CN221924898U - A glass thickness detection tool - Google Patents

Abstract

The utility model provides a glass thickness detection tool, which relates to the technical field of glass thickness detection tools and comprises a bottom plate and a contact plate, wherein an L-shaped plate is fixedly arranged at the top end of the bottom plate, an electric push rod is fixedly arranged at the top end of the L-shaped plate, a connecting plate is fixedly arranged at the output end of the electric push rod, a measuring ruler is fixedly arranged on the surface of the contact plate, a processing table is slidingly connected to the surface of the L-shaped plate, a bidirectional threaded rod A is rotatably connected to the inner side of the processing table, and a clamping plate is connected to the surface of the bidirectional threaded rod A in a threaded manner. According to the utility model, through arranging the motor, the bidirectional threaded rod B, the sliding groove, the sliding plate, the transverse plate, the rotating plate, the fixed block and the connecting plate, the distance between the processing table and the electric push rod can be adjusted by rotating the bidirectional threaded rod B, so that the device is applicable to glass and glass products with different thicknesses, the adjusting process is rapid and convenient, and the flexibility and the adaptability are improved.

Description

A glass thickness detection tool

Technical Field

The utility model relates to the technical field of glass thickness detection tooling, in particular to a glass thickness detection tooling.

Background Art

The glass thickness detection tool is a device or tool for measuring the thickness of a glass plate or glass product. Publication No. CN219454911U discloses a thickness detection tool for hollow glass processing, which includes: a mounting plate; a second connecting plate, the bottom of the second connecting plate is fixedly connected to the top of the mounting plate, and the right side of the second connecting plate is fixedly connected to the first connecting plate. The utility model provides a thickness detection tool for hollow glass processing. The utility model has a function of starting the electric telescopic rod to extend outward by pressing the control switch, thereby moving the connecting block downward, and at the same time, the connecting block moves downward along the scale plate with the connecting strip and the moving block until the bottom of the connecting block contacts the surface of the hollow glass to be detected. This thickness detection tool for hollow glass processing avoids the need for manual detection work, thereby reducing the fatigue of the detection personnel and reducing the detection error. However, this thickness detection tool can only measure glass of a certain thickness, and no adjustment mechanism is provided. It is difficult to measure when facing some glass or glass products with higher thickness, and needs to be improved.

Utility Model Content

The purpose of the utility model is to solve the technical problems raised in the above background technology.

The utility model adopts the following technical scheme: a glass thickness detection tool, comprising a bottom plate and a contact plate, an L-shaped plate is fixedly installed on the top of the bottom plate, an electric push rod is fixedly installed on the top of the L-shaped plate, a connecting plate is fixedly installed on the output end of the electric push rod, a measuring ruler is fixedly installed on the surface of the contact plate, a processing table is slidably connected to the surface of the L-shaped plate, a two-way threaded rod A is rotatably connected to the inner side of the processing table, a clamp is threadedly connected to the surface of the two-way threaded rod A, a motor is fixedly installed on the bottom end of the processing table, a two-way threaded rod B is fixedly installed on the output end of the motor, a sliding groove is provided at the bottom end of the processing table, a sliding plate is slidably connected to the inner side of the sliding groove, a cross plate is fixedly installed on the inner side of the sliding plate, a rotating plate is rotatably connected to the surface of the sliding plate, and a fixed block is rotatably connected to the inner side of the rotating plate.

Preferably, the surface of the bidirectional threaded rod A is provided with two sets of opposite threads, the inner side of the clamping plate is provided with threads, and the threads provided on the inner sides of the two sets of clamping plates are respectively engaged with the two sets of threads on the surface of the bidirectional threaded rod A. Here, by providing the threads on the inner sides of the clamping plates, the two sets of clamping plates can be driven to slide in opposite directions by rotating the bidirectional threaded rod A, so that the glass can be clamped.

Preferably, the surface of the bidirectional threaded rod B is provided with two sets of opposite threads, the inner side of the transverse plate is provided with threads, and the threads provided on the inner sides of the two sets of transverse plates are respectively engaged with the two sets of threads on the surface of the bidirectional threaded rod B. Here, by providing the threads on the inner side of the transverse plate, the two sets of transverse plates and the slide plate can be driven to slide in opposite directions along the slide groove during the rotation of the bidirectional threaded rod B, thereby adjusting the height of the processing table.

Preferably, the fixing block is fixedly installed on the top of the bottom plate, and the measuring ruler is slidably connected to the L-shaped plate. Here, by setting the fixing block and the bottom plate, the processing table can be driven up and down to adjust in coordination with the rotating plate during the rotation of the bidirectional threaded rod.

Preferably, a convex plate is fixedly installed at the bottom end of the connecting plate, a sliding rod is fixedly installed on the side of the convex plate, a spring is sleeved on the surface of the sliding rod, a slider is slidably connected to the surface of the sliding rod, a connecting plate is rotatably connected to the surface of the slider, a block is fixedly installed on the inner side of the contact plate, and a guide rod is fixedly installed on the inner side of the contact plate. Here, by providing the convex plate, the sliding rod, the spring, the slider, the connecting plate, the block, and the guide rod, a buffering effect can be achieved when the telescopic rod drives the contact plate and the measuring ruler to descend and contact the measured glass, thereby preventing the glass from breaking due to excessive pressure.

Preferably, one end of the spring is fixedly mounted on the side of the convex plate, and the other end of the spring is fixedly mounted on the side of the slider. Here, by providing the spring, an effective buffering effect can be achieved in cooperation with the connecting plate and the slider during the pressing process of the contact plate.

Preferably, the guide rod is slidably connected to the connecting plate, and the block is rotatably connected to the connecting plate. Here, by providing the guide rod, a guiding effect can be achieved, the stability of the contact plate when it descends can be improved, and the measurement error can be reduced.

Compared with the prior art, the advantages and positive effects of the utility model are:

1. In the utility model, by arranging a motor, a bidirectional threaded rod B, a slide groove, a slide plate, a horizontal plate, a rotating plate, a fixed block, and a connecting plate, the distance between the processing table and the electric push rod can be adjusted by rotating the bidirectional threaded rod B, so that it can be suitable for glass and glass products of different thicknesses. The adjustment process is quick and convenient, thereby improving flexibility and adaptability.

2. In the utility model, by providing a convex plate, a sliding rod, a spring, a slider, a connecting plate, a block, and a guide rod, a buffering effect can be achieved after the contact plate is pressed down and contacts the glass to be tested, which can effectively avoid glass cracks caused by excessive pressure of the electric push rod.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG1 is a schematic diagram of a glass thickness detection tooling proposed by the present invention;

FIG2 is a bottom view of a glass thickness detection tooling proposed by the present invention;

FIG3 is a partial structural cross-sectional view of a glass thickness detection tooling proposed by the present invention;

FIG. 4 is an enlarged view of point A in FIG. 3 of a glass thickness detection tooling proposed by the present invention.

Legend:

1. Bottom plate; 2. L-shaped plate; 3. Electric push rod; 4. Contact plate; 5. Measuring ruler; 6. Processing table; 7. Two-way threaded rod A; 8. Clamp; 9. Motor; 10. Two-way threaded rod B; 11. Slide; 12. Slide plate; 13. Horizontal plate; 14. Rotating plate; 15. Fixed block; 16. Connecting plate; 17. Convex plate; 18. Sliding rod; 19. Spring; 20. Sliding block; 21. Connecting plate; 22. Block; 23. Guide rod.

DETAILED DESCRIPTION

In order to more clearly understand the above-mentioned purpose, features and advantages of the utility model, the utility model is further described below in conjunction with the accompanying drawings and embodiments. It should be noted that the embodiments of the present application and the features in the embodiments can be combined with each other without conflict.

In the following description, many specific details are set forth to facilitate a full understanding of the present invention. However, the present invention may also be implemented in other ways than those described herein. Therefore, the present invention is not limited to the specific embodiments of the following disclosure.

Embodiment 1

Please refer to Figures 1-3. The utility model provides a technical solution: a glass thickness detection tool, including a bottom plate 1 and a contact plate 4, an L-shaped plate 2 is fixedly installed on the top of the bottom plate 1, an electric push rod 3 is fixedly installed on the top of the L-shaped plate 2, a connecting plate 16 is fixedly installed on the output end of the electric push rod 3, a measuring ruler 5 is fixedly installed on the surface of the contact plate 4, the measuring ruler 5 is slidably connected to the L-shaped plate 2, a processing table 6 is slidably connected to the surface of the L-shaped plate 2, a bidirectional threaded rod A7 is rotatably connected to the inner side of the processing table 6, two groups of reverse threads are provided on the surface of the bidirectional threaded rod A7, a thread is provided on the inner side of a clamping plate 8, and the threads provided on the inner sides of the two groups of clamping plates 8 are respectively meshed with the two groups of threads on the surface of the bidirectional threaded rod A7, the surface of the bidirectional threaded rod A7 is threadedly connected with the clamping plate 8, and by setting the threads on the inner side of the clamping plate 8, the two groups of threads can be driven by rotating the bidirectional threaded rod A7. The clamping plate 8 slides in the opposite direction, so that the glass can be clamped. A motor 9 is fixedly installed at the bottom end of the processing table 6, and a bidirectional threaded rod B10 is fixedly installed at the output end of the motor 9. The motor 9 is started and drives the bidirectional threaded rod B10 to rotate. Under the action of the thread, the two groups of cross plates 13 and the slide plate 12 will be driven to slide along the slide groove 11. The surface of the bidirectional threaded rod B10 is provided with two groups of reverse threads, and the inner side of the cross plate 13 is provided with threads, and the threads provided on the inner sides of the two groups of cross plates 13 are respectively engaged with the two groups of threads on the surface of the bidirectional threaded rod B10. A slide groove 11 is provided at the bottom end of the processing table 6, and the inner side of the slide groove 11 is slidably connected with a slide plate 12, and the inner side of the slide plate 12 is fixedly installed with a cross plate 13. The surface of the slide plate 12 is rotatably connected with a rotating plate 14, and the inner side of the rotating plate 14 is rotatably connected with a fixed block 15, and the fixed block 15 is fixedly installed at the top of the bottom plate 1.

Embodiment 2

Please refer to Figures 3-4. A convex plate 17 is fixedly installed on the bottom end of the connecting plate 16, and a sliding rod 18 is fixedly installed on the side of the convex plate 17. A spring 19 is sleeved on the surface of the sliding rod 18. One end of the spring 19 is fixedly installed on the side of the convex plate 17, and the other end of the spring 19 is fixedly installed on the side of the sliding block 20. The surface of the sliding rod 18 is slidably connected to the sliding block 20, and the surface of the sliding block 20 is rotatably connected to the connecting plate 21. A block 22 is fixedly installed on the inner side of the contact plate 4, and the block 22 is rotatably connected to the connecting plate 21. A guide rod 23 is fixedly installed on the inner side of the contact plate 4, and the guide rod 23 is slidably connected to the connecting plate 16. After the contact plate 4 is pressed down and contacts the glass to be tested, a buffer effect can be obtained, which can effectively avoid the glass cracking caused by excessive pressure on the electric push rod 3.

Working principle: When working, first adjust the height of the processing table 6 according to the thickness of the glass to be tested, start the motor 9 and drive the two-way threaded rod B10 to rotate. Under the action of the thread, the two sets of horizontal plates 13 and the slide plate 12 will slide along the slide groove 11. At the same time, the rotating plate 14 will be driven to adjust the position. The rise or fall of the processing table 6 is achieved by changing the angle between the rotating plate 14 and the bottom plate 1. After the position of the processing table 6 is adjusted, the glass to be tested is first placed on the processing table 6, and then the two-way threaded rod A7 is rotated to drive the two sets of clamping plates 8 along the processing table 6. The glass to be measured is clamped and fixed by sliding in the reverse direction, and then the electric push rod 3 is started to drive the contact plate 4 to descend. After the contact plate 4 contacts the glass to be measured, the connecting plate 16 will continue to slide downward along the guide rod 23 under the action of pressure. At this time, the block 22 will drive the slider 20 to slide outward on the slide bar 18 through the connecting plate 21, so that the slider 20 squeezes the springs 19 on both sides and is buffered, thereby preventing the glass to be measured from being damaged due to excessive pressure of the electric push rod 3. Then the glass thickness can be calculated according to the measuring ruler 5.

The above description is only a preferred embodiment of the present invention and does not limit the present invention in other forms. Any technician familiar with the profession may use the technical content disclosed above to change or modify it into an equivalent embodiment with equivalent changes and apply it to other fields. However, any simple modification, equivalent change and modification made to the above embodiment based on the technical essence of the present invention without departing from the content of the technical solution of the present invention still falls within the protection scope of the technical solution of the present invention.

Claims (7)

1. A glass thickness detection tool, comprising a bottom plate (1) and a contact plate (4), characterized in that: an L-shaped plate (2) is fixedly mounted on the top of the bottom plate (1), an electric push rod (3) is fixedly mounted on the top of the L-shaped plate (2), a connecting plate (16) is fixedly mounted on the output end of the electric push rod (3), a measuring ruler (5) is fixedly mounted on the surface of the contact plate (4), a processing table (6) is slidably connected to the surface of the L-shaped plate (2), a bidirectional threaded rod A (7) is rotatably connected to the inner side of the processing table (6), and the bidirectional threaded rod A (7) is rotatably connected to the inner side of the processing table (6), and the bidirectional threaded rod A (7) is rotatably connected to the inner side of the processing table (6). The surface of the threaded rod A (7) is threadedly connected with a clamping plate (8); the bottom end of the processing table (6) is fixedly installed with a motor (9); the output end of the motor (9) is fixedly installed with a bidirectional threaded rod B (10); the bottom end of the processing table (6) is provided with a slide groove (11); the inner side of the slide groove (11) is slidably connected with a slide plate (12); the inner side of the slide plate (12) is fixedly installed with a cross plate (13); the surface of the slide plate (12) is rotatably connected with a rotating plate (14); the inner side of the rotating plate (14) is rotatably connected with a fixed block (15). 2. The glass thickness detection tool according to claim 1 is characterized in that: the surface of the bidirectional threaded rod A (7) is provided with two sets of opposite threads, the inner side of the clamping plate (8) is provided with threads, and the threads provided on the inner sides of the two sets of clamping plates (8) are respectively engaged with the two sets of threads on the surface of the bidirectional threaded rod A (7). 3. The glass thickness detection tool according to claim 1 is characterized in that: the surface of the bidirectional threaded rod B (10) is provided with two sets of opposite threads, the inner side of the cross plate (13) is provided with threads, and the two sets of threads provided on the inner side of the cross plate (13) are respectively engaged with the two sets of threads on the surface of the bidirectional threaded rod B (10). 4. The glass thickness detection tool according to claim 1 is characterized in that: the fixed block (15) is fixedly installed on the top of the bottom plate (1), and the measuring ruler (5) is slidably connected to the L-shaped plate (2). 5. The glass thickness detection tooling according to claim 1 is characterized in that: a convex plate (17) is fixedly installed on the bottom end of the connecting plate (16), a sliding rod (18) is fixedly installed on the side of the convex plate (17), a spring (19) is sleeved on the surface of the sliding rod (18), a sliding block (20) is slidably connected to the surface of the sliding rod (18), and a connecting plate (21) is rotatably connected to the surface of the sliding block (20), a block (22) is fixedly installed on the inner side of the contact plate (4), and a guide rod (23) is fixedly installed on the inner side of the contact plate (4). 6. The glass thickness detection tooling according to claim 5 is characterized in that one end of the spring (19) is fixedly mounted on the side of the convex plate (17), and the other end of the spring (19) is fixedly mounted on the side of the slider (20). 7. The glass thickness detection tool according to claim 5, characterized in that: the guide rod (23) is slidably connected to the connecting plate (16), and the block (22) is rotatably connected to the connecting plate (21).