A drill press for producing tire chains
By introducing a servo motor-driven gear system and an air duct into the drilling machine used for producing tire anti-skid chains, the problem of difficult debris removal during drilling was solved, and the convenience of debris removal and drilling operation was achieved.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- TIANJIN JUNTONG MASCH CO LTD
- Filing Date
- 2025-03-13
- Publication Date
- 2026-06-12
AI Technical Summary
Existing tire anti-skid chain drilling equipment cannot conveniently use high-speed airflow to blow away the debris generated during drilling.
A drilling machine for producing tire anti-skid chains was designed. It uses a servo motor to drive an active bevel gear and a driven gear system to rotate the blades. A high-speed airflow is discharged through an air duct to blow away debris. The drilling operation is achieved by combining a lifting plate and a clamping system.
This technology enables simultaneous air blowing during drilling, effectively removing debris and improving production efficiency and ease of operation.
Smart Images

Figure CN224347475U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of tire anti-skid chain production technology, specifically to a drilling machine for producing tire anti-skid chains. Background Technology
[0002] Drilling of anti-skid chains refers to the process of drilling holes in the chain or chain links during the manufacturing process of anti-skid chains. The purpose of these drillings may include installing accessories, improving chain flexibility, reducing weight, or other specific requirements.
[0003] Traditional tire anti-skid chain drilling structures cannot easily be blown while working, nor can they easily use high-speed airflow to blow away the debris generated during drilling. Summary of the Invention
[0004] To address the problems in the existing technology, this utility model provides a drilling machine for producing tire anti-skid chains, which can conveniently blow air during operation, and conveniently use high-speed airflow to blow away the debris generated during drilling.
[0005] The technical solution adopted by this utility model to solve its technical problem is a drilling machine for producing tire anti-skid chains, including a base plate, a top plate, a first fixed chamber, a second fixed chamber, a second servo motor, a tool holder, and a drilling tool. The first fixed chamber is connected to the bottom of the lifting plate near the center. The second servo motor is installed in the top of the first fixed chamber through a mounting seat. The output end of the second servo motor is connected to a drive bevel gear. The bottom of the drive bevel gear is connected to an extension shaft. The extension shaft passes through the bottom of the first fixed chamber and is connected to the tool holder. The tool holder holds the drilling tool.
[0006] A second fixed chamber is provided at one end of the first fixed chamber. A first driven shaft and a second driven shaft are respectively provided through slots near the top and bottom of the inner wall of the second fixed chamber. The end of the first driven shaft is located inside the first fixed chamber. A driven bevel gear that meshes with the driving bevel gear is provided around the end of the first driven shaft. A first driven spur gear and a second driven spur gear are respectively provided around the first and second driven shafts. The first driven spur gear meshes with the second driven spur gear. An air inlet is provided through one side of the bottom of the second fixed chamber. A blade is provided on the outer side of the second driven shaft near the end of the second driven spur gear. An air outlet pipe is provided at the end of the second fixed chamber away from the air inlet.
[0007] By adopting the above technical solution, the second servo motor can easily drive the active bevel gear to rotate during operation, thereby driving the driven bevel gear to rotate, which in turn drives the first driven shaft and the first driven spur gear to rotate. When the first driven spur gear rotates, it drives the second driven spur gear to rotate. When the second driven spur gear rotates, it can easily drive the blades to rotate, thereby facilitating the intake of external air through the air inlet and the exhaust through the air outlet. The air outlet facilitates the discharge of high-speed airflow, which can blow air while working, using high-speed airflow to blow away the debris generated during drilling.
[0008] Specifically, vertical plates are welded to both ends of the top of the base plate, and a top plate is connected to the top of the vertical plates. A first extension plate and a second extension plate are respectively provided on the top of the top plate near the inner side of the vertical plates.
[0009] Specifically, a first servo motor is mounted on a fixed base at the bottom of the top plate near the first extension plate. Thread holes and guide holes are respectively provided at both ends of the top of the lifting plate. A lead screw is connected to the power output end of the first servo motor, and the lead screw is sleeved in the thread hole.
[0010] Specifically, a first support plate and a second support plate are respectively connected to one side of the bottom end of the first extension plate and the second extension plate. A bearing is provided on the top of the first support plate, and the bottom end of the lead screw is located inside the bearing. A guide rod is connected between the second extension plate and the top plate, and the guide rod passes through the guide hole.
[0011] By adopting the above technical solution, the bearing can conveniently limit the bottom end of the lead screw, and the guide hole can limit and guide the guide rod, so that the lifting plate can only move up and down.
[0012] Specifically, the top of the base plate is provided with a clamp mounting groove, and a cable routing hole is provided through one side of the top of the first fixed compartment.
[0013] Specifically, L-shaped support legs are welded to both ends of the bottom of the base plate, and mounting holes are provided through the bottom of the L-shaped support legs.
[0014] The beneficial effects of this utility model are:
[0015] The present invention relates to a drilling machine for producing tire anti-skid chains. The second servo motor conveniently drives the active bevel gear to rotate during operation. Since the active bevel gear meshes with the driven bevel gear, and the first driven spur gear meshes with the second driven spur gear, the active bevel gear can easily drive the blades to rotate during rotation. This facilitates the intake of external air through the air inlet and the discharge through the air outlet. The air outlet facilitates the discharge of high-speed airflow, allowing for simultaneous air blowing during operation. The high-speed airflow removes debris generated during drilling. Attached Figure Description
[0016] The present invention will be further described below with reference to the accompanying drawings and embodiments.
[0017] Figure 1 This is a schematic diagram of the overall structure of this utility model;
[0018] Figure 2 This is a schematic diagram of the lifting plate, wire hole, and guide hole structure of this utility model;
[0019] Figure 3 This is a schematic diagram showing the detailed structure at point A of this utility model.
[0020] In the diagram: 1. Base plate; 2. Vertical plate; 3. Top plate; 4. First servo motor; 5. Lead screw; 6. Lifting plate; 7. Lead hole; 8. First extension plate; 9. First support plate; 10. Second extension plate; 11. Second support plate; 12. Guide rod; 13. Bearing; 14. Fixture mounting slot; 15. L-shaped support leg; 16. Mounting hole; 17. First fixed compartment; 18. Second fixed compartment; 19. Guide hole; 20. Second servo motor; 21. Wiring hole; 22. Driven bevel gear; 23. Extension shaft; 24. Tool holder; 25. Drilling tool; 26. First driven shaft; 27. Driven bevel gear; 28. First driven spur gear; 29. Second driven shaft; 30. Second driven spur gear; 31. Air inlet; 32. Blade; 33. Air outlet pipe. Detailed Implementation
[0021] To make the technical means, creative features, objectives and effects of this utility model easier to understand, the present utility model will be further described below in conjunction with specific embodiments.
[0022] To allow for simultaneous air blowing during drilling, a high-speed airflow is used to remove debris generated during drilling. Figure 1-3 As shown, the present invention discloses a drilling machine for producing tire anti-skid chains, comprising a base plate 1, a top plate 3, a first fixed chamber 17, a second fixed chamber 18, a second servo motor 20, a tool holder 24, and a drilling tool 25. The first fixed chamber 17 is connected to the bottom of the lifting plate 6 near the center. The second servo motor 20 is mounted on the top of the first fixed chamber 17 via a mounting base. The output end of the second servo motor 20 is connected to a drive bevel gear 22. The bottom of the drive bevel gear 22 is connected to an extension shaft 23. The extension shaft 23 passes through the bottom of the first fixed chamber 17 and is connected to the tool holder 24. The tool holder 24 holds the drilling tool 25.
[0023] A second fixed chamber 18 is provided at one end of the first fixed chamber 17. A first driven shaft 26 and a second driven shaft 29 are respectively provided through slots near the top and bottom of the inner wall of the second fixed chamber 18. The end of the first driven shaft 26 is located inside the first fixed chamber 17. A driven bevel gear 27 that meshes with the driving bevel gear 22 is provided around the end of the first driven shaft 26. A first driven spur gear 28 and a second driven spur gear 30 are respectively provided around the first driven shaft 26 and the second driven shaft 29. The first driven spur gear 28 meshes with the second driven spur gear 30. An air inlet hole 31 is provided through one side of the bottom end of the second fixed chamber 18. A blade 32 is provided on the outer side of the second driven shaft 29 near the end of the second driven spur gear 30. An air outlet pipe 33 is provided on the end of the second fixed chamber 18 away from the air inlet hole 31.
[0024] In use, the second servo motor 20 can easily drive the active bevel gear 22 to rotate, thereby driving the driven bevel gear 27 to rotate, which in turn drives the first driven shaft 26 and the first driven spur gear 28 to rotate. When the first driven spur gear 28 rotates, it drives the second driven spur gear 30 to rotate. When the second driven spur gear 30 rotates, it can easily drive the blades 32 to rotate, thereby facilitating the intake of external air through the air inlet 31 and the exhaust through the air outlet 33. The air outlet 33 can easily exhaust high-speed airflow, which can blow air while working, and use high-speed airflow to blow away the debris generated during drilling.
[0025] For example, such as Figure 1 As shown, the present invention also includes a base plate 2 welded to both ends of the top of the base plate 1, a top plate 3 connected to the top of the base plate 2, and a first extension plate 8 and a second extension plate 10 respectively provided on the top of the top plate 3 near the inner side of the base plate 2.
[0026] In use, the upright plate 2 provides convenient support for the bottom of the top plate 3, and the first extension plate 8 and the second extension plate 10 are conveniently installed at the bottom of the top plate 3.
[0027] For example, such as Figure 1-2 As shown, the present invention also includes a first servo motor 4 installed at the bottom of the top plate 3 near the end of the first extension plate 8 via a fixed seat, and wire holes 7 and guide holes 19 are respectively provided at both ends of the top of the lifting plate 6. The power output end of the first servo motor 4 is connected to a lead screw 5, and the lead screw 5 is sleeved in the wire hole 7.
[0028] In use, the first servo motor 4 can easily drive the lead screw 5 to rotate. Through the cooperation between the lead screw 5 and the lead hole 7, the lifting plate 6 can be easily lifted and lowered.
[0029] For example, such as Figure 1-2As shown, the present invention also includes a first support plate 9 and a second support plate 11 connected to one side of the bottom end of the first extension plate 8 and the second extension plate 10, respectively. A bearing 13 is provided on the top of the first support plate 9, and the bottom end of the lead screw 5 is located inside the bearing 13. A guide rod 12 is connected between the second extension plate 10 and the top plate 3, and the guide rod 12 passes through the guide hole 19.
[0030] During use, the bearing 13 facilitates the limiting of the bottom end of the lead screw 5, and the guide hole 19 limits and guides the guide rod 12, so that the lifting plate 6 can only move up and down.
[0031] For example, such as Figure 1 and Figure 3 As shown, the present invention also includes a clamp mounting groove 14 on the top of the base plate 1, and a wiring hole 21 through the top side of the first fixed chamber 17.
[0032] In use, the cable for powering the second servo motor 20 can be routed through the cable routing hole 21, and the clamp can be easily installed on the top of the base plate 1 by using external bolts to cooperate with the clamp mounting slot 14.
[0033] For example, such as Figure 1 As shown, the present invention also includes L-shaped support legs 15 welded to both ends of the bottom of the base plate 1, and mounting holes 16 are provided through the bottom of the L-shaped support legs 15.
[0034] During use, the L-shaped support leg 15 is easily fixed by passing external screws through the mounting hole 16, thus facilitating the installation of this drilling machine.
[0035] In use, the second servo motor 20 can easily drive the active bevel gear 22 to rotate, thereby driving the driven bevel gear 27 to rotate, which in turn drives the first driven shaft 26 and the first driven spur gear 28 to rotate. When the first driven spur gear 28 rotates, it drives the second driven spur gear 30 to rotate. When the second driven spur gear 30 rotates, it can easily drive the blades 32 to rotate, thereby facilitating the intake of external air through the air inlet 31 and the exhaust through the air outlet 33. The air outlet 33 can easily exhaust high-speed airflow, which can blow air while working, and use the high-speed airflow to blow away the debris generated during drilling.
[0036] When the first servo motor 4 is working, it can easily drive the lead screw 5 to rotate. The lead screw 5 cooperates with the lead hole 7 to easily drive the lifting plate 6 to rise and fall, thereby enabling the drilling tool 25 to rise and fall. The cable for powering the second servo motor 20 can be easily routed through the cable hole 21. The clamp can be easily installed on the top of the base plate 1 by cooperating with the external bolt and the clamp mounting slot 14. The clamp can easily clamp and fix the anti-skid chain to be clamped. The drilling tool 25 can easily perform drilling operations on the anti-skid chain.
[0037] The foregoing has shown and described the basic principles, main features, and advantages of this utility model. Those skilled in the art should understand that this utility model is not limited to the above embodiments. The descriptions of the above embodiments and specifications are merely illustrative of the principles of this utility model. Various changes and modifications can be made to this utility model without departing from its spirit and scope, and all such changes and modifications fall within the scope of protection claimed by this utility model. The scope of protection of this utility model is defined by the appended claims and their equivalents.
Claims
1. A drilling machine for producing tire anti-skid chains, characterized in that, The device includes a base plate (1), a top plate (3), a first fixed chamber (17), a second fixed chamber (18), a second servo motor (20), a tool holder (24), and a drilling tool (25). The bottom of the lifting plate (6) is connected to the first fixed chamber (17) near the center. The top of the first fixed chamber (17) is equipped with a second servo motor (20) via a mounting base. The output end of the second servo motor (20) is connected to an active bevel gear (22). The bottom of the active bevel gear (22) is connected to an extension shaft (23). The extension shaft (23) passes through the bottom of the first fixed chamber (17) and is connected to the tool holder (24). The tool holder (24) holds the drilling tool (25). A second fixed chamber (18) is provided at one end of the first fixed chamber (17). A first driven shaft (26) and a second driven shaft (29) are respectively provided through a rotating groove near the top and bottom of the inner wall of the second fixed chamber (18). The end of the first driven shaft (26) is located inside the first fixed chamber (17). A driven bevel gear (27) that meshes with the driving bevel gear (22) is provided on the periphery of the end of the first driven shaft (26). A first driven spur gear (28) and a second driven spur gear (30) are respectively provided on the periphery of the first driven shaft (26) and the second driven shaft (29). The first driven spur gear (28) meshes with the second driven spur gear (30). An air inlet hole (31) is provided through one side of the bottom end of the second fixed chamber (18). A blade (32) is provided on the outer side of the second driven shaft (29) near the end of the second driven spur gear (30). An air outlet pipe (33) is provided on the end of the second fixed chamber (18) away from the air inlet hole (31).
2. The drilling machine for producing tire anti-skid chains according to claim 1, characterized in that, The bottom plate (1) has vertical plates (2) welded to both ends of the top. The top plate (2) is connected to the top plate (3). The top plate (3) is provided with a first extension plate (8) and a second extension plate (10) near the inner side of the vertical plate (2). The top plate (3) has a first servo motor (4) installed at the bottom near the first extension plate (8) via a fixed seat. The top two ends of the lifting plate (6) are respectively provided with a wire hole (7) and a guide hole (19). The power output end of the first servo motor (4) is connected to a lead screw (5), which is sleeved in the wire hole (7).
3. The drilling machine for producing tire anti-skid chains according to claim 2, characterized in that, The first extension plate (8) and the second extension plate (10) are respectively connected to the bottom side of the first support plate (9) and the second support plate (11). The first support plate (9) is provided with a bearing (13) at the top. The bottom end of the lead screw (5) is located in the bearing (13). The second extension plate (10) and the top plate (3) are connected by a guide rod (12). The guide rod (12) passes through the guide hole (19).
4. A drilling machine for producing tire anti-skid chains according to claim 1, characterized in that, The bottom plate (1) has a clamp mounting groove (14) on its top, and a wiring hole (21) is provided on one side of the top of the first fixed chamber (17).
5. A drilling machine for producing tire anti-skid chains according to claim 1, characterized in that, The bottom of the base plate (1) is welded with L-shaped support legs (15) at both ends, and the bottom of the L-shaped support legs (15) is provided with mounting holes (16).