Tooling platform with rotating structure
By designing a tooling platform with a rotating structure, and using a servo geared motor to drive the rotating outer frame and inner frame to flip, the tedious problem of manually adjusting the angle and flipping in the cleaning of plate-shaped workpieces is solved, realizing an automated workpiece cleaning process that can accommodate the fixing of workpieces of different sizes.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- WUXI AOHUAN MACHINERY MFG
- Filing Date
- 2025-07-10
- Publication Date
- 2026-06-09
AI Technical Summary
The existing cleaning process for plate-shaped workpieces requires manual adjustment of angles and flipping, which makes the operation cumbersome, time-consuming and labor-intensive, and lacks tooling design for rotating workpieces.
A tooling platform with a rotating structure was designed, including a rotating platform, a rotating tooling frame, and a workpiece limiting fixture assembly. A servo geared motor is used to drive the rotating outer frame and rotating inner frame to rotate. Combined with the adjustable workpiece limiting fixture assembly, the automatic angle adjustment and rotation of the workpiece can be realized.
It enables automated angle adjustment and flipping of workpieces, simplifies the cleaning process, improves cleaning efficiency and convenience, and adapts to the fixing requirements of workpieces of different sizes.
Smart Images

Figure CN224333040U_ABST
Abstract
Description
Technical Field
[0001] This utility model belongs to the field of tooling platform technology, specifically relating to a tooling platform with a rotating structure. Background Technology
[0002] When cleaning plate-shaped workpieces that are contaminated with oil or other impurities, they are usually placed manually at the cleaning station and then cleaned by high-pressure spray. During the cleaning process, it is necessary to stop the high-pressure spray and manually adjust the angle of the plate-shaped workpiece and flip it over so that the high-pressure spray can thoroughly clean the surface of the workpiece.
[0003] In the traditional method of cleaning plate-shaped workpieces, manual adjustment of the workpiece angle and flipping are required, which is cumbersome, time-consuming and labor-intensive. There is no tooling for rotating plate-shaped workpieces during cleaning, which needs to be improved to solve the problem of tooling design without rotating workpieces.
[0004] Existing tooling designs for cleaning plate-shaped workpieces lack the ability to rotate the workpiece. To address this, this application proposes a tooling platform with a rotating structure. Utility Model Content
[0005] The purpose of this utility model is to provide a tooling platform with a rotating structure to solve the problem of tooling design without rotating workpieces mentioned in the background art.
[0006] To achieve the above objectives, this utility model provides the following technical solution: a tooling platform with a rotating structure, comprising...
[0007] A rotating platform includes a platform frame, a stabilizing box fixed to the platform frame by bolts, a first servo geared motor bolted inside the stabilizing box, and a rotating outer frame mounted on the platform frame and fixed to the stabilizing box by bolts.
[0008] The rotating tooling frame includes a fixed box that is fixed to the rotating outer frame by bolts, a second servo motor installed inside the fixed box, a rotating inner frame installed inside the rotating outer frame, a first rotating shaft and a second rotating shaft installed on opposite surfaces of the rotating inner frame, and symmetrically distributed guide rods provided inside the rotating inner frame.
[0009] A workpiece limiting fixture assembly for fixing plate-shaped workpieces includes a lifting block slidably sleeved on the outside of a guide rod, a mounting plate mounted on the outside of the lifting block, a support plate of the vertical mounting plate, and a limiting rod that is threadedly connected and fixed to the support plate.
[0010] Preferably, the platform frame includes a parallel chassis and columns supporting the frustum and perpendicular to the chassis.
[0011] Preferably, the supporting frustum is a stepped inverted "T" shaped structure, the outer surface of the bottom of the supporting frustum is provided with a concave annular groove, and a limiting block embedded in the annular groove is welded to the top of the column, the limiting block being arc-shaped.
[0012] Preferably, the mounting plate has a "U" shaped structure, and a locking screw for locking the lifting block passes through the mounting plate.
[0013] Preferably, the surface of the support plate is provided with equally spaced screw holes c, and the limiting rod engages with the screw holes c.
[0014] Preferably, the limiting rod is perpendicular to the support plate, and the distance between adjacent limiting rods is a spacing H.
[0015] Preferably, the center of the rotating inner frame coincides with the center of the rotating outer frame, and the distance between the top surface of the rotating inner frame and the inner surface of the top of the rotating outer frame is a spacing F.
[0016] Compared with the prior art, the beneficial effects of this utility model are:
[0017] 1. In this utility model, the designed rotating platform and rotating tooling frame, when the first servo reduction motor and the second servo motor are running respectively, cause the outer rotating frame to rotate and the inner rotating frame to flip, thereby changing the workpiece angle and flipping the workpiece so that different surfaces of the workpiece can come into contact with the cleaning spray liquid.
[0018] 2. In this utility model, the position of the workpiece limiting fixture assembly can be changed by designing different mounting plates, support plates and limiting rods, so as to make it suitable for workpieces of different sizes. Attached Figure Description
[0019] Figure 1 This is a three-dimensional structural diagram of the present invention;
[0020] Figure 2 For the present utility model Figure 1 Schematic diagram of the structure in the C-direction;
[0021] Figure 3 For the present utility model Figure 1 Enlarged structural diagram of section A in the middle;
[0022] Figure 4 For the present utility model Figure 2 Schematic diagram of the structure in the middle BB direction;
[0023] In the diagram: 1. Platform frame; 4. Guide rod; 5. Workpiece limiting fixture assembly; 11. Chassis; 12. Column; 13. Supporting frustum; 21. Stabilizing box; 22. Rotating outer frame; 23. First servo geared motor; 31. Fixing box; 32. Rotating inner frame; 33. First rotating shaft; 34. Second rotating shaft; 35. Second servo motor; 51. Lifting block; 52. Mounting plate; 53. Support plate; 54. Limiting rod; 121. Limiting block; 521. Locking screw. Detailed Implementation
[0024] The technical solutions of the present utility model will be clearly and completely described below with reference to the accompanying drawings of the embodiments. Obviously, the described embodiments are only some embodiments of the present utility model, and not all embodiments. Based on the embodiments of the present utility model, all other embodiments obtained by those of ordinary skill in the art without creative effort are within the protection scope of the present utility model.
[0025] Please see Figures 1 to 4This utility model provides a technical solution: a tooling platform with a rotating structure, including a rotating platform, a platform frame 1, a stabilizing box 21 fixed to the platform frame 1 by bolts, a first servo geared motor 23 bolted inside the stabilizing box 21, and a rotating outer frame 22 mounted on the platform frame 1 and fixed to the stabilizing box 21 by bolts. The output shaft of the first servo geared motor 23 is fixedly connected to the rotating outer frame 22 by bolts. When the first servo geared motor 23 is started, it drives the rotating outer frame 22 to rotate, causing the inner rotating frame 3 to rotate. The plate-shaped workpiece inside rotates along direction b, which changes the angle of the workpiece. The rotating fixture frame includes a fixed box 31 fixed to the rotating outer frame 22 by bolts, a second servo motor 35 installed inside the fixed box 31, a rotating inner frame 32 installed inside the rotating outer frame 22, and a first rotating shaft 33 and a second rotating shaft 34 installed on opposite surfaces of the rotating inner frame 32. The rotating inner frame 32 is provided with symmetrically distributed guide rods 4. The output shaft of the second servo motor 35 is fixed to the first rotating shaft 33 by bolts. The first rotating shaft 33 and the second rotating shaft 34... The rotating outer frame 22 is connected to the rotating inner frame 32 via bearings. When the second servo motor 35 is running, the second servo motor 35 drives the rotating outer frame 22 to rotate in the a direction, thereby achieving the purpose of flipping the rotating inner frame 32. This can achieve the purpose of flipping the rotating inner frame 32 and the workpiece even when the spray range is limited, so that different surfaces of the workpiece come into contact with the cleaning spray liquid. The workpiece limiting clamp assembly 5 for fixing the plate-shaped workpiece includes a lifting block 51 slidably sleeved on the outside of the guide rod 4, a mounting plate 52 installed on the outside of the lifting block 51, a support plate 53 perpendicular to the mounting plate 52, and a clamping device connected to the support plate 53 via bearings. The limiting rod 54 is fixed by a threaded connection. The support plate 53 is welded to the mounting plate 52. When the workpiece is installed, the corners of the workpiece are positioned between adjacent limiting rods 54. The limiting rods 54 limit the workpiece. Under the synergistic limiting effect of the support plates 53 and the limiting rods 54 distributed at the four corners, the workpiece is fixed. The lifting block 51 is fixed to the guide rod 4 by locking screws 521. If the locking screws 521 are loose, the position of the lifting block 51 can be manually changed, and different mounting plates 52, support plates 53 and limiting rods 54 can be replaced to suit workpieces of different sizes.
[0026] In this embodiment, the platform frame 1 includes a parallel chassis 11, a supporting frustum 13, and a column 12 perpendicular to the chassis 11. The platform frame 1 is designed as a support frame, supporting the rotating outer frame 22. The supporting frustum 13 is a stepped inverted "T"-shaped structure. The outer surface of the bottom of the supporting frustum 13 has a concave annular groove. A limiting block 121 embedded in the annular groove is welded to the top of the column 12. The limiting block 121 is arc-shaped. The column 12 and the limiting block 121 support the supporting frustum 13 and limit the supporting frustum 13. The chassis 11 and the stabilizing box 21 are fixed by bolts. The supporting frustum 13 is connected to the first servo reduction motor 23 through bearings. The supporting frustum 13 and the rotating outer frame 22 are fixed by bolts. The first servo reduction motor 23 drives the supporting frustum 13 and the rotating outer frame 22 to rotate.
[0027] In this embodiment, the mounting plate 52 has a "U" shaped structure. A locking screw 521 for locking the lifting block 51 passes through the mounting plate 52. The lifting block 51 and the guide rod 4 are fixed by the locking screw 521. If the locking screw 521 is loose, the position of the lifting block 51 can be manually changed, and different mounting plates 52, support plates 53 and limiting rods 54 can be replaced to make it suitable for workpieces of different sizes.
[0028] In this embodiment, the surface of the support plate 53 is provided with equally spaced screw holes c. The limiting rod 54 is engaged with the screw holes c. The limiting rod 54 is perpendicular to the support plate 53. The distance between adjacent limiting rods 54 is the spacing H. The limiting rod 54 can be disassembled and installed to change the size of the spacing H, so as to meet the needs of fixing workpieces of different thicknesses.
[0029] In this embodiment, the center of the rotating inner frame 32 coincides with the center of the rotating outer frame 22. The distance between the top surface of the rotating inner frame 32 and the inner surface of the top of the rotating outer frame 22 is the spacing F. The spacing F is 2 cm larger than the width of the rotating inner frame 32, so as to satisfy the second servo motor 35 to drive the rotation of the rotating inner frame 32.
[0030] Working principle and usage process of this utility model:
[0031] When cleaning plate-shaped workpieces, the workpieces are installed inside the rotating inner frame 32;
[0032] If the locking screw 521 is loose, the position of the lifting block 51 can be manually changed, and different mounting plates 52, support plates 53 and limiting rods 54 can be replaced to make it suitable for workpieces of different sizes.
[0033] The corners of the workpiece are installed between adjacent limiting rods 54. After the workpiece is placed, the locking screw 521 is tightened to keep the workpiece limiting fixture assembly 5 stable.
[0034] When the first servo geared motor 23 starts, the first servo geared motor 23 drives the rotating outer frame 22 to rotate, causing the plate-shaped workpiece installed inside the rotating inner frame 32 to rotate along the b direction, which has the function of changing the angle of the workpiece.
[0035] When the second servo motor 35 is running, the second servo motor 35 drives the rotating outer frame 22 to rotate along the a direction, thereby achieving the purpose of flipping the rotating inner frame 32. This can achieve the purpose of flipping the rotating inner frame 32 and the workpiece even when the spraying range is limited, so that different surfaces of the workpiece can come into contact with the cleaning spray liquid.
[0036] In summary, this application provides a tooling platform design that can rotate workpieces. The workpiece is installed inside the rotating inner frame 32. When the first servo reduction motor 23 and the second servo motor 35 are running, the rotating outer frame 22 is rotated and the rotating inner frame 32 is flipped, so as to change the angle of the workpiece and flip the workpiece so that different surfaces of the workpiece can come into contact with the cleaning spray liquid.
[0037] Although embodiments of the present invention have been shown and described (see the detailed description above), it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made to these embodiments without departing from the principles and spirit of the present invention, the scope of which is defined by the appended claims and their equivalents.
Claims
1. A tooling platform with a rotating structure, characterized in that: include The rotating platform includes a platform frame (1), a stabilizing box (21) fixed to the platform frame (1) by bolts, a first servo geared motor (23) fixed inside the stabilizing box (21) by bolts, and a rotating outer frame (22) mounted on the platform frame (1) and fixed to the stabilizing box (21) by bolts. The rotating tooling frame includes a fixed box (31) fixed to the rotating outer frame (22) by bolts, a second servo motor (35) installed inside the fixed box (31), a rotating inner frame (32) installed inside the rotating outer frame (22), a first rotating shaft (33) and a second rotating shaft (34) installed on opposite surfaces of the rotating inner frame (32), and symmetrically distributed guide rods (4) are provided inside the rotating inner frame (32). The workpiece limiting fixture assembly (5) for fixing plate-shaped workpieces includes a lifting block (51) slidably sleeved on the outside of the guide rod (4), a mounting plate (52) installed on the outside of the lifting block (51), a support plate (53) vertically mounted on the mounting plate (52), and a limiting rod (54) fixedly connected to the support plate (53) by threaded engagement.
2. The tooling platform with a rotating structure according to claim 1, characterized in that: The platform frame (1) includes a parallel chassis (11) and columns (12) supporting the frustum (13) and perpendicular to the chassis (11).
3. The tooling platform with a rotating structure according to claim 2, characterized in that: The supporting frustum (13) is a stepped inverted "T" shaped structure. The outer surface of the bottom of the supporting frustum (13) is provided with a concave annular groove. The top of the column (12) is welded with a limiting block (121) embedded in the annular groove. The limiting block (121) is in the shape of an arc.
4. The tooling platform with a rotating structure according to claim 1, characterized in that: The mounting plate (52) has a "U" shaped structure, and the mounting plate (52) has a locking screw (521) for locking the lifting block (51) through it.
5. A tooling platform with a rotating structure according to claim 1, characterized in that: The support plate (53) has equally spaced screw holes c on its surface, and the limiting rod (54) engages with the screw holes c.
6. A tooling platform with a rotating structure according to claim 1, characterized in that: The limiting rod (54) is perpendicular to the support plate (53), and the distance between adjacent limiting rods (54) is the spacing H.
7. A tooling platform with a rotating structure according to claim 1, characterized in that: The center of the rotating inner frame (32) coincides with the center of the rotating outer frame (22), and the distance between the top surface of the rotating inner frame (32) and the inner surface of the top of the rotating outer frame (22) is the spacing F.