed in one side of the heat outlet panel 1, a shell 2 is arranged on the other side of the heat outlet panel 1, an annular groove 17 is formed in one side of the heat outlet panel 1 and located at a position corresponding to the shell 2, the bottom end of the shell 2 is in sliding connection with the inner wall of the annular groove 17, a clamping assembly is arranged between the heat outlet panel 1 and the shell 2, and the bottom end of the shell 2 is fixedly arranged in the annular groove 17 through the clamping assembly; the clamping assembly is provided with four groups, the four groups of clamping assemblies are distributed at four corners of the heat outlet panel 1, the clamping assembly comprises through holes 18 formed in one end of the heat outlet panel 1, a limiting rod 4 is arranged in the through holes 18 in a matched mode, the limiting rod 4 is in sliding connection with the through holes 18, and one end of the limiting rod 4 penetrates through the heat outlet panel 1 and extends into the annular groove 17 to be provided with a clamping block 15; the clamping assembly further comprises a channel 14 formed in the inner wall of the annular groove 17, the channel 14 and the clamping block 15 are arranged in a matched mode, the clamping block 15 is connected with the inner wall of the channel 14 in a sliding mode, a telescopic spring 13 is arranged in the channel 14, one end of the telescopic spring 13 is fixedly arranged on the inner wall of one end of the channel 14, and the other end of the telescopic spring 13 is fixedly connected with one end of the clamping block 15; the clamping assembly further comprises a limiting groove 16 formed in the inner wall of one end of the shell 2, the inside of the limiting groove 16 is arranged in a matched mode with the clamping block 15, and the surface of the clamping block 15 is slidably connected with the inner wall of the limiting groove 16.

Specifically, through the setting of joint subassembly, insert the casing 2 and go out the ring channel 17 inside that the hot panel 1 surface was seted up, utilize joint subassembly to fix casing 2, be convenient for the operation personnel to install or dismantle casing 2 and play hot panel 1, can make things convenient for the operation personnel to overhaul the radiator, be convenient for improve work efficiency, promote gag lever post 4 inwards, the gag lever post 4 outwards removes from through-hole 18, the fixture block 15 that is installed with gag lever post 4 one end removes, let fixture block 15 move into the inside of channel 14, let telescopic spring 13 receive the effort, then insert the inside of ring channel 17 with casing 2, loosen gag lever post 4, the effort that telescopic spring 13 received can promote fixture block 15 and follow the inside removal of channel 14, let fixture block 15 get into in the spacing groove 16 that casing 2 inner wall was seted up, and then can fix casing 2 and play hot panel 1, let casing 2 can not produce the slip, be convenient for install or dismantle casing 2 and play hot panel 1.

Preferably, two ends of one side of the heat-out panel 1 are provided with fixing plates 5, two groups of fixing plates 5 are distributed on the inner side of the annular groove 17, and a heating assembly is arranged between the two groups of fixing plates 5; heating assembly is including fixed mounting in the inboard graphite alkene layer 9 that generates heat of play heat panel 1, and one side of graphite alkene layer 9 that generates heat is connected with insulating layer 8, and one side of insulating layer 8 is provided with insulation construction 7, through the setting of two sets of fixed plates 5, can be convenient for fix the inside heating assembly.

Specifically, through heating the setting of subassembly, can let the radiator produce the heat at the during operation, the heat of layer 9 production generates heat by graphite alkene, with heat diffusion to all around, utilize insulating layer 8's setting, the heat that layer 9 produced generates heat with graphite alkene keeps apart, change the direction of heat transfer, let the heat can follow the apopore 3 of seting up on the surface of apopore 1 and give off, and then facilitate the use, simultaneously, insulation structure 7 includes first asbestos insulation block 701 and second asbestos insulation block 702, will protect the heat further, avoid the heat to give off from other directions, let the heat concentrate and give off from apopore 3.

Preferably, a fixing component is arranged on the outer side of the heat insulation structure 7; the fixing component comprises limit holes 11 which are formed in the two ends of the outer side of the fixing plate 5, mounting rods 12 are arranged in the limit holes 11 in a matched mode, and the surfaces of the mounting rods 12 are in sliding connection with the inner walls of the limit holes 11; the fixed subassembly is still including locating the installation shell 6 in the insulation construction 7 outside, the both ends of installation shell 6 both sides all are provided with mounting hole 10, mounting hole 10 is the looks adaptation setting with installation pole 12, the bottom of installation pole 12 and the inner wall threaded connection of mounting hole 10, through the setting of fixed subassembly, can fix the subassembly that heats, avoid letting graphene receive the damage, influence heating efficiency, laminate installation shell 6 and insulation construction 7, then pass spacing hole 11 and the mounting hole 10 threaded connection of installation shell 6 tip on fixed plate 5 surface with installation pole 12, and then can let installation shell 6 extrude the subassembly that heats, avoid the subassembly that heats to produce the slip, cause the damage.

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 (8)

1. Graphene high-temperature radiator convenient to increase temperature stability, and characterized in that: including going out hot panel (1), one side that goes out hot panel (1) is provided with out hot hole (3), the opposite side that goes out hot panel (1) is provided with casing (2), go out one side of hot panel (1) and be located casing (2) correspond the department and be provided with ring channel (17), the bottom of casing (2) with the inner wall sliding connection of ring channel (17), go out hot panel (1) with be provided with the joint subassembly between casing (2), the bottom of casing (2) pass through joint subassembly fixed mounting in the inside of ring channel (17).

2. The graphene high temperature radiator facilitating increased temperature stability of claim 1, wherein: the clamping assembly is provided with four groups, the four groups of clamping assemblies are distributed at four corners of the heat outlet panel (1), the clamping assembly comprises through holes (18) formed in one end of the heat outlet panel (1), limiting rods (4) are arranged in the through holes (18) in a matched mode, the limiting rods (4) are in sliding connection with the through holes (18), and one ends of the limiting rods (4) penetrate through the heat outlet panel (1) and extend to the annular grooves (17) to be provided with clamping blocks (15).

3. The graphene high temperature radiator facilitating increased temperature stability of claim 2, wherein: the clamping assembly further comprises a channel (14) formed in the inner wall of the annular groove (17), the channel (14) is arranged in a matched mode with the clamping block (15), the clamping block (15) is slidably connected with the inner wall of the channel (14), a telescopic spring (13) is arranged in the channel (14), one end of the telescopic spring (13) is fixedly mounted on the inner wall of one end of the channel (14), and the other end of the telescopic spring (13) is fixedly connected with one end of the clamping block (15).

4. The graphene high temperature radiator facilitating increased temperature stability of claim 3, wherein: the clamping assembly further comprises a limiting groove (16) formed in the inner wall of one end of the shell (2), the inside of the limiting groove (16) is in fit with the clamping block (15), and the surface of the clamping block (15) is in sliding connection with the inner wall of the limiting groove (16).

5. The graphene high temperature radiator facilitating increased temperature stability of claim 1, wherein: two ends of one side of the heat outlet panel (1) are provided with fixing plates (5), two groups of fixing plates (5) are distributed on the inner side of the annular groove (17), and heating components are arranged between the two groups of fixing plates (5).

6. The graphene high temperature radiator facilitating increased temperature stability of claim 5, wherein: the heating assembly comprises a graphene heating layer (9) fixedly mounted on the inner side of the heat-emitting panel (1), one side of the graphene heating layer (9) is connected with a heat insulation layer (8), one side of the heat insulation layer (8) is provided with a heat insulation structure (7), and the outer side of the heat insulation structure (7) is provided with a fixing assembly.

7. The graphene high temperature radiator facilitating increased temperature stability of claim 6, wherein: the fixing assembly comprises limiting holes (11) formed in two ends of the outer side of the fixing plate (5), mounting rods (12) are arranged in the limiting holes (11) in a matched mode, and the surfaces of the mounting rods (12) are in sliding connection with the inner walls of the limiting holes (11).

8. The graphene high temperature radiator facilitating increased temperature stability of claim 7, wherein: the fixing assembly further comprises an installation shell (6) arranged on the outer side of the heat insulation structure (7), installation holes (10) are formed in two ends of two sides of the installation shell (6), the installation holes (10) are arranged in a matched mode with the installation rods (12), and the bottoms of the installation rods (12) are in threaded connection with the inner walls of the installation holes (10).