CN219511492U - Tail gate size detection mechanism - Google Patents

Abstract

The utility model provides a tail gate size detection mechanism, which comprises: the detection platform is provided with a product to be detected, a plurality of detection probes are arranged on the detection platform, the detection probes are arranged along the edge of the detection platform, each detection probe comprises a detection head, a forward pushing cylinder, a connecting block and a zero setting component, the forward pushing cylinder penetrates through the connecting block to be connected with the detection head, and the zero setting component is rotationally connected with the connecting block and is in contact with the detection head. The zeroing component is connected with the connecting block in a connecting mode of rotating connection and then is contacted with the detecting head, so that zeroing is carried out on the detecting head. Through increasing the number of detection probes, the accuracy of data is improved, the abnormal NG condition of the workpiece caused by inaccurate detection is reduced, and in addition, the forward pushing cylinder is adopted to enable the taking and placing of the product workpiece to be smooth, so that time is saved. Furthermore, the detection head is zeroed in a rotating mode, so that the detection head can be unscrewed for zeroing according to the situation and screwed in for hiding, and further the repeated installation procedure of the zeroing block is avoided.

Description

Tail gate size detection mechanism

Technical Field

The utility model relates to the field of tail gate manufacturing, in particular to a tail gate gear detection mechanism.

Background

In the existing method, the number of the size detection of the tail gate is small, and the detection accuracy is not accurate enough, so that a plurality of workpiece detection errors are caused to be abnormal NG. In addition, a mode that one air cylinder pulls a plurality of measuring heads to push forward is adopted, so that the problem of clamping pieces can occur.

Therefore, in order to avoid the failure of the gauge head or the failure of the gauge head caused by the increase of the service time, a zeroing workpiece is mounted on the gauge head. The prior zeroing workpiece is shown in fig. 1: the measuring head 1 is externally connected with the mounting base 2, then a mounting hole is formed in the mounting base 2 at a position near the measuring head 1, the adjusting block 3 is arranged through the mounting hole, zero setting is carried out by utilizing the adjusting block 3, the adjusting block of the zero setting structure is mounted when zero setting is needed, unloading is carried out after zero setting is finished, and otherwise detection is influenced. Therefore, the zeroing structure is relatively complex in structure and is troublesome to install.

Disclosure of Invention

The technical problems to be solved by the utility model are as follows: aiming at the technical defects of the existing detection probes and the zeroing structure of the detection probes, the tail gate size detection mechanism is provided.

In order to solve the above technical problems, the present utility model provides a tail gate size detection mechanism, which includes: the detection platform is provided with a product to be detected, a plurality of detection probes are arranged on the detection platform, the detection probes are arranged along the edge of the detection platform, each detection probe comprises a detection head, a forward pushing cylinder, a connecting block and a zero setting component, the forward pushing cylinder penetrates through the connecting block to be connected with the detection head, and the zero setting component is rotationally connected with the connecting block and is in contact with the detection head.

The tail gate size detection mechanism provided by the utility model can also have the following characteristics: the zero setting assembly comprises a telescopic rod, a telescopic spring and an adjusting block, wherein the adjusting block is arranged at one end of the telescopic rod, and the telescopic spring is sleeved outside the telescopic rod.

The tail gate size detection mechanism provided by the utility model can also have the following characteristics: one end of the telescopic rod penetrates through the connecting block.

The tail gate size detection mechanism provided by the utility model can also have the following characteristics: the regulating block is arranged at one end of the telescopic rod penetrating through the connecting block.

The tail gate size detection mechanism provided by the utility model can also have the following characteristics: the adjusting block is driven by the telescopic rod to rotate.

The tail gate size detection mechanism provided by the utility model can also have the following characteristics: the protruding block is arranged below the connecting block, and the adjusting block is clamped with the protruding block after rotating and is contacted with the detecting head.

The tail gate size detection mechanism provided by the utility model can also have the following characteristics: the bottom of regulating block is provided with the extension piece of outwards extending, has the clearance between extension piece and the projection piece, and extension piece and the contact of detecting head.

The tail gate size detection mechanism provided by the utility model can also have the following characteristics: the upper part of the detection head is connected with a displacement sensor.

The tail gate size detection mechanism provided by the utility model can also have the following characteristics: the number of the detection probes is more than or equal to 50.

The utility model has the beneficial effects that:

the tail gate size detection mechanism comprises a detection table and a plurality of detection probes. The detection probe comprises a detection head, a forward pushing cylinder, a connecting block and a zeroing assembly. The push-forward cylinder passes the connecting block and is connected with the detection head, and the zero subassembly rotates with the connecting block to be connected, and with detect the head contact, based on this tail-gate size detection mechanism, the zero subassembly is connected with the connecting block through the connected mode of rotating the connection, then with detect the head contact, and then carry out zero setting to the detection head. Through increasing the number of detection probes, the accuracy of data is improved, the abnormal NG condition of the workpiece caused by inaccurate detection is reduced, and in addition, the forward pushing cylinder is adopted to enable the taking and placing of the product workpiece to be smooth, so that time is saved. Furthermore, the detection head is zeroed in a rotating mode, so that the detection head can be unscrewed for zeroing according to the situation and screwed in for hiding, and further the repeated installation procedure of the zeroing block is avoided.

In addition, the zeroing subassembly includes telescopic link, expansion spring and regulating block, and the connecting block is passed to the one end of telescopic link, and the regulating block sets up on the one end that the telescopic link passed the connecting block, and when the telescopic link rotated down, the regulating block also rotated along with it, and then can contact the detecting head and zeroe.

In addition, the below of connecting block is provided with the bulge, and the bottom of regulating block is provided with the extension piece, has the clearance between extension piece and the bulge, and this clearance can block the detection head, and then makes to extend soon and detect the head contact.

Drawings

FIG. 1 is a schematic diagram of a prior art size detection device;

fig. 2 is a schematic structural view of a tail gate size detecting mechanism in the present embodiment;

fig. 3 is a schematic structural view of the inspection probe in the present embodiment.

Detailed Description

In order to make the technical problems, technical schemes and beneficial effects solved by the utility model more clear, the utility model is further described in detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the scope of the utility model.

In this embodiment, the tail gate size detection mechanism is applied to size detection of a tail gate product.

As shown in fig. 2 and 3, the tail gate size detection mechanism includes a detection table 100 and a plurality of detection probes 10.

The inspection station 100 has placed thereon a product tail gate workpiece to be inspected.

A plurality of inspection probes are disposed along the edge of the inspection station 100 for inspecting the dimensions of a workpiece of a size. In this embodiment, the number of the detection probes is not less than 50, the detection probes are set as many as possible, more data sizes are adopted, and the accuracy of the data is ensured as much as possible.

Each of the inspection probes 10 includes an inspection head 11, a push-forward cylinder 12, a connection block 13, and a zeroing assembly. The zeroing assembly comprises a telescopic rod 14, a telescopic spring 15 and an adjusting block 16.

The connecting block 13 is a base for connecting the above components, and the bottom is provided with a protruding block 17. The connecting block 13 is provided with two mounting positions with a certain interval therebetween.

One end of the push-forward cylinder 12 passes through one of the mounting positions of the connection block 13 to be connected with the detection head 11. A displacement sensor 19 is provided above the same side as the push-forward cylinder 12.

The telescopic rod 14 is rotatably connected with the connecting block 13 through another mounting position. The telescopic spring 15 is sleeved outside the telescopic rod 14, and the adjusting block 16 is arranged at one end of the telescopic rod 14 penetrating through the installation position.

The adjusting block 16 and the detecting head 11 are positioned on one side of the connecting block 13, and the upper end of the telescopic rod 14 and the front pushing cylinder 12 are positioned on the same side.

The bottom side of the adjustment block 16 is provided with an outwardly extending extension block 18.

When the telescopic rod 14 rotates, the telescopic rod 14 rotates downwards to drive the adjusting block 16 to rotate, and when the telescopic rod rotates to a certain angle, the upper part of the adjusting block 16 abuts against the protruding block 17. At this time, a gap is formed between the extension block 18 at the bottom of the adjusting block 16 and the protruding block 17, the gap is the length of the detecting head 11, the extension block 18 just engages with the detecting head 11 and contacts with the detecting head 11, and then the zeroing of the detecting head 11 is realized.

The tail gate size detection mechanism in the embodiment comprises a detection table and a plurality of detection probes. The detection probe comprises a detection head, a forward pushing cylinder, a connecting block and a zeroing assembly. The push-forward cylinder passes the connecting block and is connected with the detection head, and the zero subassembly rotates with the connecting block to be connected, and with detect the head contact, based on this tail-gate size detection mechanism, the zero subassembly is connected with the connecting block through the connected mode of rotating the connection, then with detect the head contact, and then carry out zero setting to the detection head. Through increasing the number of detection probes, the accuracy of data is improved, the abnormal NG condition of the workpiece caused by inaccurate detection is reduced, and in addition, the forward pushing cylinder is adopted to enable the taking and placing of the product workpiece to be smooth, so that time is saved. Furthermore, the detection head is zeroed in a rotating mode, so that the detection head can be unscrewed for zeroing according to the situation and screwed in for hiding, and further the repeated installation procedure of the zeroing block is avoided.

In addition, the zeroing subassembly includes telescopic link, expansion spring and regulating block, and the connecting block is passed to the one end of telescopic link, and the regulating block sets up on the one end that the telescopic link passed the connecting block, and when the telescopic link rotated down, the regulating block also rotated along with it, and then can contact the detecting head and zeroe.

In addition, the below of connecting block is provided with the bulge, and the bottom of regulating block is provided with the extension piece, has the clearance between extension piece and the bulge, and this clearance can block the detection head, and then makes to extend soon and detect the head contact.

It will be apparent to those skilled in the art that various modifications and variations can be made to the present utility model without departing from the spirit or scope of the utility model. Thus, it is intended that the present utility model also include such modifications and alterations insofar as they come within the scope of the appended claims or the equivalents thereof.

Claims (9)

1. A tail gate size detection mechanism, comprising:

a detection table on which a product to be detected is placed,

a plurality of detection probes, a plurality of detection probes are arranged along the edge of the detection table,

wherein the detection probe comprises a detection head, a forward pushing cylinder, a connecting block and a zeroing component,

the forward pushing cylinder penetrates through the connecting block to be connected with the detection head,

the zeroing component is rotationally connected with the connecting block and is contacted with the detection head.

2. The tail gate size detection mechanism of claim 1, wherein:

the zero setting component comprises a telescopic rod, a telescopic spring and an adjusting block,

the adjusting block is arranged at one end of the telescopic rod,

the telescopic spring is sleeved outside the telescopic rod.

3. The tail gate size detection mechanism of claim 2, wherein:

one end of the telescopic rod penetrates through the connecting block.

4. A tail gate size detection mechanism as claimed in claim 3, wherein:

the adjusting block is arranged at one end of the telescopic rod penetrating through the connecting block.

5. A tail gate size detection mechanism as claimed in claim 3, wherein:

the adjusting block is driven by the telescopic rod to rotate.

6. The tail gate size detection mechanism as set forth in claim 5, wherein:

a protruding block is arranged below the connecting block,

the adjusting block is clamped with the protruding block after rotating and is contacted with the detecting head.

7. The tail gate size detection mechanism as set forth in claim 6, wherein:

the bottom of the adjusting block is provided with an extending block which extends outwards,

a gap is formed between the extending block and the protruding block, and the extending block is in contact with the detecting head.

8. The tail gate size detection mechanism of claim 1, wherein:

and a displacement sensor is connected above the detection head.

9. The tail gate size detection mechanism of claim 1, wherein:

the number of the detection probes is more than or equal to 50.