A machining fixed support platform
By designing an electric telescopic rod and gear structure with multi-angle clamping and height adjustment, the problem of poor adaptability of existing fixed support platforms has been solved, enabling flexible adaptation to various workpieces and machine tools, and reducing replacement costs and time.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- SUZHOU SHUANGDE RUI PRECISION MASCH CO LTD
- Filing Date
- 2025-08-06
- Publication Date
- 2026-07-10
AI Technical Summary
Existing fixed support platforms are usually designed for specific workpieces and are difficult to adapt to various machine tools and workpiece shapes. This results in the need to re-customize tooling when changing products, increasing costs and changeover time, and they cannot meet various processing needs.
A machining fixed support platform was designed, which adopts a variety of electric telescopic rods and gear structures to realize multi-angle clamping and height adjustment of workpieces, and adapts to the use of workpieces of different shapes and machine tools.
It enables adaptation to various workpiece shapes and machine tools, reducing the cost and time of tooling changes and improving processing flexibility and efficiency.
Smart Images

Figure CN224476176U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of machining platform technology, and in particular to a machining fixed support platform. Background Technology
[0002] Using a fixed support platform when machining plastic and wood products can prevent surface dents or dimensional deviations caused by excessive cutting or clamping forces, and also enables efficient batch processing. The use of a fixed support platform in machining ensures machining accuracy, efficiency, and safety.
[0003] However, common fixed support platforms are often designed for specific workpieces, and changing products requires custom-made tooling, increasing costs and changeover time. Furthermore, common fixed support platforms cannot perform corresponding operations during machining; they can only fix the workpiece in place, making them incompatible with various machine tools.
[0004] Therefore, this application provides a machining fixed support platform to solve the problems mentioned in the background art. Utility Model Content
[0005] The purpose of this invention is to address the shortcomings of existing technologies by proposing a machining fixed support platform. This device can be adapted to workpieces of more shapes and to more machine tools.
[0006] To achieve the above objectives, the present invention provides the following technical solution:
[0007] A machining fixed support platform includes a shell, a bearing plate, and a support plate. A support shell is fixedly disposed on the lower end face of the shell. First support blocks are fixedly disposed on both sides of the upper end face of the bearing plate. Drive motors are fixedly disposed on both sides of the outer walls of the two first support blocks. Connecting blocks are fixedly connected to the output ends of the two drive motors. First electric telescopic rods are fixedly disposed on both sides of the outer walls of the two connecting blocks. First clamping members are fixedly connected to the output ends of the two first electric telescopic rods. First grooves are formed on both sides of the outer walls of the two first clamping members. Second support blocks are fixedly disposed on the front and rear ends of the upper end face of the bearing plate. Second electric telescopic rods are fixedly disposed on the front and rear ends of the two second support blocks. Second clamping members are fixedly connected to the output ends of the two second electric telescopic rods. Second grooves are formed on the front and rear ends of the two second clamping members. A support column is fixedly disposed on the lower end face of the bearing plate.
[0008] Furthermore, a third electric telescopic rod is fixedly installed inside the support shell, and the middle part of the lower end face of the support plate is fixedly connected to the upper output end of the third electric telescopic rod.
[0009] Furthermore, a power-off braking motor is fixedly installed on the upper surface of the support plate near the outer wall, a first gear is fixedly connected to the upper surface of the power-off braking motor, a bearing seat is fixedly installed in the middle of the upper surface of the support plate, a second gear is fixedly connected to the upper surface of the outer wall of the support column, and the lower surface of the outer wall of the support column is rotatably installed inside the bearing seat, with the first gear meshing with the second gear.
[0010] Furthermore, the support plate is slidably embedded inside the outer casing at the upper end.
[0011] Furthermore, the support plate is slidably disposed inside the outer casing and located at the lower end of the bearing plate.
[0012] Furthermore, three support legs are evenly spaced around the lower end face of the outer shell.
[0013] Furthermore, both of the first clamping members are cylindrical and both of the first grooves are semi-cylindrical, and both of the second clamping members are rectangular and both of the second grooves are isosceles trapezoidal.
[0014] This utility model has the following beneficial effects:
[0015] 1. This utility model proposes a machining fixed support platform. Machining is commonly used for processing plastic and wood products. This device can horizontally or vertically clamp cylindrical workpieces by rotating two first-section clamping members. Two second-section clamping members can clamp polygonal workpieces of different shapes, such as rectangles, rhombuses, and triangles.
[0016] 2. The machining fixed support platform proposed in this utility model can be used to adjust the workpiece, bearing seat, support column, second gear, bearing plate and components on the bearing plate by activating the third electric telescopic rod to raise or lower the workpiece when the workpiece is too short or the tool length is insufficient. Attached Figure Description
[0017] Figure 1 This is a top view of the entire utility model;
[0018] Figure 2 This is a bottom view of the overall design of this utility model;
[0019] Figure 3 This is a schematic diagram of the bearing plate connection structure of this utility model;
[0020] Figure 4 This is a schematic diagram of the support plate connection structure of this utility model.
[0021] Legend:
[0022] 1. Outer shell; 2. Bearing plate; 3. First support block; 4. Second support block; 5. First clamping component; 6. Second clamping component; 7. First groove; 8. Second groove; 9. First electric telescopic rod; 10. Second electric telescopic rod; 11. Support column; 12. Third electric telescopic rod; 13. Support plate; 14. Bearing seat; 15. Power-off braking motor; 16. First gear; 17. Second gear; 18. Support shell; 19. Drive motor; 20. Connecting block. Detailed Implementation
[0023] 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.
[0024] Reference Figure 1 - Figure 4 This utility model provides an embodiment of a machining fixed support platform, comprising a shell 1, a bearing plate 2, and a support plate 13. A support shell 18 is fixedly disposed on the lower end face of the shell 1. First support blocks 3 are fixedly disposed on both sides of the upper end face of the bearing plate 2. Drive motors 19 are fixedly disposed on both sides of the outer walls of the two first support blocks 3. Connecting blocks 20 are fixedly connected to the output ends of the two drive motors 19. First electric telescopic rods 9 are fixedly disposed on both sides of the outer walls of the two connecting blocks 20. First clamping members 5 are fixedly connected to the output ends of the two first electric telescopic rods 9. First grooves 7 are formed on both sides of the outer walls of the two first clamping members 5. Second support blocks 4 are fixedly disposed on both the front and rear ends of the upper end face of the bearing plate 2. Second electric telescopic rods 10 are fixedly disposed on the front and rear ends of the two second support blocks 4. Second clamping members 6 are fixedly connected to the output ends of the two second electric telescopic rods 10. Second grooves 8 are formed on the front and rear ends of the two second clamping members 6. Support columns 11 are fixedly disposed on the lower end face of the bearing plate 2. Three legs are evenly spaced around the lower end face of the shell 1.
[0025] Specifically, when using this device to clamp polygonal workpieces, the two second electric telescopic rods 10 can be activated to drive the two second clamping members 6 to clamp them. When clamping a cylinder horizontally, the two first electric telescopic rods 9 can be activated to drive the two first clamping members 5 to clamp the cylindrical workpiece. When clamping a vertical cylindrical workpiece, the two drive motors 19 can be activated to drive the two connecting blocks 20 to rotate the two first electric telescopic rods 9 and the two first clamping members 5 clockwise by 90°, and then the two first electric telescopic rods 9 can be activated to drive the two first clamping members 5 to clamp the cylindrical workpiece. When using this device, if the workpiece clamping height is too low or the tool distance is insufficient, the third electric telescopic rod 12 can be activated to raise and adjust the height of the support plate 13, bearing seat 14, power-off brake motor 15, first gear 16, support column 11, second gear 17, bearing plate 2, two first support blocks 3, two second support blocks 4, two drive motors 19, two connecting blocks 20, two first electric telescopic rods 9, two first clamping parts 5, two second electric telescopic rods 10, two second clamping parts 6, and the workpiece. During use, the workpiece can also be adjusted according to the required machining surface. By activating the power-off brake motor 15, the first gear 16 is driven, and the first gear 16 meshes with the second gear 17, causing the bearing plate 2, two first support blocks 3, two second support blocks 4, two drive motors 19, two connecting blocks 20, two first electric telescopic rods 9, two first clamping parts 5, two second electric telescopic rods 10, two second clamping parts 6, and the workpiece to rotate. The support shell 18 supports the third electric telescopic rod 12 to prevent displacement. The two first support blocks 3 and two second support blocks 4 allow the two first clamping members 5 and two second clamping members 6 to move during clamping. Two drive motors 19 drive the two connecting blocks 20, the two first electric telescopic rods 9, and the two first clamping members 5 to rotate. The two connecting blocks 20 connect the two first electric telescopic rods 9 to the two drive motors 19. The two first electric telescopic rods 9 drive the two first clamping members 5 to clamp the workpiece. The two second electric telescopic rods 10 drive the two second clamping members 6 to clamp the workpiece. The support column 11 supports the bearing plate 2, allowing the first gear 16 and the second gear 17 to mesh.
[0026] Reference Figure 3 , Figure 4A third electric telescopic rod 12 is fixedly installed inside the support shell 18. The middle part of the lower end face of the support plate 13 is fixedly connected to the upper output end of the third electric telescopic rod 12. A power-off braking motor 15 is fixedly installed on the outer wall side of the upper end face of the support plate 13. A first gear 16 is fixedly connected to the upper end face of the power-off braking motor 15. A bearing seat 14 is fixedly installed in the middle part of the upper end face of the support plate 13. A second gear 17 is fixedly connected to the upper end face of the outer wall of the support column 11. The lower end face of the outer wall of the support column 11 is rotatably installed inside the bearing seat 14, and the first gear 16 and the second gear 17 mesh.
[0027] Specifically, the support plate 13, bearing seat 14, power-off brake motor 15, first gear 16, support column 11, second gear 17, bearing plate 2, two first support blocks 3, two second support blocks 4, two drive motors 19, two connecting blocks 20, two first electric telescopic rods 9, two first clamping parts 5, two second electric telescopic rods 10, and two second clamping parts 6 can be raised via the third electric telescopic rod 12. The power-off brake motor 15 can drive the first gear 16 to rotate the second gear 17. The bearing seat 14 can limit the displacement of the support column 11, allowing it to rotate only in its original position, while also reducing friction.
[0028] Reference Figure 3 , Figure 4 The carrier plate 2 is slidably embedded inside the upper part of the outer shell 1, and the support plate 13 is slidably disposed inside the outer shell 1 and located at the lower end of the carrier plate 2.
[0029] Specifically, when the third electric telescopic rod 12 is activated, the bearing plate 2 will slide up and down inside the outer shell 1 at the upper end, while the support plate 13 will slide up and down inside the outer shell 1.
[0030] Reference Figure 1 , Figure 3 Both first clamping members 5 are cylindrical and both first grooves 7 are semi-cylindrical, and both second clamping members 6 are rectangular and both second grooves 8 are isosceles trapezoidal.
[0031] Specifically, the first clamping member 5 is semi-cylindrical so that it can rotate in place, the first groove 7 is semi-cylindrical so that it can clamp cylindrical workpieces, and the second clamping member 6 is isosceles trapezoidal so that it can clamp various polygonal workpieces.
[0032] Working principle: When using this device to clamp polygonal workpieces, the two second electric telescopic rods 10 are activated to drive the two second clamping components 6 to clamp the workpiece. For horizontal clamping of cylindrical workpieces, the first electric telescopic rod 9 is activated to drive the two first clamping components 5 to clamp the workpiece. For clamping vertical cylindrical workpieces, the two drive motors 19 are first activated to rotate the two first clamping components 5 clockwise by 90°, and then the first electric telescopic rod 9 is activated to drive the two first clamping components 5 to clamp the workpiece. If the workpiece height or tool distance is insufficient during clamping, the third electric telescopic rod 12 can be activated to drive the support column 11, which in turn lifts the bearing plate 2 and the workpiece to the target height. When using this device, the workpiece can also be rapidly rotated on the desired machining surface.
[0033] Finally, it should be noted that the above description is only a preferred embodiment of the present utility model and is not intended to limit the present utility model. Although the present utility model has been described in detail with reference to the foregoing embodiments, those skilled in the art can still modify the technical solutions described in the foregoing embodiments or make equivalent substitutions for some of the technical features. Any modifications, equivalent substitutions, improvements, etc., made within the spirit and principles of the present utility model should be included within the protection scope of the present utility model.
Claims
1. A machining fixed support platform, comprising a shell (1), a bearing plate (2), and a support plate (13), characterized in that: A support shell (18) is fixedly installed on the lower end face of the outer shell (1). A first support block (3) is fixedly installed on both sides of the upper end face of the bearing plate (2). A drive motor (19) is fixedly installed on both sides of the outer wall of the two first support blocks (3). A connecting block (20) is fixedly connected to the output end of each of the two drive motors (19). A first electric telescopic rod (9) is fixedly installed on both sides of the outer wall of each of the two connecting blocks (20). A first clamping member (5) is fixedly connected to the output end of each of the two first electric telescopic rods (9). The two first clamping members (5) have first grooves (7) on both sides of their outer walls. The upper end of the bearing plate (2) is fixedly provided with second support blocks (4) at the front and rear ends. The two second support blocks (4) are fixedly provided with second electric telescopic rods (10) at the front and rear ends. The output ends of the two second electric telescopic rods (10) are fixedly connected with second clamping members (6). The two second clamping members (6) have second grooves (8) at the front and rear ends. The lower end of the bearing plate (2) is fixedly provided with support columns (11).
2. The machining fixed support platform according to claim 1, characterized in that: The third electric telescopic rod (12) is fixedly installed inside the support shell (18), and the middle part of the lower end face of the support plate (13) is fixedly connected to the upper output end of the third electric telescopic rod (12).
3. The machining fixed support platform according to claim 1, characterized in that: A power-off braking motor (15) is fixedly installed on the upper end face of the support plate (13) near the outer wall. A first gear (16) is fixedly connected to the upper end face of the power-off braking motor (15). A bearing seat (14) is fixedly installed in the middle of the upper end face of the support plate (13). A second gear (17) is fixedly connected to the upper end face of the outer wall of the support column (11). The lower end face of the outer wall of the support column (11) is rotatably installed inside the bearing seat (14), and the first gear (16) and the second gear (17) mesh.
4. The machining fixed support platform according to claim 1, characterized in that: The support plate (2) is slidably embedded inside the upper part of the outer shell (1).
5. A machining fixed support platform according to claim 4, characterized in that: The support plate (13) is slidably disposed inside the outer shell (1) and located at the lower end of the bearing plate (2).
6. The machining fixed support platform according to claim 1, characterized in that: The lower end face of the outer shell (1) is provided with three legs at equal intervals.
7. A machining fixed support platform according to claim 1, characterized in that: Both first clamping members (5) are cylindrical and both first grooves (7) are semi-cylindrical. Both second clamping members (6) are rectangular and both second grooves (8) are isosceles trapezoidal.