CN220840095U - Rotatable testing table - Google Patents

Abstract

The utility model discloses a rotatable detection table, which comprises a detection platform, a clamp mechanism and a clamping plate mechanism, wherein a chute is fixedly arranged on the upper end surface of the detection platform, a driving screw rod is rotatably connected between the inner walls of the two sides of the chute, mounting blocks are sleeved on the outer walls of the two sides of the driving screw rod in a threaded manner, the clamp mechanism comprises two mounting plates, the two mounting plates are respectively and fixedly connected to the upper end surfaces of the two mounting blocks, supporting plates are fixedly connected to the upper end surfaces of the two mounting plates, regulating shafts are rotatably sleeved on the two supporting plates, regulating plates are fixedly connected to the opposite ends of the two regulating shafts, and regulating grooves are fixedly formed in the outer walls of the opposite ends of the two regulating plates. The rotatable detection table disclosed by the utility model can effectively carry out rotation adjustment on an object to be detected, is convenient to carry out more comprehensive detection, can adapt to the object clamping requirement of uneven surfaces, and has practicability.

Description

A rotatable testing table

Technical Field

The utility model relates to the technical field of detection platforms, in particular to a rotatable detection platform.

Background technique

Automated testing is a process that converts human-driven testing behavior into machine execution. Usually, after the test case is designed and passed the review, the tester performs the test step by step according to the procedures described in the test case to compare the actual results with the expected results. In this process, in order to save manpower, time or hardware resources and improve testing efficiency, the concept of automated testing was introduced.

The current automated inspection platform uses a fixture to clamp and fix objects during use, making the object inspection process more stable. However, the fixture is generally fixed in position after clamping, resulting in blind spots in the inspection of the object being inspected. Manual flipping is required, which affects efficiency and is inconvenient. Based on this, we propose a rotatable inspection table for improvement.

Utility Model Content

The main purpose of the utility model is to provide a rotatable testing platform, which can effectively solve the technical problems in the background technology.

In order to achieve the above purpose, the technical solution adopted by the utility model is:

A rotatable inspection platform, comprising an inspection platform, a fixture mechanism and a clamping plate mechanism, wherein a slide groove is fixedly provided on the upper surface of the inspection platform, a driving screw is rotatably connected between the inner walls on both sides of the slide groove, and mounting blocks are threadedly sleeved on the outer walls on both sides of the driving screw, and the fixture mechanism comprises two mounting plates, and the two mounting plates are respectively fixedly connected to the upper end surfaces of the two mounting blocks;

The upper end surfaces of the two mounting plates are fixedly connected with support plates, and the two support plates are rotatably sleeved with adjustment shafts. The two adjustment shafts are fixedly connected with adjustment plates at one opposite end, and adjustment grooves are fixedly opened on the outer walls at one opposite end of the two adjustment plates. Adjustment screws are rotatably connected between the front and rear inner walls of the two adjustment grooves, and sliders are threadedly sleeved on the two adjustment screws near the front and rear outer walls.

As a further solution of the utility model, a servo motor is fixedly arranged on the upper surface of one of the mounting plates, and a transmission component is sleeved on the output end of the servo motor and the outer wall of the adjusting shaft.

As a further solution of the utility model, the front ends of the two adjusting screw rods both penetrate the adjusting plate and are fixedly connected with knobs.

As a further solution of the utility model, the clamping mechanism includes a fixed plate, which is fixedly connected to the outer wall of the slider, and a plurality of mounting grooves are fixedly opened on the outer wall of the fixed plate, and buffer pins and buffer springs are sleeved in the plurality of mounting grooves, and the other ends of the plurality of buffer pins and buffer springs are fixedly connected to a convex plate.

As a further solution of the utility model, the plurality of buffer springs are movably sleeved on the outer walls of the plurality of buffer pins respectively.

As a further solution of the utility model, a plurality of the installation grooves are evenly distributed on the outer wall of the fixing plate.

The beneficial effects of the utility model are as follows:

By driving the screw rod to rotate and drive the two mounting blocks to move relative to each other, the clamp mechanism can be driven to move relative to each other to clamp and fix the object. Then, the servo motor is used to drive the adjustment shaft to rotate through the transmission assembly to rotate the clamped object, which is convenient for more comprehensive detection of the object and has practicality.

By setting up a clamping mechanism that cooperates with the clamping mechanism to clamp the object, and connecting the convex plate and the fixed plate on the clamping mechanism that contact the surface of the object through a buffer pin and a buffer spring, the clamping mechanism can adapt to the clamping needs of objects with uneven surfaces, improve the clamping force, and be more stable.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG1 is a schematic diagram of the overall structure of a rotatable testing platform of the utility model;

FIG2 is a schematic diagram of the internal structure of a slideway of a rotatable testing platform of the present invention;

FIG. 3 is a schematic diagram of the disassembled structure of a clamping plate mechanism of a rotatable testing platform of the utility model.

In the figure: 1. detection platform; 2. slide groove; 3. driving screw; 4. mounting block; 5. clamping mechanism; 51. mounting plate; 52. support plate; 53. adjusting shaft; 54. servo motor; 55. transmission assembly; 56. adjusting plate; 57. adjusting groove; 58. adjusting screw; 59. slider; 510. knob; 6. clamping plate mechanism; 61. fixing plate; 62. mounting groove; 63. buffer pin; 64. buffer spring; 65. convex plate.

Detailed ways

In order to make the technical means, creative features, objectives and effects achieved by the present invention easy to understand, the present invention is further described below in conjunction with specific implementation methods.

As shown in Figures 1-3, a rotatable inspection table includes an inspection platform 1, a clamping mechanism 5 and a clamping plate mechanism 6. A slide groove 2 is fixedly opened on the upper end surface of the inspection platform 1, and a driving screw 3 is rotatably connected between the inner walls on both sides of the slide groove 2. Mounting blocks 4 are threadedly sleeved on the outer walls on both sides of the driving screw 3. The clamping mechanism 5 includes two mounting plates 51, and the two mounting plates 51 are respectively fixedly connected to the upper end surfaces of the two mounting blocks 4.

The upper end surfaces of the two mounting plates 51 are fixedly connected to support plates 52, and the two support plates 52 are rotatably sleeved with adjustment shafts 53. The two adjustment shafts 53 are fixedly connected to adjustment plates 56 at the opposite ends. Adjustment grooves 57 are fixedly opened on the outer walls of the opposite ends of the two adjustment plates 56. Adjustment screws 58 are rotatably connected between the front and rear inner walls of the two adjustment grooves 57. The two adjustment screws 58 are threadedly sleeved with sliders 59 near the front and rear outer walls. The adjustment screws 58 and the driving screw 3 are made of double-threaded screws.

In this embodiment, a servo motor 54 is fixedly installed on the upper end surface of one of the mounting plates 51, and a transmission assembly 55 is sleeved on the output end of the servo motor 54 and the outer wall of the adjustment shaft 53. The servo motor 54 can drive the adjustment shaft 53 to rotate through the transmission assembly 55, and then drive the adjustment plate 56 to rotate, and finally drive the object fixed and clamped by the clamping mechanism 6 to rotate.

In this embodiment, the front ends of the two adjusting screw rods 58 penetrate the adjusting plate 56 and are fixedly connected with a knob 510 . The knob 510 can be used to drive the adjusting screw rods 58 to rotate, thereby controlling the relative movement of the two sliders 59 .

In this embodiment, the clamping mechanism 6 includes a fixed plate 61, which is fixedly connected to the outer wall of the slider 59. A plurality of mounting grooves 62 are fixedly opened on the outer wall of the fixed plate 61. The plurality of mounting grooves 62 are evenly distributed on the outer wall of the fixed plate 61. Buffer pins 63 and buffer springs 64 are sleeved in the plurality of mounting grooves 62. The plurality of buffer springs 64 are movably sleeved on the outer walls of the plurality of buffer pins 63, respectively. The other ends of the plurality of buffer pins 63 and buffer springs 64 are fixedly connected with a convex plate 65. The buffer pins 63 cooperate with the buffer springs 64 to drive the convex plate 65 to press and clamp the object.

It should be noted that the utility model is a rotatable testing platform. When in use, the driving screw 3 is driven to rotate by the motor, thereby controlling the relative movement of the two mounting blocks 4, thereby driving the clamp mechanism 5 to clamp the object, and the knob 510 is used to drive the adjusting screw 58 to rotate, thereby driving the two sliders 59 to move relative to each other, thereby driving the clamp mechanism 6 to clamp and fix the other surfaces of the object, thereby improving the clamping stability. Then, the servo motor 54 is used to drive the adjusting shaft 53 to rotate through the transmission assembly 55, thereby driving the adjusting plate 56 to rotate, thereby driving the clamped object to rotate, thereby facilitating a more comprehensive inspection of the object, which is convenient and saves trouble.

The above shows and describes the basic principle and main features of the utility model and the advantages of the utility model. Those skilled in the art should understand that the utility model is not limited by the above embodiments. The above embodiments and descriptions are only for explaining the principle of the utility model. Without departing from the spirit and scope of the utility model, the utility model may have various changes and improvements, which fall within the scope of the utility model to be protected. The scope of protection of the utility model is defined by the attached claims and their equivalents.

Claims (6)

1. A rotatable test stand, characterized in that: the device comprises a detection platform (1), a clamp mechanism (5) and a clamping plate mechanism (6), wherein a chute (2) is fixedly arranged on the upper end surface of the detection platform (1), a driving screw rod (3) is rotationally connected between the inner walls of the two sides of the chute (2), mounting blocks (4) are sleeved on the outer walls of the two sides of the driving screw rod (3) through threads, the clamp mechanism (5) comprises two mounting plates (51), and the two mounting plates (51) are respectively and fixedly connected to the upper end surfaces of the two mounting blocks (4);

Two equal fixedly connected with backup pad (52) of mounting panel (51) up end, two all rotate on backup pad (52) and cup jointed regulating spindle (53), two equal fixedly connected with regulating plate (56) of the relative one end of regulating spindle (53), two all fixedly seted up adjustment tank (57) on the outer wall of the relative one end of regulating plate (56), two all rotate between the inner wall around adjustment tank (57) and be connected with accommodate the lead screw (58), two equal screw thread has cup jointed slider (59) on the outer wall around accommodate the lead screw (58) is close to.

2. A rotatable inspection station as claimed in claim 1, wherein: wherein, a servo motor (54) is fixedly arranged on the upper end surface of the mounting plate (51), and a transmission assembly (55) is sleeved on the output end of the servo motor (54) and the outer wall of the adjusting shaft (53).

3. A rotatable inspection station as claimed in claim 1, wherein: the front ends of the two adjusting screw rods (58) penetrate through the adjusting plate (56) and are fixedly connected with a knob (510).

4. A rotatable inspection station as claimed in claim 1, wherein: the clamping plate mechanism (6) comprises a fixing plate (61), the fixing plate (61) is fixedly connected to the outer wall of the sliding block (59), a plurality of mounting grooves (62) are fixedly formed in the outer wall of the fixing plate (61), a plurality of buffer pins (63) and buffer springs (64) are sleeved in the mounting grooves (62), and a plurality of convex plates (65) are fixedly connected to the other ends of the buffer pins (63) and the buffer springs (64).

5. The rotatable inspection station of claim 4, wherein: the buffer springs (64) are movably sleeved on the outer walls of the buffer pins (63) respectively.

6. The rotatable inspection station of claim 4, wherein: the plurality of mounting grooves (62) are uniformly distributed on the outer wall of the fixed plate (61).