CN220871610U

CN220871610U - Non-standard radiator bottom heat source contact through-stop gauge

Info

Publication number: CN220871610U
Application number: CN202322499600.4U
Authority: CN
Inventors: 马靖; 范群浩
Original assignee: Dongguan Enel Metal Technology Co ltd
Current assignee: Dongguan Enel Metal Technology Co ltd
Priority date: 2023-09-14
Filing date: 2023-09-14
Publication date: 2024-04-30
Anticipated expiration: 2033-09-14

Abstract

The utility model discloses a non-standard radiator bottom heat source contact through check tool, which comprises a radiator, wherein the radiator consists of a main structure and a plurality of connecting structures, the bottom surface of the main structure and the connecting structures are provided with height differences, and a groove structure is arranged at the position of the main structure corresponding to the connecting structures; the middle part of the gauge base is provided with a positioning groove; the detection module comprises two detection tracks, a group of through check blocks are slidably mounted on each detection track, and the positions of the through check blocks correspond to the positions of the connecting structures in the radiator. According to the utility model, two detection tracks and the through check blocks are arranged for the nonstandard radiator, each group of through check blocks is adaptively adjusted according to different structures on two sides of the radiator, so that the structure of each through check block is matched with the structure of the soldering parts on two sides of the radiator, and the through gauge and the no-go gauge can be replaced according to different model requirements, so that more nonstandard products are detected in an adaptive manner, and the functionality of the final product is efficiently ensured.

Description

Non-standard radiator bottom heat source contact through-stop gauge

Technical Field

The utility model relates to the technical field of detection tools, in particular to a non-standard heat source bottom contact through-stop detection tool.

Background

The radiator is used as an important part for heat dissipation of equipment, various structures matched with the radiator are needed according to the difference of the internal space of the equipment and the distribution position of key heating components, and as a nonstandard product, the radiator is difficult to carry out standardized production through production equipment commonly used in the market, and on the other hand, the produced finished product is difficult to carry out standardized detection, so that the heat dissipation effect of the radiator in actual use is difficult to ensure.

Especially when a radiator needs to be contacted with two heating components simultaneously to dissipate heat, the contact part needs to be adjusted in a targeted way due to different structures and positions, and the adaptive structure is generally fixed on a radiator main body in a soldering way, so that the requirements of a use scene are adapted.

In summary, in the production process of nonstandard heat sink products, soldering connection can be usually performed manually, or existing equipment on the market is improved so as to adapt to the production of the products, but the stability of final products is difficult to ensure by both methods, especially manual soldering, the accuracy of the removed welding position is difficult to ensure, and the heat sink parts are possibly bent due to improper operation, so that the finished products are required to be detected in a targeted manner so as to ensure that the specifications of the finished products meet the requirements, and therefore, a detection device capable of detecting different structures on two sides of the heat sink is required to be used as efficient as possible and simple to operate.

Disclosure of utility model

The utility model aims to provide a non-standard heat source bottom contact through check tool for solving the problems in the background technology.

In order to achieve the above purpose, the present utility model provides the following technical solutions:

a nonstandard heat sink bottom heat source contact check tool comprising:

The radiator is used as a detected main body and consists of a main structure and a plurality of connecting structures, wherein assembling positions are arranged on two sides of the main structure, the connecting structures are arranged in the assembling positions, a height difference is arranged between the bottom surface of the main structure and the connecting structures, and a groove structure is further arranged at the position of the main structure corresponding to the connecting structures, so that the radiator meets the assembling requirement and achieves the preset radiating effect;

The heat radiator is characterized by comprising a checking fixture base which is used as an assembly core and used for positioning and fixing the heat radiator, wherein a positioning groove is formed in the middle of the checking fixture base, a fixing device is arranged at one end of the positioning groove, and the fixing device is matched with the positioning groove;

The detection module is used for detecting the size of the radiator and comprises two detection tracks, the detection tracks are respectively arranged on two sides of the positioning groove of the detection tool base, a group of through check blocks are slidably arranged on each detection track, the positions of the through check blocks correspond to the positions of the connecting structures in the radiator, each group of through check blocks comprises a through gauge and a non-stop gauge, the horizontal height of the through gauge is lower than that of the non-stop gauge, the height difference between the through gauge and the non-stop gauge is the standard height size range of the connecting structures in the radiator, and the through check blocks on two sides are different in shape and are matched with the connecting structures with different groove structures on two sides.

In the utility model, three connecting structures, namely a first connecting structure, a second connecting structure and a third connecting structure, are arranged in the radiator, the first connecting structure is independently arranged on one side of the main structure, the groove structure is arranged at the bottom of the first connecting structure and protrudes downwards compared with the bottom surface of the main structure, the second connecting structure and the third connecting structure are jointly arranged on the other side of the main structure, and the second connecting structure and the third connecting structure have the same horizontal height and are higher than the bottom surface of the main structure.

Further, the detection track is divided into a first detection track and a second detection track, the go gauge and the no-go gauge which are slidably mounted on the first detection track are a first go gauge and a first no-go gauge, the first go gauge and the first no-go gauge correspond to the first connecting structure, a bump structure is arranged on the inner side of the first go gauge and corresponds to the groove structure, the go gauge and the no-go gauge which are slidably mounted on the second detection track are a second go gauge and a second no-go gauge, and the second go gauge and the second no-go gauge correspond to the second connecting structure and the third connecting structure.

Further, the level of the first go gauge measuring point is 2.05+0.05/-0mm lower than the level of the bottom surface of the positioning groove, the level of the first go gauge measuring point is 1.75+0/-0.05mm lower than the level of the bottom surface of the positioning groove, the level of the second go gauge measuring point is 1.58+0/-0.05mm higher than the level of the bottom surface of the positioning groove, and the level of the second go gauge measuring point is 1.98+0.05/-0mm higher than the level of the bottom surface of the positioning groove.

In the utility model, one end of the detection track is contacted with the gauge base, and the other end of the detection track is provided with a limit column, so that the go gauge and the no-go gauge sliding on the detection track are limited by the gauge base and the limit column.

In the utility model, the bottom surface of the positioning groove is square, and is matched with the main structure, and the width is 120.5+/-0.05 mm.

In the utility model, the fixing device comprises a pressing block, a connecting piece and a handle, wherein the pressing block is matched with the positioning groove and is controlled by the handle and the connecting piece, so that the radiator is fixed in the positioning groove.

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

according to the utility model, two detection tracks and the through check blocks are arranged for the nonstandard radiator, each group of through check blocks is adaptively adjusted according to different structures on two sides of the radiator, so that the structure of each through check block is matched with the structure of soldering parts on two sides of the radiator, through gauges and no-go gauges in the same group of through check blocks are arranged to be different in height, when the through gauges pass through the non-stop gauges, the specification of a product is clear, the through gauges and the no-go gauges can be replaced according to different model requirements, further detection of more nonstandard products is adapted, and the functionality of the final product is efficiently ensured.

Drawings

FIG. 1 is a diagram showing the overall structure of a gauge base and a detection module according to the present utility model;

FIG. 2 is an exploded view of the test fixture base and the test module of the present utility model;

FIG. 3 is an exploded view of another angle between the base of the gauge and the detection module according to the present utility model;

FIG. 4 is an overall construction diagram of a radiator according to the present utility model;

FIG. 5 is a side view of a heat sink according to the present utility model;

FIG. 6 is an exploded view of a heat sink according to the present utility model;

FIG. 7 is an exploded view of another embodiment of a heat sink according to the present utility model;

fig. 8 is a state diagram of the use of the present utility model.

In the figure: 100. a heat sink; 101. a main structure; 1011. assembling the position; 102. a first connection structure; 103. a second connection structure; 104. a third connection structure; 105. a groove structure; 200. a gauge base; 201. a positioning groove; 202. a fixing device; 2021. briquetting; 2022. a connecting piece; 2023. a handle; 300. a detection module; 301. detecting a track; 3011. a first detection track; 3012. a second detection track; 3021. a first go gauge; 3022. a first stop gauge; 3023. a bump structure; 3031. a second go gauge; 3032. a second stop gauge; 304. and a limit column.

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. 1-8, an embodiment of the present utility model is provided:

a nonstandard heat sink bottom heat source contact check tool comprising:

The radiator 100 is used as a detected main body, the radiator 100 is composed of a main structure 101 and a plurality of connecting structures, the two sides of the main structure 100 are provided with assembling positions 1011, the connecting structures are arranged in the assembling positions 1011, the bottom surface of the main structure 100 and the connecting structures have a height difference, and the positions of the main structure 100 corresponding to the connecting structures are also provided with groove structures 105, so that the radiator 100 meets the assembling requirements and achieves the preset radiating effect;

The checking fixture base 200 is used as an assembly core and is used for positioning and fixing the radiator 100, a positioning groove 201 is formed in the middle of the checking fixture base 200, a fixing device 202 is arranged at one end of the positioning groove 201, and the fixing device 202 is matched with the positioning groove 201;

The detection module 300 is configured to detect a size of the heat sink 100, the detection module 300 includes two detection tracks 301, the detection tracks 301 are respectively disposed on two sides of the positioning groove 201 of the detection tool base 200, a group of through check blocks are slidably mounted on each detection track 301, the positions of the through check blocks correspond to the positions of the connection structures in the heat sink 100, each group of through check blocks includes a through gauge and a no-go gauge, the level of the through gauge is lower than that of the no-go gauge, the height difference between the through gauge and the no-go gauge is a standard height dimension range of the connection structures in the heat sink 100, and the through check blocks on two sides have different shapes, so that the through check blocks are matched with the connection structures with different groove structures 105 on two sides.

In this embodiment, three connection structures, namely, a first connection structure 102, a second connection structure 103 and a third connection structure 104 are disposed in the heat sink 100, the first connection structure 102 is independently disposed on one side of the main structure 101, a groove structure 105 is disposed at the bottom of the first connection structure 102, the groove structure 105 protrudes downward from the bottom surface of the main structure 101, the second connection structure 103 and the third connection structure 104 are disposed on the other side of the main structure 101, and the second connection structure 103 and the third connection structure 104 have the same horizontal height and are higher than the bottom surface of the main structure 101.

Further, the detection track 301 is divided into a first detection track 3011 and a second detection track 3012, the go gauge and the no-go gauge slidably mounted on the first detection track 3011 are a first go gauge 3021 and a first no-go gauge 3022, the first go gauge 3021 and the first no-go gauge 3022 correspond to the first connection structure 102, a bump structure 3023 is arranged inside the first go gauge 3021 and the first no-go gauge 3022, the bump structure 3023 corresponds to the groove structure 105, the go gauge and the no-go gauge slidably mounted on the second detection track 2012 are a second go gauge 3031 and a second no-go gauge 3032, and the second go gauge 3031 and the second no-go gauge 3032 correspond to the second connection structure 103 and the third connection structure 104.

Further, the level of the measuring point of the first gauge 3021 is 2.05mm lower than the level of the bottom surface of the positioning groove 201, the level of the measuring point of the first gauge 3022 is 1.75mm lower than the level of the measuring point of the positioning groove bottom 201, the level of the measuring point of the second gauge 3031 is 1.58mm higher than the level of the bottom surface of the positioning groove 201, and the level of the measuring point of the second gauge 3032 is 1.98mm higher than the level of the bottom surface of the positioning groove 201.

In this embodiment, one end of the detection track 301 contacts with the detection tool base 200, and the other end is provided with a limit post 304, so that the go gauge and the no-go gauge sliding on the detection track 301 are limited by the detection tool base 200 and the limit post 304.

In this embodiment, the bottom surface of the positioning groove 201 is square, and is matched with the main structure 101, and has a width of 120.5mm.

In this embodiment, the fixing device 202 includes a pressing block 2021, a connecting member 2022, and a handle 2023, where the pressing block 2021 is matched with the positioning slot 201, and is controlled by the handle 2023 and the connecting member 2022, so as to fix the radiator 100 in the positioning slot 201.

Working principle:

in the production line, a worker or equipment welds the connecting structure and the groove structure 105 in the assembly position 1011 of the main structure 101 in a soldering manner, after the assembly action is completed, the tester places the assembled radiator 100 in the positioning groove 201 of the gauge base 200, drives the pressing block 2021 to press down by matching the handle 2023 with the connecting piece 2022, fixes the radiator 100 in the positioning groove 201, and completes the detection preparation action;

Then, detection can be started, during detection, a detector firstly dials the first go gauge 3021 to enable the first go gauge 3021 to slide on the first detection track 3011 and move from the position of the limit post 304 to the other end, if the first go gauge 3021 passes smoothly, then dials the first no-go gauge 3022, if the first no-go gauge 3022 is blocked by the radiator 100 and cannot pass, then dials the second go gauge 3031, the second go gauge 3031 passes smoothly, dials the second no-go gauge 3032, the second no-go gauge 3032 is blocked, the test is completed, the above actions are completed smoothly, the size compliance of the radiator 100 is indicated, if any one of the actions is inconsistent, the size compliance of the radiator 100 is indicated, and the detection action is completed;

After the detection is completed, the detection personnel returns the go gauge and the no-go gauge, and drives the pressing block 2021 to leave the radiator 100 through the handle 2023 matched with the connecting piece 2022, and takes out the radiator, if the specification of the radiator 100 changes, the go gauge and the no-go gauge need to be replaced in an adaptive manner, so that the detection action is ensured to be performed accurately.

It will be evident to those skilled in the art that the utility model is not limited to the details of the foregoing illustrative embodiments, and that the present utility model may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. The present embodiments are, therefore, to be considered in all respects as illustrative and not restrictive, the scope of the utility model being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Claims

1. The utility model provides a nonstandard radiator bottom heat source contact check utensil which characterized in that includes:

2. The non-standard radiator bottom heat source contact check tool according to claim 1, wherein three connecting structures are arranged in the radiator, namely a first connecting structure, a second connecting structure and a third connecting structure, the first connecting structure is independently arranged on one side of the main structure, the bottom of the first connecting structure is provided with the groove structure, the groove structure protrudes downwards compared with the bottom surface of the main structure, the second connecting structure and the third connecting structure are jointly arranged on the other side of the main structure, and the second connecting structure and the third connecting structure are the same in horizontal height and higher than the bottom surface of the main structure.

3. The non-standard radiator bottom heat source contact through and stop gauge according to claim 2, wherein the detection track is divided into a first detection track and a second detection track, the through gauge and the stop gauge slidably mounted on the first detection track are a first through gauge and a first stop gauge, the first through gauge and the first stop gauge correspond to each other with the first connecting structure, a bump structure is arranged on the inner side of the first through gauge and the first stop gauge, the bump structure corresponds to the groove structure, the through gauge and the stop gauge slidably mounted on the second detection track are a second through gauge and a second stop gauge, and the second through gauge and the second stop gauge correspond to the second connecting structure and the third connecting structure.

4. A non-standard radiator bottom heat source contact check tool according to claim 3, wherein the first gauge measuring point has a level 2.05+0.05/-0mm lower than the level of the locating groove bottom surface, the first gauge measuring point has a level 1.75+0/-0.05mm lower than the level of the locating groove bottom surface, the second gauge measuring point has a level 1.58+0/-0.05mm higher than the level of the locating groove bottom surface, and the second gauge measuring point has a level 1.98+0.05/-0.05 mm higher than the level of the locating groove bottom surface.

5. The non-standard radiator bottom heat source contact go-no-go gauge according to claim 1, wherein one end of the detection track is in contact with the gauge base, and a limit post is arranged at the other end of the detection track, so that the go gauge and the no-go gauge sliding on the detection track are limited by the gauge base and the limit post.

6. The non-standard radiator bottom heat source contact check tool according to claim 1, wherein the bottom surface of the positioning groove is square, and the width of the positioning groove is 120.5+/-0.05 mm, which is matched with the main structure.

7. The non-standard heat sink bottom heat source contact check tool according to claim 1, wherein the fixing device comprises a pressing block, a connecting piece and a handle, wherein the pressing block is matched with the positioning groove and is controlled by the handle and the connecting piece, so that the heat sink is fixed in the positioning groove.

8. The non-standard radiator bottom heat source contact check tool according to claim 1, wherein the connecting structure and the groove structure are fixedly mounted on the main structure by welding.