CN216206115U - Tool rack for mounting instrument cross beam checking fixture - Google Patents

Abstract

The utility model relates to a tool rack for mounting an instrument cross beam detection tool, which is characterized in that when the tool rack for mounting the instrument cross beam detection tool is used, the instrument cross beam detection tool is connected between a head end ejector rod and a tail end ejector rod, and the instrument cross beam detection tool can be rotated to be supported on a middle upright post by rotating a connecting disc through a driving hand wheel, so that an operator can conveniently mount a mounting interface on one side, facing the operator, of the instrument cross beam detection tool; the instrument cross beam detection tool can also rotate through the driving hand wheel to enable the positioning pin on the connecting disc to be inserted into the positioning hole in the flange plate, so that the instrument cross beam detection tool can hover at a specific position, and an operator can conveniently install an installation interface on the instrument cross beam detection tool towards one side of the operator. Therefore, the orientation of the mounting interface on the instrument beam detection tool can be conveniently adjusted, and an operator can conveniently mount the mounting interface on the instrument beam detection tool.

Description

Tool rack for mounting instrument cross beam checking fixture

Technical Field

The utility model relates to a tool rack for mounting an instrument cross beam detection tool, in particular to a tool rack for mounting an automobile instrument cross beam detection tool.

Background

In the field of automobile manufacturing technology, it is necessary to inspect relevant parts of an automobile to detect the size, shape, etc. of the parts to determine whether the parts are acceptable. In order to detect the size and shape of relevant parts such as an automobile instrument panel, an instrument beam detector is designed for mounting the relevant parts such as the instrument panel, and the instrument beam detector is provided with an instrument panel relevant part mounting interface with the same size as that of a real automobile and used for mounting the instrument panel parts. Because the instrument panel parts are more and the shape directions are different, if a worker adjusts the posture of the worker to adapt to the installation direction of the related parts, the installation is very inconvenient, and time and labor are wasted.

SUMMERY OF THE UTILITY MODEL

In view of the above disadvantages of the prior art, the technical problem to be solved by the present invention is to provide a tool rack for mounting a cross beam gauge, which can facilitate the mounting operation of parts on the cross beam gauge.

In order to achieve the purpose, the utility model provides a tool rack for mounting an instrument beam detection tool, which comprises a bottom frame, wherein a head end stand column and a tail end stand column which are arranged oppositely are arranged on the bottom frame, a head end bearing and a tail end bearing which are coaxially arranged are respectively arranged on the head end stand column and the tail end stand column, a head end ejector rod for ejecting the head end of the instrument beam detection tool is arranged in the head end bearing, and a tail end ejector rod for ejecting the tail end of the instrument beam detection tool is arranged in the tail end bearing;

a flange plate is fixed on the head end upright post, and a positioning hole is formed in the flange plate; a connecting disc is coaxially fixed on the head end ejector rod and driven by a driving hand wheel, and a positioning pin is inserted in the connecting disc; the chassis is also provided with a middle upright post for supporting the instrument beam detection tool;

when the instrument cross beam gauge is connected between the head end ejector rod and the tail end ejector rod, the instrument cross beam gauge can be rotated to be supported on the middle upright post by rotating the driving hand wheel; or the hand wheel is driven to rotate so that the positioning pin on the connecting disc is inserted into the positioning hole on the flange plate, and the instrument cross beam detection tool is suspended at a specific position.

Preferably, the head end ejector rod is provided with a square head used for being inserted into a square hole in the head end of the instrument beam gauge.

Preferably, the instrument beam detection tool comprises a connecting rod and an accessory connected to the connecting rod, and the connecting rod is arranged coaxially with the head end ejector rod or the tail end ejector rod.

Preferably, the middle upright post is provided with a groove for supporting the connecting rod.

Preferably, the tail end ejector rod is provided with a cylindrical head used for being inserted into a round hole in the tail end of the instrument cross beam detection tool.

Preferably, the tail end ejector rod is connected in a spring barrel in a sliding mode, the spring barrel is supported in a tail end bearing, and the tail end ejector rod is pressed towards the instrument cross beam detection tool by a spring in the spring barrel.

More preferably, the tail end bearing comprises two bearing seats coaxially juxtaposed, the spring cartridge being connected in both bearing seats.

More preferably, the spring cylinder is provided with a long groove extending along the axial direction of the spring cylinder, the tail end ejector rod is connected with a positioning column, the positioning column is exposed out of the long groove, the side wall of the head end of the long groove is provided with a first positioning groove perpendicular to the length direction of the long groove, and the tail end of the long groove is provided with a second positioning groove perpendicular to the length direction of the long groove; the tail end ejector rod can move on the spring cylinder shaft to enable the positioning column to move into the first positioning groove or the second positioning groove.

Furthermore, a handle perpendicular to the positioning column is connected to the positioning column.

As mentioned above, the tool rack for mounting the instrument cross beam gauge has the following beneficial effects: when the tool rack for mounting the instrument beam detection tool is used, the instrument beam detection tool is connected between the head end ejector rod and the tail end ejector rod, the instrument beam detection tool can be rotated to be supported on the middle upright post by rotating the connecting disc through the driving hand wheel, so that an operator can conveniently mount a mounting interface on one side, facing the operator, of the instrument beam detection tool; the instrument cross beam detection tool can also rotate through the driving hand wheel to enable the positioning pin on the connecting disc to be inserted into the positioning hole in the flange plate, so that the instrument cross beam detection tool can hover at a specific position, and an operator can conveniently install an installation interface on the instrument cross beam detection tool towards one side of the operator. Therefore, the orientation of the mounting interface on the instrument beam detection tool can be conveniently adjusted, and an operator can conveniently mount the mounting interface on the instrument beam detection tool.

Drawings

FIG. 1 shows a schematic structural diagram of an instrument beam gauge mounted on a tool rack.

Fig. 2 shows a schematic structural diagram of the instrument beam gauge mounted on the tool rack from another angle.

FIG. 3 shows a schematic structural diagram of a tool rack for mounting a gauge cross beam gauge.

Fig. 4 is a schematic structural diagram of components such as the tail-end ejector rod, the spring barrel, the tail-end bearing, and the like.

Fig. 5 is a schematic structural diagram of a middle upright post capable of extending and contracting in the height direction, and a slide rail and a slide block on the upright post.

Description of the element reference numerals

1 underframe

2 head end column

3 tail end column

4 head end bearing

5 tail end bearing

6 instrument crossbeam examines utensil

7 head end ejector rod

8 tail end ejector rod

9 Flange plate

10 handle

11 connecting disc

12 drive hand wheel

13 positioning pin

14 middle upright post

15 connecting rod

16 grooves

17 spring cartridge

18 long groove

19 positioning column

20 first positioning groove

21 second positioning groove

22 slide rail

23 sliding block

24 column tube

25 support column

Detailed Description

The following description of the embodiments of the present invention is provided for illustrative purposes, and other advantages and effects of the present invention will become apparent to those skilled in the art from the present disclosure.

It should be understood that the structures, ratios, sizes, and the like shown in the drawings and described in the specification are only used for matching with the disclosure of the specification, so as to be understood and read by those skilled in the art, and are not used to limit the conditions under which the present invention can be implemented, so that the present invention has no technical significance, and any structural modification, ratio relationship change, or size adjustment should still fall within the scope of the present invention without affecting the efficacy and the achievable purpose of the present invention. In addition, the terms such as "upper", "lower", "left", "right" and "middle" used in the present specification are for clarity of description, and are not intended to limit the scope of the present invention, and changes or modifications of the relative relationship may be made without substantial technical changes.

As shown in fig. 1 to 3, the utility model provides a tool rack for mounting an instrument beam detection tool, which comprises a chassis 1, wherein a head end upright 2 and a tail end upright 3 are arranged on the chassis 1, the head end upright 2 and the tail end upright 3 are arranged oppositely, a head end bearing 4 and a tail end bearing 5 are respectively arranged on the head end upright 2 and the tail end upright 3, the head end bearing 4 is internally provided with a head end ejector rod 7 for ejecting the head end of the instrument beam detection tool 6, and the tail end bearing 5 is internally provided with a tail end ejector rod 8 for ejecting the tail end of the instrument beam detection tool 6;

a flange plate 9 is fixed on the head end upright post 2, and a positioning hole is formed in the flange plate 9; a connecting disc 11 is coaxially fixed on the head end ejector rod 7, the connecting disc 11 is driven by a driving hand wheel 12, and a positioning pin 13 is inserted on the connecting disc 11; the underframe 1 is also provided with a middle upright post 14 for supporting the instrument beam gauge 6;

when the instrument beam gauge 6 is connected between the head end ejector rod 7 and the tail end ejector rod 8, the instrument beam gauge 6 can be rotated to be supported on the middle upright post 14 by rotating the driving hand wheel 12; or the driving hand wheel 12 rotates to enable the positioning pin 13 on the connecting disc 11 to be inserted into the positioning hole on the flange plate, so that the instrument beam gauge 6 is suspended at a specific position.

When the tool rack for mounting the instrument cross beam detection tool is used, the instrument cross beam detection tool 6 is connected between the head end ejector rod 7 and the tail end ejector rod 8, the instrument cross beam detection tool 6 can be rotated to be supported on the middle upright post 14 by rotating the connecting disc 11 through the driving hand wheel 12, and therefore an operator can conveniently mount a mounting interface on one side, facing the operator, of the instrument cross beam detection tool 6; the instrument cross beam detection tool 6 can also be rotated through the driving hand wheel 12, so that the positioning pin 13 on the connecting disc 11 is inserted into the positioning hole in the flange plate, the instrument cross beam detection tool 6 is suspended at a specific position, and an installation interface facing one side of an operator on the instrument cross beam detection tool 6 is conveniently installed by the operator. Therefore, the orientation of the installation interface on the instrument beam detection tool 6 can be conveniently adjusted, and an operator can conveniently install the installation interface on the instrument beam detection tool 6.

As shown in fig. 1 to 2, after the instrument beam gauge 6 is mounted on the tool rack, the instrument beam gauge 6 can be adjusted to a position supported in the groove 16 of the center pillar 14 or rotated to a position where the positioning pin 13 on the connecting plate 11 is inserted into the positioning hole on the flange plate and hovers at a specific position, the operator mounts the mounting interface portion facing the operator, the height of the tool rack supporting the instrument beam is designed according to the height of the operator, so that the operator can conveniently work as a standard, and the mounting rack can be designed into a structure capable of adjusting the height according to needs.

In the tool rack for mounting the instrument beam detection tool, the head end ejector rod 7 and the tail end ejector rod 8 are coaxially arranged, and the driving hand wheel drives the instrument beam detection tool 6 to rotate through the head end ejector rod 7, so that torque needs to be transmitted between the head end ejector rod 7 and the instrument beam detection tool 6, and as a preferred implementation mode, the head end ejector rod 7 is provided with a square head for being inserted into a square hole in the head end of the instrument beam detection tool 6, so that the head end ejector rod 7 can drive the instrument beam detection tool 6 to rotate. The tail end ejector rod 8 plays a role in auxiliary supporting and positioning for the instrument cross beam detection tool 6, the tail end ejector rod 8 is provided with a cylindrical head used for being inserted into a round hole in the tail end of the instrument cross beam detection tool 6, and therefore the tail end ejector rod 8 and the tail end of the instrument cross beam detection tool 6 can be matched and positioned easily.

The instrument beam detection tool 6 is an irregular-shaped structural part, the instrument beam detection tool 6 comprises a connecting rod 15 and accessories connected to the connecting rod 15, and the connecting rod 15 is arranged coaxially with the head end ejector rod 7 or the tail end ejector rod 8. The instrument cross beam detection tool 6 is difficult to stay in a natural balance state under the action of gravity on a tool rack, and the maximum moment generated by the instrument cross beam detection tool 6 during rotation is relatively small by arranging the eccentric position of the connecting rod 15 relative to the head end ejector rod 7 or the tail end ejector rod 8.

In order to enable the instrument beam detection tool 6 to be rotated to a plurality of angle positions, so that an operator can conveniently carry out installation operation from different angle positions, a plurality of positioning holes can be formed in the flange plate 9, positioning pins on the connecting disc 11 can be inserted into different positioning holes when the driving hand wheel 12 is rotated, and the instrument beam detection tool 6 can be suspended at different angle positions. In addition, the middle upright post 14 can be designed to be telescopic in the height direction, so that the instrument cross beam gauge 6 can be supported by the middle upright post 14 at different height positions. The telescopic structure of the middle upright post can be realized by a mechanism capable of realizing telescopic in the prior art, and the detailed description is omitted here. As shown in fig. 5, the telescopic middle column 14 includes a column barrel 24 and a support post 25 inserted in the column barrel 24, a tightening screw (not shown) is provided on the column barrel 24 to lock the support post 25 at any position in the height direction, a slide rail 22 perpendicular to the connecting rod 15 of the instrument beam detection tool 6 is provided at the top end of the telescopic middle column 14, the slide rail 22 is perpendicular to the middle column 14, a slide block 23 is connected to the slide rail 22, and a groove 16 is provided on the slide block 23, so that when the instrument beam detection tool 6 needs to be supported at different height positions, the middle column 14 is adjusted to a set height, and when the connecting rod 15 of the instrument beam detection tool 6 is supported on the middle column 14, the slide block 23 is moved to the groove 16 to align with the connecting rod 15.

In order to enable the center pillar 14 to reliably support the instrument cross-beam gauge 6, as a preferred embodiment, as shown in fig. 2 and 3, the center pillar 14 is provided with a groove 16 for supporting the connecting rod 15. When the connecting rod 15 of the instrument beam gauge 6 is supported in the groove 16, the groove 16 can clamp the connecting rod 15, and the connecting rod 15 is reliably supported.

When the instrument cross beam detection tool 6 is connected with a tool frame, one end of the instrument cross beam detection tool 6 is connected with the tool frame, generally, the head end of the instrument cross beam detection tool 6 is connected with a head end ejector rod 7, in the process, the tail end ejector rod 8 needs to avoid the tail end of the instrument cross beam detection tool 6, therefore, the tail end ejector rod 8 can be designed to be in a telescopic mode, as an optimal implementation mode, as shown in fig. 4, the tail end ejector rod 8 is connected in a spring cylinder 17 in a sliding mode, the spring cylinder 17 is supported in a tail end bearing 5, and the tail end ejector rod 8 is pressed towards the instrument cross beam detection tool 6 by a spring in the spring cylinder 17. The length of the spring cartridge 17 is long, and in order to reliably support the spring cartridge 17, referring to fig. 4, the rear bearing 5 includes two bearing seats coaxially juxtaposed, and the spring cartridge 17 is connected between the two bearing seats.

Referring to fig. 4, a long groove 18 extending axially along the spring cylinder 17 is provided on the spring cylinder 17, the tail end ejector rod 8 is connected with a positioning column 19, the positioning column 19 is exposed from the long groove 18, a first positioning groove 20 perpendicular to the length direction of the long groove 18 is provided on the side wall of the head end of the long groove 18, and a second positioning groove 21 perpendicular to the length direction of the long groove 18 is provided at the tail end of the long groove 18; the tail mandril 8 can move on the spring barrel 17 shaft so that the positioning column 19 moves to the first positioning groove 20 or the second positioning groove 21. Like this, when utensil 6 is examined to the instrument crossbeam is connected with head end ejector pin 7, earlier with tail end ejector pin 8 retraction to spring case 17, move reference column 19 to second constant head tank 21 in, after utensil 6 is examined to the instrument crossbeam is accomplished with head end ejector pin 7 and is connected, in moving reference column 19 to first constant head tank 20 for tail end ejector pin 8 stretches out and inserts in the round hole on utensil 6 is examined to the instrument crossbeam from spring case 17. The tail end mandril 8 can rotate and move back and forth on the spring barrel 17, and in order to move the tail end mandril 8, as shown in fig. 4, a handle 10 perpendicular to the positioning column 19 is connected to the positioning column 19.

Based on the technical scheme of the embodiment, the tool frame for mounting the instrument cross beam detection tool can facilitate the mounting operation of parts on the instrument cross beam detection tool by an operator, and is simple in structure and convenient to use.

In conclusion, the present invention effectively overcomes various disadvantages of the prior art and has high industrial utilization value.

The foregoing embodiments are merely illustrative of the principles and utilities of the present invention and are not intended to limit the utility model. Any person skilled in the art can modify or change the above-mentioned embodiments without departing from the spirit and scope of the present invention. Accordingly, it is intended that all equivalent modifications or changes which can be made by those skilled in the art without departing from the spirit and technical spirit of the present invention be covered by the claims of the present invention.

Claims (9)

1. A tool rack for mounting an instrument beam detection tool is characterized by comprising a bottom frame, wherein a head end stand column and a tail end stand column which are arranged oppositely are arranged on the bottom frame, a head end bearing and a tail end bearing which are coaxially arranged are respectively mounted on the head end stand column and the tail end stand column, a head end ejector rod for ejecting the head end of the instrument beam detection tool is mounted in the head end bearing, and a tail end ejector rod for ejecting the tail end of the instrument beam detection tool is mounted in the tail end bearing;

a flange plate is fixed on the head end upright post, and a positioning hole is formed in the flange plate; a connecting disc is coaxially fixed on the head end ejector rod and driven by a driving hand wheel, and a positioning pin is inserted in the connecting disc; the chassis is also provided with a middle upright post for supporting the instrument beam detection tool;

when the instrument cross beam gauge is connected between the head end ejector rod and the tail end ejector rod, the instrument cross beam gauge can be rotated to be supported on the middle upright post by rotating the driving hand wheel; or the hand wheel is driven to rotate so that the positioning pin on the connecting disc is inserted into the positioning hole on the flange plate, and the instrument cross beam detection tool is suspended at a specific position.

2. The tool rack for mounting the instrument beam testing fixture according to claim 1, wherein: the head end ejector rod is provided with a square head used for being inserted into a square hole in the head end of the instrument cross beam gauge.

3. The tool rack for mounting the instrument beam testing fixture according to claim 1, wherein: the instrument crossbeam detection tool comprises a connecting rod and an accessory connected with the connecting rod, wherein the connecting rod is arranged with the head end ejector rod or the tail end ejector rod in a non-coaxial mode.

4. The tool rack for mounting the instrument beam testing fixture according to claim 3, wherein: and a groove for bearing the connecting rod is arranged on the middle upright post.

5. The tool rack for mounting the instrument beam testing fixture according to claim 1, wherein: the tail end ejector rod is provided with a cylindrical head used for being inserted into a round hole in the tail end of the instrument cross beam detection tool.

6. The tool rack for mounting the instrument beam testing fixture according to claim 1, wherein: the tail end ejector rod is connected in a spring barrel in a sliding mode, the spring barrel is supported in a tail end bearing, and the tail end ejector rod is pressed towards the instrument cross beam detection tool by a spring in the spring barrel.

7. The tool rack for mounting the instrument beam testing fixture according to claim 6, wherein: the tail end bearing comprises two bearing blocks which are coaxially arranged in parallel, and the spring cylinder is connected in the two bearing blocks.

8. The tool rack for mounting the instrument beam testing fixture according to claim 6, wherein: the spring cylinder is provided with a long groove extending along the axial direction of the spring cylinder, the tail end ejector rod is connected with a positioning column, the positioning column is exposed out of the long groove, the side wall of the head end of the long groove is provided with a first positioning groove vertical to the length direction of the long groove, and the tail end of the long groove is provided with a second positioning groove vertical to the length direction of the long groove; the tail end ejector rod can move on the spring cylinder shaft to enable the positioning column to move into the first positioning groove or the second positioning groove.

9. The tool rack for mounting the instrument beam testing fixture according to claim 8, wherein: and the positioning column is connected with a handle perpendicular to the positioning column.

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