A rotating tooling table for parts
By employing a side clamping assembly and a rotating body structure in the tooling fixture, the position of the side push plate is automatically adjusted, solving the problems of cumbersome operation and high cost of existing tooling fixtures when clamping uneven parts, and realizing simple fixing and efficient operation of parts of any shape.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Patents(China)
- Current Assignee / Owner
- SHANDONG YIYANG IND TECH CO LTD
- Filing Date
- 2024-07-02
- Publication Date
- 2026-07-07
AI Technical Summary
Existing tooling fixtures are cumbersome to operate, costly, and have complex structures when clamping uneven parts, making it difficult to meet the fixing requirements of parts of arbitrary shapes.
The device employs side clamps within multiple storage slots. Through the cooperation of guide plates and side push plates, the position of the side push plates is automatically adjusted using a single force to fix uneven parts. Combined with a rotating body to provide power, the structure is simplified and the operating space is increased.
It enables easy fixing of parts of any shape, reduces costs, simplifies the operation process, and increases the operability.
Smart Images

Figure CN118438233B_ABST
Abstract
Description
Technical Field
[0001] This invention relates to the technical field of tooling fixtures, and in particular to a rotating tooling table for parts. Background Technology
[0002] In the field of machining, whether it is the processing of metal parts or product inspection, tooling fixtures are required. They are mainly tools or equipment that provide clamping, positioning and support for parts. Tooling fixtures are generally made of metal or other sturdy materials and are used to maintain the stability and precise position of workpieces during manufacturing, assembly and processing. The existing tooling fixture structure is mainly a cylinder and a clamping plate mounted on the cylinder. The cylinder pushes the clamping plate to clamp and fix the parts in a linear manner. However, when the clamping surface of the parts is not flat, multiple sets of cylinders are required for fixation. This not only makes the clamping operation more cumbersome, but also has a large cost, complex structure, small operating space and is not convenient for placing and removing parts. Summary of the Invention
[0003] To solve the above-mentioned technical problems, the present invention provides a rotating tooling table for parts, the specific technical solution of which is as follows:
[0004] A component rotating tooling table includes a placement table and multiple storage slots formed on the placement table. The multiple storage slots are arranged in a ring, and the length direction of the storage slots is along the radial direction of the ring. Each storage slot has a sliding opening at its bottom, and a side clamping assembly for clamping the component is slidably disposed in the sliding opening.
[0005] The side clamp assembly consists of a movable seat, an adjusting plate, a guide plate, and a side push plate. There are two adjusting plates, two guide plates, and two side push plates. The movable seat is slidably installed in the sliding opening and is used to adjust the distance between the side push plate and the component. The two adjusting plates are located on the front and rear sides of the upper surface of the movable seat, respectively. The adjusting plates are rotatably installed on the movable seat and are used to switch the side push plate between a storage position and a working position. The storage position of the side push plate is located in the storage slot. The guide plate is vertical, and the side push plate is horizontal. Both guide plates are located between the two side push plates, and both ends of the guide plates are rotatably connected to the two side push plates. One guide plate is located between the two adjusting plates and rotates relative to the two adjusting plates. The side push plate is used to press and fix the component.
[0006] Furthermore, a U-shaped channel is provided inside the side push plate, with both openings of the U-shaped channel facing the component direction. A push rod is slidably inserted into each opening, and the two push rods are connected by multiple ball bearings located inside the U-shaped channel.
[0007] Furthermore, the movable seat has a long opening that extends vertically through the entire seat. The length of the long opening is along the moving direction of the movable seat. Two adjusting plates are located on the front and rear sides of the long opening, respectively. A slider and a vertical rod that slides through the slider are slidably arranged inside the long opening. The vertical rod is vertical and connected to a side push plate.
[0008] Furthermore, the placement platform is provided with a rotating body, which is used to provide power for the movement of the movable seat and the rotation of the adjusting plate;
[0009] The rotating body includes a fixed sleeve, a sleeve, and a movable column. The fixed sleeve is inserted and fixed on the placement platform. An annular groove and two straight grooves are opened on the inner wall of the fixed sleeve. The annular groove is located at the top of the straight grooves and is connected to each other. The sleeve slides vertically inside the fixed sleeve, and two clamping plates are provided on the outer wall of the sleeve. When the clamping plates are in the straight grooves, the clamping plates and the sleeve move vertically. When the clamping plates are in the annular grooves, the clamping plates and the sleeve rotate.
[0010] The sleeve has a spiral groove, the moving column is vertically slidably installed inside the sleeve, and the outer wall of the moving column is provided with a pusher that can slide in the spiral groove. When the moving column moves up and down, the moving column exerts a force on the sleeve through the pusher and the spiral groove.
[0011] The sleeve and the movable seat are equipped with a transmission structure. When the sleeve rotates, the movable seat moves within the sliding port through the transmission structure. The sleeve and the adjusting plate are equipped with a connecting arm structure. When the sleeve moves up and down, the adjusting plate drives the side push plate to switch between the storage position and the working position through the connecting arm structure.
[0012] Furthermore, the connecting arm structure includes a connecting ring rotatably fitted on the outer wall of the sleeve and multiple extension arms mounted on the connecting ring. The extension arms are along the radial direction of the connecting ring, and each extension arm is slidably equipped with an adjusting sleeve. The adjusting sleeve and the adjusting plate are connected by a first connecting rod and a second connecting rod. The first connecting rod is vertical and the second connecting rod is inclined.
[0013] Furthermore, a first bevel gear is provided on the outer wall of the sleeve, and a second bevel gear meshes with the first bevel gear. A threaded rod is screwed into the movable seat, and the threaded rod is connected to the second bevel gear in a transmission connection.
[0014] Furthermore, the first bevel gear is rotatably mounted on the fixed sleeve, and multiple synchronization grooves are opened on the outer wall of the sleeve. Multiple synchronization ridges are provided on the inner wall of the inner hole of the first bevel gear, and the synchronization ridges slide within the synchronization grooves.
[0015] Furthermore, the extension arm is connected to the movable column by a leaf spring, and the bottom of the movable column is powered by a cylinder.
[0016] The advantages of this invention are:
[0017] By applying a single force to the two guide plates, the two guide plates automatically cooperate with the uneven surfaces of the parts to adjust the position of the two side push plates, thereby enabling the two side push plates to automatically adapt to the shape of the parts, facilitating effective fixation of the parts, and this fixing method can meet the fixing requirements of parts of any shape.
[0018] By using a single force to power the two side push plates, the structure can be greatly simplified, operation can be made easier, costs can be saved, the operating space can be increased, and the placement and removal of parts can be facilitated. Attached Figure Description
[0019] To more clearly illustrate the technical solutions in the embodiments of the present invention or the prior art, the drawings used in the description of the embodiments or the prior art will be briefly introduced below. Obviously, the drawings described below are only some embodiments recorded in the present invention. For those skilled in the art, other drawings can be obtained based on these drawings without creative effort.
[0020] Figure 1 This is a schematic diagram of the structure of the present invention;
[0021] Figure 2 yes Figure 1 Mid-top view of the structure;
[0022] Figure 3 yes Figure 1 Schematic diagram of the structure of multiple sets of side clamps;
[0023] Figure 4 yes Figure 3 Enlarged structural diagram of the middle side clamp;
[0024] Figure 5 yes Figure 4 Enlarged left view of the center guide plate structure;
[0025] Figure 6 yes Figure 5 Schematic diagram of the structure of the middle side push plate (section view and top view);
[0026] Figure 7 yes Figure 3 Enlarged structural diagram of the central fixed sleeve;
[0027] Figure 8 yes Figure 7 Schematic diagram of the cross-sectional structure of the fixed sleeve and the sleeve;
[0028] Reference numerals: 1. Placement platform; 2. Movable seat; 3. Adjusting plate; 4. Guide plate; 5. Side push plate; 6. Ball bearing; 7. Top rod; 8. Slider; 9. Vertical rod; 10. Fixing sleeve; 11. Annular groove; 12. Straight groove; 13. Sleeve; 14. Clamping plate; 15. Spiral groove; 16. Moving column; 17. Pulley; 18. Connecting ring; 19. Extension arm; 20. Adjusting sleeve; 21. First connecting rod; 22. Second connecting rod; 23. First bevel gear; 24. Second bevel gear; 25. Threaded rod; 26. Leaf spring; 27. Cylinder. Detailed Implementation
[0029] The technical solutions of the present invention will be clearly and completely described below with reference to the accompanying drawings of the embodiments of the present invention. Obviously, the described embodiments are only some embodiments of the present invention, and not all embodiments.
[0030] In the description of this invention, it should be noted that the orientations or positional relationships indicated by terms such as "center", "up", "down", "left", "right", "vertical", "horizontal", "inner", and "outer" are based on the orientations or positional relationships shown in the accompanying drawings. They are only for the convenience of describing this invention and simplifying the description, and do not indicate or imply that the device or element referred to must have a specific orientation, or be constructed and operated in a specific orientation. Therefore, they should not be construed as limitations on this invention.
[0031] In the description of this invention, it should be noted that, unless otherwise explicitly specified and limited, the terms "installation," "connection," and "linking" should be interpreted broadly. For example, they can refer to fixed connections, detachable connections, or integral connections; they can refer to mechanical connections or electrical connections; they can refer to direct connections or indirect connections through an intermediate medium; and they can refer to the internal communication between two components. Those skilled in the art can understand the specific meaning of the above terms in this invention based on the specific circumstances. This embodiment is written in a progressive manner.
[0032] like Figures 1 to 8 As shown, a component rotating tooling table of the present invention includes a placement table 1 and a plurality of storage slots opened on the placement table 1. The plurality of storage slots are arranged in a ring, and the length direction of the storage slots is along the radial direction of the ring. A sliding opening is opened at the bottom of each storage slot, and a side clamping group for clamping the component is slidably arranged in the sliding opening.
[0033] The side clamp assembly consists of a movable seat 2, an adjusting plate 3, a guide plate 4, and a side push plate 5. There are two adjusting plates 3, two guide plates 4, and two side push plates 5. The movable seat 2 is slidably installed in the sliding opening and is used to adjust the distance between the side push plate 5 and the component. The two adjusting plates 3 are located on the front and rear sides of the upper surface of the movable seat 2, respectively. The adjusting plates 3 are rotatably installed on the movable seat 2 and are used to switch the side push plate 5 between a storage position and a working position. The storage position of the side push plate 5 is located in the storage slot. The guide plate 4 is vertical, and the side push plate 5 is horizontal. Both guide plates 4 are located between the two side push plates 5, and both ends of the guide plates 4 are rotatably connected to the two side push plates 5. One guide plate 4 is located between the two adjusting plates 3 and rotates relative to the two adjusting plates 3. The side push plate 5 is used to press and fix the component.
[0034] In detail, multiple sets of side clamps are arranged in a ring. When it is necessary to fix the parts, the multiple sets of side clamps approach each other and squeeze the parts between them to complete the fixing work. The storage slot on the placement platform 1 can be used to store the adjustment plate 3, guide plate 4, and side push plate 5 in the tilted state. In this way, when the parts are placed on the placement platform 1 or when the parts on the placement platform 1 are removed, the adjustment plate 3, guide plate 4, and side push plate 5 can be hidden, making the working surface of the placement platform 1 more spacious, so as to facilitate the placement and removal of parts. The movable base 2 can provide the installation position for the adjustment plate 3, guide plate 4, and side push plate 5. When the movable base 2 moves, it can push the side push plate 5 towards the parts and squeeze and fix the parts through the side push plate 5. The adjustment plate 3 can provide support for the guide plate 4 and side push plate 5. When the adjustment plate 3 is tilted, the adjustment plate 3, guide plate 4, and side push plate 5 are in an idle state. When vertical, the adjusting plate 3, guide plate 4, and side push plate 5 are in working condition, allowing the side push plate 5 to switch between the storage position and the working position. One end of the adjusting plate 3 is rotatably connected to the moving base 2, and the other end of the adjusting plate 3 is rotatably connected to the side wall of one of the two guide plates 4. This connection can be achieved through a rotating shaft and a connecting sleeve. The two guide plates 4 and the two side push plates 5 can form a parallelogram. When the two side push plates 5 come into contact with the uneven surface of the component, the two side push plates 5 move relative to each other with the two guide plates 4 as guides. In this way, the two side push plates 5 can simultaneously come into contact with the uneven surface of the component, while the guide plates 4 only need to be tilted. This achieves the clamping of irregular components. This method only requires moving the moving base 2. Since the two side push plates 5 are guided by the two guide plates 4, the side push plates 5 remain in a horizontal state, thus achieving the guiding effect of the side push plates 5.
[0035] By applying a single force to the two guide plates 4, the two guide plates 4 automatically cooperate with the uneven surfaces of the parts to adjust the position of the two side push plates 5. This allows the two side push plates 5 to automatically adapt to the shape of the parts, facilitating effective fixation of the parts. This fixing method can meet the fixing requirements of parts of any shape. At the same time, by providing power to the two side push plates 5 with a single force, the structure can be greatly simplified, operation can be made easier, costs can be saved, the operating space can be increased, and the placement and removal of parts can be facilitated.
[0036] Furthermore, a U-shaped channel is provided in the side push plate 5, with both openings of the U-shaped channel facing the component direction. A push rod 7 is slidably inserted in each opening, and the two push rods 7 are connected by multiple balls 6 located in the U-shaped channel.
[0037] In detail, multiple ball bearings 6 are slidably arranged inside the U-shaped channel. One end of each of the two push rods 7 is located in one of the two openings of the U-shaped channel, and the other end of each push rod 7 extends to the outside of the U-shaped channel. When one push rod 7 moves, it can press the other push rod 7 through the multiple ball bearings 6, thereby connecting the two push rods 7 through the multiple ball bearings 6. When fixing the parts, the side push plate 5 moves towards the parts, and the ends of the two push rods 7 can contact the outer wall of the parts. When the outer wall of the parts is uneven, the extension length of the two push rods 7 on the side push plate 5 changes, that is, the two push rods 7 are misaligned. The two push rods 7 press against each other through the multiple ball bearings 6, thereby allowing the side push plate 5 to fix the uneven parts through the two push rods 7 on it.
[0038] It should be noted that, in order to prevent the push rod 7 from disengaging from the U-shaped channel when idle, a retaining edge is provided at the opening of the U-shaped channel, and a retaining edge is provided at the end of the push rod 7 inside the U-shaped channel to limit the push rod 7.
[0039] By combining the two side push plates 5 on the side clamp assembly and the two push rods 7 on each side push plate 5, automatic adjustment in the vertical and longitudinal directions on the vertical plane can be achieved, thus facilitating the effective fixing of irregular parts.
[0040] Furthermore, the movable seat 2 has a long opening that extends vertically through the entire structure. The length of the long opening is along the moving direction of the movable seat 2. Two adjusting plates 3 are located on the front and rear sides of the long opening, respectively. A slider 8 and a vertical rod 9 that slides through the slider 8 are respectively located inside the long opening. The vertical rod 9 is vertical and is connected to a side push plate 5.
[0041] In detail, to ensure that the side push plate 5 remains horizontal when moving, it can be guided by a long opening, a slider 8, and a vertical rod 9. Combined with the function of the two guide plates 4, this ensures that both side push plates 5 remain horizontal at all times. This allows the end of the push rod 7 to face the component vertically and effectively compress it. At the same time, when storing, it is convenient to hide the side push plate 5 and the push rod 7 horizontally in the storage slot, reducing the space occupied by the side push plate 5 and the push rod 7 in the storage slot.
[0042] Furthermore, the placement platform 1 is provided with a rotating body, which is used to provide power for the movement of the movable seat 2 and the rotation of the adjusting plate 3;
[0043] The rotating body includes a fixed sleeve 10, a sleeve 13, and a movable column 16. The fixed sleeve 10 is inserted and fixed on the placement platform 1. An annular groove 11 and two straight grooves 12 are opened on the inner wall of the fixed sleeve 10. The annular groove 11 is located at the top of the straight grooves 12 and is connected to each other. The sleeve 13 slides vertically inside the fixed sleeve 10, and two clamping plates 14 are provided on the outer wall of the sleeve 13. When the clamping plates 14 are in the straight grooves 12, the clamping plates 14 and the sleeve 13 move vertically. When the clamping plates 14 are in the annular grooves 11, the clamping plates 14 and the sleeve 13 rotate.
[0044] The sleeve 13 has a spiral groove 15 inside, the moving column 16 is vertically slidably installed inside the sleeve 13, and the outer wall of the moving column 16 is provided with a deflector 17 that can slide in the spiral groove 15. When the moving column 16 moves up and down, the moving column 16 exerts a force on the sleeve 13 through the deflector 17 and the spiral groove 15.
[0045] The sleeve 13 and the movable seat 2 are provided with a transmission structure. When the sleeve 13 rotates, the movable seat 2 moves in the sliding mouth through the transmission structure. The sleeve 13 and the adjusting plate 3 are provided with a connecting arm structure. When the sleeve 13 moves up and down, the adjusting plate 3 drives the side push plate 5 to switch between the storage position and the working position through the connecting arm structure.
[0046] In detail, when the clamping plate 14 is in the straight groove 12, if the moving column 16 moves, the moving column 16 can only push the sleeve 13 to move up and down through the deflector 17. When the clamping plate 14 is in the annular groove 11, if the moving column 16 moves upward, the moving column 16 can only push the sleeve 13 to rotate through the deflector 17 and the spiral groove 15. At this time, the clamping plate 14 moves in the annular groove 11. This realizes that the moving column 16 can move up and down and rotate the sleeve 13.
[0047] During operation, the two clamping plates 14 are located on the lower side inside the two straight grooves 12 respectively. At this time, the side push plate 5 is in the storage state. When the part is placed on the placement platform 1, the moving column 16 is pushed to move upward. At this time, due to the restriction of the straight groove 12, the moving column 16 pushes the sleeve 13 upward through the deflector 17 and the spiral groove 15. The sleeve 13 adjusts the side push plate 5 from the storage position to the working position through the connecting arm structure. When the clamping plate 14 slides from the straight groove 12 into the annular groove 11, the sleeve 13 stops moving up and down. At this time, the moving column 16 pushes the sleeve 13 to rotate with the help of the deflector 17 and the spiral groove 15. That is, the deflector 17 slides in the spiral groove 15. The sleeve 13 drives the moving seat 2 to move through the transmission structure. The moving seat 2 pushes the side push plate 5 to move towards the part and squeezes and fixes the part.
[0048] By adopting the above structural form, the fixing of parts can be made simpler and easier to operate.
[0049] Furthermore, the connecting arm structure includes a connecting ring 18 rotatably fitted on the outer wall of the sleeve 13 and a plurality of extension arms 19 mounted on the connecting ring 18. The extension arms 19 are radially arranged along the connecting ring 18, and each extension arm 19 is slidably equipped with an adjusting sleeve 20. The adjusting sleeve 20 is connected to the adjusting plate 3 through a first connecting rod 21 and a second connecting rod 22. The first connecting rod 21 is vertical and the second connecting rod 22 is inclined.
[0050] In detail, one end of the second connecting rod 22 is rotatably connected to the adjusting plate 3, and the other end is rotatably connected to the first connecting rod 21. The second connecting rod 22 is tilted away from the axis of the fixed sleeve 10. This makes it convenient for the second connecting rod 22 to pull the adjusting plate 3 to rotate when it moves up and down. This avoids the second connecting rod 22 not being able to exert an effective force on the adjusting plate 3 when the second connecting rod 22 and the adjusting plate 3 are both vertical and collinear. When the sleeve 13 moves up and down, the sleeve 13 can drive the adjusting plate 3 to rotate on the moving seat 2 through the connecting ring 18, the extension arm 19, the adjusting sleeve 20, the first connecting rod 21 and the second connecting rod 22, thereby adjusting the position of the side push plate 5. When the moving seat 2 moves, the adjusting sleeve 20 can slide on the extension arm 19. When the sleeve 13 rotates, it rotates relative to the connecting ring 18.
[0051] Furthermore, a first bevel gear 23 is provided on the outer wall of the sleeve 13, and a second bevel gear 24 is meshed and driven on the first bevel gear 23. A threaded rod 25 is screwed through the movable seat 2, and the threaded rod 25 is connected to the second bevel gear 24 in a driving connection.
[0052] In detail, the movable seat 2 extends downward toward the side wall of the fixed sleeve 10. This part can be used to insert the threaded rod 25. The threaded rod 25 is coaxially connected with the second bevel gear 24. When the sleeve 13 rotates, the sleeve 13 can drive the first bevel gear 23 to rotate synchronously. The first bevel gear 23 drives the threaded rod 25 to rotate through the second bevel gear 24. The threaded rod 25 pushes the movable seat 2 to move, thereby providing it with power.
[0053] Furthermore, the first bevel gear 23 is rotatably mounted on the fixed sleeve 10, and multiple synchronization grooves are opened on the outer wall of the sleeve 13. Multiple synchronization ridges are provided on the inner wall of the inner hole of the first bevel gear 23, and the synchronization ridges slide within the synchronization grooves.
[0054] In detail, the first bevel gear 23 is mounted on the fixed sleeve 10, and the threaded rod 25 is connected to the fixed sleeve 10 by a fixed plate. When the sleeve 13 rotates, the first bevel gear 23 can be driven to rotate synchronously through the synchronous ridge and the synchronous groove. When the sleeve 13 moves up and down, the synchronous ridge slides in the synchronous groove, so that the up and down movement of the sleeve 13 will not interfere with the threaded rod 25.
[0055] Furthermore, the extension arm 19 is connected to the moving column 16 by a leaf spring 26, and the bottom of the moving column 16 is powered by a cylinder 27.
[0056] In detail, the cylinder 27 can push the moving column 16 to move up and down. By setting the leaf spring 26, the leaf spring 26 can generate a repulsive force that separates the sleeve 13 and the moving column 16. The deflector 17 is locked at the end of the spiral groove 15. When the moving column 16 moves upward, the moving column 16 pushes the sleeve 13 to move upward on the fixed sleeve 10 through the deflector 17 and the leaf spring 26. When the clamping plate 14 moves into the annular groove 11, the sleeve 13 stops moving, the moving column 16 continues to move, and the leaf spring 26 undergoes elastic deformation.
[0057] When the parts need to be removed, the sleeve 13 and the moving column 16 move in opposite directions, and the clamping plate 14 stays in the annular groove 11 and rotates. At this time, the deflector 17 moves toward the end of the spiral groove 15. When the deflector 17 moves to the end of the spiral groove 15, the clamping plate 14 moves to the top of the straight groove 12. The deflector 17 pulls the sleeve 13 downward, and the sleeve 13 drives the clamping plate 14 to slide into the straight groove 12. This realizes the smooth reverse movement of the sleeve 13 and the moving column 16. That is, when the deflector 17 has not reached the specified position, due to the action of the leaf spring 26, a repulsive force is generated on the sleeve 13 and the moving column 16 to separate them. Therefore, the clamping plate 14 can pass the top of the straight groove 12 multiple times but cannot enter the straight groove 12. This avoids the situation where there is no connection between the sleeve 13 and the moving column 16, and the deflector 17 has not yet moved to the specified position in the spiral groove 15, while the clamping plate 14 moves to the top of the straight groove 12 and directly enters the straight groove 12 downward.
[0058] The above description is only a preferred embodiment of the present invention. It should be noted that for those skilled in the art, several improvements and modifications can be made without departing from the technical principles of the present invention, and these improvements and modifications should also be considered within the scope of protection of the present invention.
Claims
1. A rotating tooling table for parts, characterized in that, It includes a placement platform (1) and multiple storage slots opened on the placement platform (1). The multiple storage slots are arranged in a ring, and the length direction of the storage slots is along the radial direction of the ring. Each storage slot has a sliding opening at the bottom, and a side clamping group for clamping the parts is slidably arranged in the sliding opening. The side clamp assembly consists of a movable seat (2), an adjusting plate (3), a guide plate (4), and a side push plate (5). The number of adjusting plates (3), guide plates (4), and side push plates (5) are all two. The movable seat (2) is slidably installed in the sliding opening and is used to adjust the distance between the side push plate (5) and the parts. The two adjusting plates (3) are located on the front and rear sides of the upper surface of the movable seat (2). The adjusting plates (3) are rotatably installed on the movable seat (2) and are used to switch the side push plate (5) between the storage position and the working position. The storage position of the side push plate (5) is located in the storage slot. The guide plate (4) is vertical and the side push plate (5) is horizontal. The two guide plates (4) are located between the two side push plates (5), and the two ends of the guide plate (4) are rotatably connected to the two side push plates (5). One of the guide plates (4) is located between the two adjusting plates (3) and rotates relative to the two adjusting plates (3). The side push plate (5) is used to squeeze and fix the parts. The movable seat (2) has a long opening that runs vertically through it. The length of the long opening is along the moving direction of the movable seat (2). Two adjusting plates (3) are located on the front and rear sides of the long opening, respectively. A slider (8) and a vertical rod (9) that slides through the slider (8) are provided inside the long opening. The vertical rod (9) is vertical and connected to a side push plate (5). The placement platform (1) is provided with a rotating body, which is used to provide power for the movement of the movable seat (2) and the rotation of the adjusting plate (3); The rotating body includes a fixed sleeve (10), a sleeve (13), and a movable column (16). The fixed sleeve (10) is inserted and fixed on the placement platform (1). An annular groove (11) and two straight grooves (12) are opened on the inner wall of the fixed sleeve (10). The annular groove (11) is located at the top of the straight grooves (12) and is connected to each other. The sleeve (13) slides vertically inside the fixed sleeve (10). Two clamping plates (14) are provided on the outer wall of the sleeve (13). When the clamping plate (14) is in the straight groove (12), the clamping plate (14) and the sleeve (13) move vertically. When the clamping plate (14) is in the annular groove (11), the clamping plate (14) and the sleeve (13) rotate. The sleeve (13) has a spiral groove (15) inside. The moving column (16) is vertically slidably installed inside the sleeve (13). The outer wall of the moving column (16) is provided with a lever (17) that can slide inside the spiral groove (15). When the moving column (16) moves up and down, the moving column (16) exerts a force on the sleeve (13) through the lever (17) and the spiral groove (15). Among them, a transmission structure is provided between the sleeve (13) and the movable seat (2). When the sleeve (13) rotates, the movable seat (2) moves in the sliding mouth through the transmission structure. A connecting arm structure is provided between the sleeve (13) and the adjusting plate (3). When the sleeve (13) moves up and down, the adjusting plate (3) drives the side push plate (5) to switch between the storage position and the working position through the connecting arm structure. The connecting arm structure includes a connecting ring (18) rotatably fitted on the outer wall of the sleeve (13) and multiple extension arms (19) mounted on the connecting ring (18). The extension arms (19) are along the radial direction of the connecting ring (18). Each extension arm (19) is slidably equipped with an adjusting sleeve (20). The adjusting sleeve (20) is connected to the adjusting plate (3) through a first connecting rod (21) and a second connecting rod (22). The first connecting rod (21) is vertical and the second connecting rod (22) is inclined. The sleeve (13) has a first bevel gear (23) on its outer wall, and a second bevel gear (24) meshes with the first bevel gear (23). A threaded rod (25) is screwed into the movable seat (2), and the threaded rod (25) is connected to the second bevel gear (24) in a transmission connection.
2. The component rotating fixture according to claim 1, characterized in that, The side push plate (5) has a U-shaped channel. Both openings of the U-shaped channel face the component direction. A push rod (7) is slidably inserted in each opening. The two push rods (7) are connected by multiple balls (6) located in the U-shaped channel.
3. A rotating tooling table for parts according to claim 2, characterized in that, The first bevel gear (23) is rotatably mounted on the fixed sleeve (10). Multiple synchronization grooves are opened on the outer wall of the sleeve (13). Multiple synchronization ridges are provided on the inner wall of the inner hole of the first bevel gear (23). The synchronization ridges slide within the synchronization grooves.
4. A rotating tooling table for parts according to claim 3, characterized in that, The extension arm (19) is connected to the movable column (16) by a leaf spring (26), and the bottom of the movable column (16) is powered by a cylinder (27).