CN221037180U - Split type gauge for 3D bending extrusion molding copper aluminum bar - Google Patents

Abstract

The utility model relates to a split type detection tool for a 3D bending extrusion molding copper aluminum bar, which comprises a detection body, wherein a first installation position detection block is arranged at the head part of the detection body corresponding to a workpiece, a second installation position detection block is arranged at the tail part of the corresponding workpiece, a bending position detection block is arranged at the bending position of the corresponding workpiece, the detection body is split type, a first section detection body, a middle section detection body and a last section detection body are sequentially arranged along a bending path of the workpiece, and at least 3 reference blocks are arranged on each section detection body. The utility model can effectively detect the bending precision, the mounting hole precision and the mounting surface flatness of the workpiece, and at least 3 reference blocks are arranged on each section of the split inspection body, so that the inspection body can be conveniently and rapidly positioned, and then a reference coordinate system is established, thereby realizing the detection rapidly and stably.

Description

Split type gauge for 3D bending extrusion molding copper aluminum bar

Technical Field

The utility model relates to the technical field of three-dimensional inspection tools, in particular to a split type inspection tool for a 3D bending extrusion molding copper-aluminum bar, which is used for detecting the shape, position and size of the extrusion molding copper-aluminum bar of a quick-charging connector.

Background

At present, the bending parts of the copper aluminum bars of the quick-charging connector are all space bending, and the three-coordinate system is difficult to establish, so that the three-coordinate system cannot be used for size detection. Most products are manufactured by detecting the mounting hole part only, and the folded part cannot be completely used for accurate qualitative judgment.

Disclosure of Invention

The utility model aims to overcome the defects, and provides a split type gauge for a 3D bending extruded copper aluminum bar, which realizes the dimensional detection of a space bending product, intuitively feeds back the deviation of the product, and is convenient to produce and adjust to ensure the consistency of the product.

The purpose of the utility model is realized in the following way:

The utility model provides a split type utensil of examining of extrusion molding copper aluminum bar of bending of 3D, is including examining specifically, examine specifically to be equipped with first installation position detection piece corresponding to the head of work piece, the afterbody that corresponds the work piece is equipped with the second installation position detection piece, and the department of bending that corresponds the work piece is equipped with the position detection piece of bending, examine specifically to adopt split type, be equipped with first section in proper order along the crooked route of work piece and examine specifically, the middle section examine specifically and last section examine specifically, every section examine specifically on be equipped with 3 reference blocks at least.

Preferably, overlapping lap joints are arranged between the first section detecting body and the middle section detecting body, between the middle section detecting body and the last section detecting body, the overlapping lap joints are used for connecting adjacent sections of detecting bodies, positioning pins and connecting bolts are arranged on the overlapping lap joints, the sections of detecting bodies are firstly processed separately, then are assembled through the positioning pins, and finally are connected and fixed into a whole through the connecting bolts.

Preferably, along the curved path of the workpiece, the first section is specifically provided with a first installation position detection block, a first bending position detection block, a second bending position detection block, a third bending position detection block, a fourth bending position detection block, a fifth bending position detection block and a sixth bending position detection block in sequence, the middle section is specifically provided with a seventh bending position detection block and an eighth bending position detection block in sequence, and the tail section is specifically provided with a ninth bending position detection block, a tenth bending position detection block, an eleventh bending position detection block, a twelfth bending position detection block, a thirteenth bending position detection block and a second installation position detection block in sequence.

Preferably, the first bending position detecting block, the third bending position detecting block, the fifth bending position detecting block, the sixth bending position detecting block, the seventh bending position detecting block, the eighth bending position detecting block, the ninth bending position detecting block, the eleventh bending position detecting block, the twelfth bending position detecting block and the thirteenth bending position detecting block are horizontal bending detecting blocks, and bending clamping grooves are formed on the horizontal bending detecting blocks corresponding to the workpieces;

The second bending position detection block, the fourth bending position detection block and the tenth bending position detection block are space bending detection blocks, and the space bending detection blocks are provided with attaching inclined planes corresponding to the workpieces.

Preferably, 3 reference blocks on the same section of the sample body form a right-angle triangle structure.

Preferably, one right-angle side of the right-angle triangular structure is consistent with the horizontal transverse direction, and the other right-angle side of the right-angle triangular structure is consistent with the horizontal longitudinal direction.

Preferably, the first installation position detection block and the second installation position detection block position, clamp and fix the head part and the tail part of the workpiece, and the detection pin is arranged on the detection body.

Preferably, the detection pin is fixed on the detection body through a spring rope, and the detection pin is arranged on two types, one is a hole position detection pin, and the other is a plane detection pin.

Preferably, the bottom of the detecting body is provided with foot pads which are distributed at the corners of each detecting body and avoid overlapping parts.

The beneficial effects of the utility model are as follows:

detecting the bending precision of the workpiece by arranging a bending position detection block;

The gauge body adopts a split structure, and is firstly and separately processed and assembled through the locating pin, so that the requirement of gauge processing equipment is reduced, and meanwhile, the cost of gauge maintenance and replacement is reduced;

At least 3 reference blocks are arranged on each section of the split detection body, so that the detection body can be conveniently and rapidly located, then a reference coordinate system is established, and the detection is rapidly and stably realized.

By arranging the detection pin, the aperture, the hole site and the flatness of the installation plane of the workpiece are detected.

Drawings

Fig. 1 is a schematic structural view of the present utility model.

Fig. 2 is a rear view of fig. 1.

Fig. 3 is a partial enlarged view of fig. 1.

Fig. 4 is a top view of the present utility model.

Fig. 5 is a schematic view of the mounting structure of the present utility model.

Wherein: the first section is checked to be specific 1; a middle section detecting body 2; a final segment detecting body 3; a positioning pin 4; a connecting bolt 5; a first mounting position detection block 6; a second mounting position detection block 7; a first bending position detection block 8; a second bending position detection block 9; a third bending position detection block 10; a fourth bending position detection block 11; a fifth bending position detection block 12; a sixth bending position detection block 13; a seventh bending position detection block 14; an eighth bending position detection block 15; a ninth bending position detection block 16; a tenth bending position detection block 17; an eleventh bending bit detection block 18; a twelfth bending position detection block 19; thirteenth bending position detection block 20; a reference block 21; a hole position detecting pin 22; a plane detection pin 23; foot pad 24.

Description of the embodiments

Referring to fig. 1-5, the utility model relates to a split type detection tool for a 3D bending extrusion molding copper aluminum bar, which comprises a detection body, wherein the detection body is split, a first section detection body 1, a middle section detection body 2 and a last section detection body 3 are sequentially arranged along a bending path of a workpiece, overlapping lap joints are respectively arranged between the first section detection body 1 and the middle section detection body 2 and between the middle section detection body 2 and the last section detection body 3, the overlapping lap joints are used for connecting adjacent section detection bodies, positioning pins 4 and connecting bolts 5 are arranged at the overlapping lap joints, the section detection bodies are firstly processed separately, then are assembled through the positioning pins 4, and finally are connected and fixed into a whole through the connecting bolts 5.

The head of the corresponding workpiece of the detecting body is provided with a first installation position detecting block 6, the tail of the corresponding workpiece is provided with a second installation position detecting block 7, and the bending position of the corresponding workpiece is provided with a bending position detecting block.

Along the bending path of the workpiece, a first installation position detection block 6, a first bending position detection block 8, a second bending position detection block 9, a third bending position detection block 10, a fourth bending position detection block 11, a fifth bending position detection block 12 and a sixth bending position detection block 13 are sequentially arranged on the first section detection body 1, a seventh bending position detection block 14 and an eighth bending position detection block 15 are sequentially arranged on the middle section detection body 2, a ninth bending position detection block 16, a tenth bending position detection block 17, an eleventh bending position detection block 18, a twelfth bending position detection block 19, a thirteenth bending position detection block 20 and a second installation position detection block 7 are sequentially arranged on the tail section detection body 3, and a horizontal bending position detection groove is formed in the first bending position detection block 8, the third bending position detection block 10, the fifth bending position detection block 12, the sixth bending position detection block 13, the seventh bending position detection block 14, the eighth bending position detection block 15, the ninth bending position detection block 16, the eleventh bending position detection block 18, the twelfth bending position detection block 19 and the thirteenth bending position detection block 20.

The second bending position detection block 9, the fourth bending position detection block 11 and the tenth bending position detection block 17 are space bending detection blocks, and the space bending detection blocks are provided with attaching inclined planes corresponding to the workpieces.

At least 3 reference blocks 21 are arranged on each section of the detection body, so that the detection body can be conveniently and rapidly located, then a reference coordinate system is established, and the detection can be rapidly and stably realized. The 3 reference blocks 21 on the same section of the sample body form a right-angle triangle structure. One right-angle side of the right-angle triangular structure is consistent with the horizontal transverse direction, and the other right-angle side of the right-angle triangular structure is consistent with the horizontal longitudinal direction.

The first installation position detection block 6 and the second installation position detection block 7 position, clamp and fix the head part and the tail part of the workpiece, and a detection pin is arranged on the detection body to detect the installation hole and the installation plane of the workpiece. The detection pin is fixed on the detection body through a spring rope. The detection pin is arranged in two types, one is a hole position detection pin 22, the other is a plane detection pin 23, jacks are arranged on the installation position detection blocks corresponding to the hole position detection pins 22, steps are arranged on the installation position detection blocks corresponding to the plane detection pins 23, when the end portions of the workpieces are placed in the installation position detection blocks, the bottom surfaces of the workpieces and the steps form slots of the plane detection pins, and the plane detection pins detect the installation end portions of the workpieces in a planeness mode, so that the planeness of installation planes of the workpieces is guaranteed.

The bottom of the test body is provided with foot pads 24, and the foot pads 24 are distributed at the corners of each section of the test body and avoid overlapping parts.

In addition to the above embodiments, the present utility model also includes other embodiments, and all technical solutions that are formed by equivalent transformation or equivalent substitution should fall within the protection scope of the claims of the present utility model.

Claims (9)

1. Split type utensil of examining of extrusion molding copper aluminum bar of bending of 3D, its characterized in that: the automatic detection device comprises a detection body, wherein the detection body corresponds to the head of a workpiece and is provided with a first installation position detection block, the tail of the corresponding workpiece is provided with a second installation position detection block, the bending part of the corresponding workpiece is provided with a bending position detection block, the detection body is split, a first section detection body, a middle section detection body and a last section detection body are sequentially arranged along a bending path of the workpiece, and each section detection body is at least provided with 3 reference blocks.

2. The split gauge for 3D bending extruded copper aluminum bars of claim 1, wherein: the automatic detection device is characterized in that overlapping lap joints are arranged between the first section detection body and the middle section detection body, between the middle section detection body and the last section detection body, the overlapping lap joints are used for connecting adjacent section detection bodies, positioning pins and connecting bolts are arranged on the overlapping lap joints, the section detection bodies are firstly processed separately, then are assembled through the positioning pins, and finally are connected and fixed into a whole through the connecting bolts.

3. The split gauge for 3D bending extruded copper aluminum bars of claim 1, wherein: the bending path along the workpiece is characterized in that a first installation position detection block, a first bending position detection block, a second bending position detection block, a third bending position detection block, a fourth bending position detection block, a fifth bending position detection block and a sixth bending position detection block are sequentially arranged on the first section detection body, a seventh bending position detection block and an eighth bending position detection block are sequentially arranged on the middle section detection body, and a ninth bending position detection block, a tenth bending position detection block, an eleventh bending position detection block, a twelfth bending position detection block, a thirteenth bending position detection block and a second installation position detection block are sequentially arranged on the tail section detection body.

4. The split gauge for 3D bending extruded copper aluminum bars of claim 3, wherein: the first bending position detection block, the third bending position detection block, the fifth bending position detection block, the sixth bending position detection block, the seventh bending position detection block, the eighth bending position detection block, the ninth bending position detection block, the eleventh bending position detection block, the twelfth bending position detection block and the thirteenth bending position detection block are horizontal bending detection blocks, and bending clamping grooves are formed in the horizontal bending detection blocks corresponding to the workpieces;

The second bending position detection block, the fourth bending position detection block and the tenth bending position detection block are space bending detection blocks, and the space bending detection blocks are provided with attaching inclined planes corresponding to the workpieces.

5. The split gauge for 3D bending extruded copper aluminum bars of claim 1, wherein: and 3 reference blocks on the same section of the sample body form a right-angle triangle structure.

6. The split gauge for the 3D bent extruded copper aluminum bar of claim 5, wherein: one right-angle side of the right-angle triangular structure is consistent with the horizontal transverse direction, and the other right-angle side of the right-angle triangular structure is consistent with the horizontal longitudinal direction.

7. The split gauge for 3D bending extruded copper aluminum bars of claim 1, wherein: the first installation position detection block and the second installation position detection block position, clamp and fix the head part and the tail part of the workpiece, and a detection pin is arranged on the detection body.

8. The split gauge for the 3D bent extruded copper aluminum bar of claim 7, wherein: the detection pin is fixed on the detection body through a spring rope, and the detection pin is arranged on two types, namely a hole position detection pin and a plane detection pin.

9. The split gauge for 3D bending extruded copper aluminum bars of claim 2, wherein: the bottom of the detecting body is provided with foot pads which are distributed at the corners of each detecting body and avoid overlapping parts.