Stamping die heat treatment feeding device

By adjusting the angle and height of the conveyor frame through a worm gear motor and belt pulley transmission system, the adaptability and stability issues of the existing device when there are height differences are solved, and the convenience and stability of the stamping die heat treatment feeding device are realized.

CN224466804UActive Publication Date: 2026-07-07TIANJIN AIXIN HEAT TREATMENT CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
TIANJIN AIXIN HEAT TREATMENT CO LTD
Filing Date
2025-08-29
Publication Date
2026-07-07

AI Technical Summary

Technical Problem

Existing stamping die heat treatment feeding devices require operators to provide additional support when there are differences in conveyor belt height, resulting in insufficient equipment adaptability and stability.

Method used

The worm is driven by a worm motor to rotate, which in turn drives the worm wheel and the angle shaft to rotate, adjusting the feeding angle and height of the conveyor frame. Combined with the synchronous rotation of the drive motor shaft and the transmission belt of the pulley, the equipment achieves a self-locking function.

Benefits of technology

This increases the adaptability and stability of the equipment, avoids mold misalignment and jamming, ensures that the adjustable angle can be maintained even after a power outage, and improves the ease of use and reliability of the equipment.

✦ Generated by Eureka AI based on patent content.

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  • Figure CN224466804U_ABST
    Figure CN224466804U_ABST
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Abstract

A stamping die heat treatment feeding device includes an equipment base, an equipment column, a motor shaft, a second bearing, a third bearing, and a linkage shaft bracket. The upper part of the equipment base is fixedly connected to the equipment column. The front part of the equipment column has a sub-bracket, the lower part of which is fixedly connected to the equipment base. The upper part of the equipment column has an angle shaft groove, and the side of the positioning plate has an angle shaft. The angle shaft groove is adapted to the angle shaft and is connected to the angle shaft. The angle shaft rotates inside the angle shaft groove. The front part of the angle shaft is fixedly connected to a worm gear. The upper part of the equipment column is fixedly connected to a worm gear frame. The worm gear frame is adapted to the worm gear and is connected to the worm gear. The worm gear rotates inside the worm gear frame. The side of the equipment column is fixedly connected to a worm gear frame, and the worm gear rotates inside the worm gear frame.
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Description

Technical Field

[0001] This utility model relates to the field of mold heat treatment feeding, and in particular to a stamping mold heat treatment feeding device. Background Technology

[0002] An existing patent (publication number: CN221139960U) discloses a heat treatment feeding device for stamping dies. This device includes a material processing body and a support frame inside it, further comprising: a protective plate fixedly connected to the top of the support frame; a feeding roller symmetrically rotatably connected to the protective plate; a conveyor belt wrapped around the outer surface of the feeding roller; a rotating component fixedly connected to the protective plate, with its rotating end fixed to one of the feeding rollers; and a hot air component located inside the support frame, with its outlet facing the conveyor belt. However, this device, where "the conveyor belt wraps around the outer surface of the feeding roller," relies on the conveyor belt above the support frame for die feeding. Since the support frame is of fixed height, if the end device has a certain height difference, the operator needs to additionally elevate the end, which has certain limitations. Summary of the Invention

[0003] This utility model addresses the aforementioned shortcomings of the existing technology by providing a stamping die heat treatment feeding device. After the mold is placed at the first transmission belt on the upper part of the equipment base, when it is necessary to adjust the feeding angle of the conveyor frame, the worm motor on the side of the equipment column drives the worm to rotate, causing the worm to drive the worm wheel to rotate, and at the same time, driving the angle shaft at the rear of the conveyor frame to rotate, thereby adjusting the conveying height at the end of the conveyor frame, thus increasing the adaptability of the equipment.

[0004] The objective of this utility model is achieved through the following technical solution:

[0005] A stamping die heat treatment feeding device includes a base, a column, a motor shaft, a second bearing, a third bearing, and a linkage shaft support. The upper part of the base is fixedly connected to the column. The front of the column has a secondary support, the lower part of which is fixedly connected to the base. The upper part of the column has an angle shaft groove, and the side of the positioning plate has an angle shaft. The angle shaft groove is adapted to the angle shaft and connects to it. The angle shaft rotates within the groove. The front of the angle shaft is fixedly connected to a worm gear. The upper part of the column is fixedly connected to a worm gear frame, which is adapted to the worm gear and connects to it. The wheel rotates inside the worm gear frame. The side of the equipment column is fixedly connected to the worm gear frame. The worm rotates inside the worm gear frame. The rear of the worm gear frame is fixedly connected to the worm motor. The output shaft of the worm motor is fixedly connected to the worm. The worm wheel meshes with the upper part of the worm. The front of the positioning plate is fixedly connected to the conveyor frame. The side of the conveyor frame is fixedly connected to the outside of the first bearing. The first bearing is compatible with the first pulley. The first bearing is connected to the first pulley. The first pulley is fixed inside the first bearing. The front of the first pulley has a motor shaft. The rear of the angle shaft has a motor shaft groove. The motor shaft groove is compatible with the motor shaft. The motor shaft groove is connected to the motor shaft.

[0006] The motor shaft rotates inside the motor shaft groove. The rear part of the angle shaft is fixedly connected to the drive motor. The output shaft of the drive motor is fixedly connected to the motor shaft. The front part of the conveyor frame is fixedly connected to the outside of the second bearing. The second bearing is adapted to the second pulley.

[0007] The second bearing is connected to the second pulley, which is fixed inside the second bearing. The first pulley is connected to the second pulley via the second transmission belt. The rear of the equipment column is fixedly connected to the guide frame, and the front of the guide frame is fixedly connected to the outside of the third bearing. Beneficial effects

[0008] 1. In the process of using the stamping die heat treatment feeding device of this utility model, after the die is placed at the first transmission belt on the upper part of the equipment base, if it is necessary to adjust the feeding angle of the conveyor frame, the worm motor on the side of the equipment column drives the worm to rotate, so that the worm drives the worm wheel to rotate, and at the same time, drives the angle shaft at the rear of the conveyor frame to rotate, thereby adjusting the conveying height at the end of the conveyor frame, thereby increasing the adaptability of the equipment.

[0009] 2. During the use of the stamping die heat treatment feeding device of this utility model, the drive motor shaft at the front of the angle shaft rotates, causing the motor shaft to drive the second transmission belt inside the first and second pulleys to rotate. At the same time, the power is transmitted through the transmission wheel inside the motor shaft and the linkage shaft, so that the first and second transmission belts inside the third and fourth pulleys rotate synchronously and at the same speed. This avoids the mold above the second and first transmission belts from being misaligned and jammed due to speed difference, thereby increasing the stability of the equipment.

[0010] 3. During the use of the stamping die heat treatment feeding device of this utility model, the internal worm gear is driven by the worm motor to rotate the worm wheel. Because the transmission principle of the worm and worm wheel has a self-locking function, the device can maintain the adjusted angle even after power failure, thereby enhancing the stability of the device. Attached Figure Description

[0011] Figure 1 This is a schematic diagram of the structure of a heat treatment feeding device for stamping dies according to the present invention.

[0012] Figure 2 This is a three-dimensional assembly diagram of a heat treatment feeding device for stamping dies according to the present invention.

[0013] Figure 3 This is a three-dimensional assembly diagram of the worm gear frame structure of a heat treatment feeding device for stamping dies according to the present invention.

[0014] Figure 4 This is a three-dimensional assembly diagram of the positioning plate structure of the stamping die heat treatment feeding device according to the present invention.

[0015] Figure 5 This is a partial cross-sectional schematic diagram of the angle shaft structure of the heat treatment feeding device for stamping dies according to the present invention.

[0016] Figure 6 This is a three-dimensional assembly diagram of the conveyor frame structure of a heat treatment feeding device for stamping dies according to the present invention.

[0017] Figure 7 This is a partial cross-sectional schematic diagram of the column structure of the stamping die heat treatment feeding device according to the present invention.

[0018] Figure 8 This is a three-dimensional assembly diagram of the guide frame structure of the heat treatment feeding device for stamping dies according to the present invention. Detailed Implementation

[0019] The present invention will be further described in detail below with reference to the accompanying drawings and embodiments:

[0020] Example 1:

[0021] A stamping die heat treatment feeding device includes an equipment base 01, an equipment column 02, a motor shaft 15, a second bearing 18, a third bearing 22, and a linkage shaft bracket 27. The upper part of the equipment base 01 is fixedly connected to the equipment column 02. The front part of the equipment column 02 has a sub-bracket 03, the lower part of which is fixedly connected to the equipment base 01. The upper part of the equipment column 02 has an angle shaft groove 04, and the side of the positioning plate 05 has an angle shaft 06. The angle shaft groove 04 is adapted to the angle shaft 06 and connects to the angle shaft 06. The angle shaft 06 rotates inside the angle shaft groove 04. In the operation of the stamping die heat treatment feeding device, after the die is placed at the first transmission belt 31 on the upper part of the equipment base 01, if it is necessary to adjust the feeding angle of the conveyor frame 12, the worm motor 11 on the side of the equipment column 02 drives the worm 10 to rotate. This causes the worm 10 to drive the worm wheel 07 to rotate, and simultaneously drives the angle shaft 06 at the rear of the conveyor frame 12 to rotate. This allows the angle shaft 06 to adjust the conveying height at the end of the conveyor frame 12, thereby increasing the adaptability of the equipment. The front part of the angle shaft 06 is fixedly connected to the worm wheel 07, and the upper part of the equipment column 02 is connected to the worm wheel frame 08. The worm gear frame 08 is fixedly connected to the worm gear 07, and the worm gear 07 rotates inside the worm gear frame 08. The side of the equipment column 02 is fixedly connected to the worm gear frame 09, and the worm 10 is rotatably connected inside the worm gear frame 09. The rear of the worm gear frame 09 is fixedly connected to the worm motor 11, and the output shaft of the worm motor 11 is fixedly connected to the worm 10. During the use of the stamping die heat treatment feeding device, the worm motor 11 drives the internal worm 10 to drive the worm gear 07 to rotate. Because the transmission principle of the worm 10 and the worm gear 07 has a self-locking function, the equipment can withstand interruptions. Even after power is applied, the adjusted angle can be maintained, thereby enhancing the stability of the equipment. The worm gear 07 meshes with the upper part of the worm 10. The front part of the positioning plate 05 is fixedly connected to the conveyor frame 12. The side part of the conveyor frame 12 is fixedly connected to the outside of the first bearing 13. The first bearing 13 is adapted to the first pulley 14. The first bearing 13 is connected to the first pulley 14. The first pulley 14 is fixed inside the first bearing 13. The front part of the first pulley 14 has a motor shaft 15. The rear part of the angle shaft 06 has a motor shaft groove 16. The motor shaft groove 16 is adapted to the motor shaft 15. The motor shaft groove 16 is connected to the motor shaft 15.

[0022] Example 2:

[0023] The motor shaft 15 of this utility model rotates inside the motor shaft groove 16. The rear part of the angle shaft 06 is fixedly connected to the drive motor 17. The output shaft of the drive motor 17 is fixedly connected to the motor shaft 15. The front part of the conveyor frame 12 is fixedly connected to the outside of the second bearing 18. The second bearing 18 is adapted to the second pulley 19.

[0024] Example 3:

[0025] In this invention, the second bearing 18 is connected to the second pulley 19, and the second pulley 19 is fixed inside the second bearing 18. The first pulley 14 is connected to the second pulley 19 through the second transmission belt 20. During the use of the stamping die heat treatment feeding device, the motor shaft 15 is driven to rotate by the drive motor 17 at the front of the angle shaft 06. This causes the motor shaft 15 to drive the second transmission belt 20 inside the first pulley 14 and the second pulley 19 to rotate. At the same time, the power is transmitted through the transmission wheel 25 inside the linkage shaft 24 inside the motor shaft 15, so that the first transmission belt 31 inside the third pulley 23 and the fourth pulley 30 rotates synchronously and at the same speed as the second transmission belt 20. This avoids the mold above the second transmission belt 20 and the first transmission belt 31 from being misaligned and jammed due to speed difference, thereby increasing the stability of the equipment. The rear of the equipment column 02 is fixedly connected to the guide frame 21, and the front of the guide frame 21 is fixedly connected to the outside of the third bearing 22.

[0026] Example 4:

[0027] The third pulley 23 of this utility model is fixedly connected inside the third bearing 22. The rear of the third pulley 23 has a linkage shaft 24. The rear of the motor shaft 15 and the rear of the linkage shaft 24 both have transmission wheels 25. The two sets of transmission wheels 25 are connected by a transmission wheel belt 26. The surface of the equipment column 02 is fixedly connected to the linkage shaft bracket 27.

[0028] Example 5:

[0029] The rear of the linkage shaft 24 of this utility model is rotatably connected inside the linkage shaft bracket 27. The front of the guide frame 21 is fixedly connected to the outside of the fourth bearing 29. The inside of the fourth bearing 29 is fixedly connected to the fourth pulley 30. The third pulley 23 is connected to the fourth pulley 30 through the first transmission belt 31. The front of the first transmission belt 31 corresponds to the rear of the second transmission belt 20.

[0030] Example 6:

[0031] Installation steps of this utility model: Fix the upper part of the equipment base 01 to the equipment column 02; fix the lower part of the auxiliary support 03 to the equipment base 01; rotate the angle shaft 06 inside the angle shaft groove 04; fix the front part of the angle shaft 06 to the worm gear 07; fix the upper part of the equipment column 02 to the worm gear frame 08; rotate the worm gear 07 inside the worm gear frame 08; fix the side of the equipment column 02 to the worm gear frame 09; rotate the worm 10 inside the worm gear frame 09. Connect the worm gear carrier 09 to the worm motor 11, fix the output shaft of the worm motor 11 to the worm 10, mesh the worm wheel 07 on the upper part of the worm 10, fix the front part of the positioning plate 05 to the conveyor frame 12, fix the side of the conveyor frame 12 to the outside of the first bearing 13, fix the first pulley 14 inside the first bearing 13, rotate the motor shaft 15 inside the motor shaft groove 16, and fix the rear part of the angle shaft 06 to the drive motor 17. The output shaft of the drive motor 17 is fixedly connected to the motor shaft 15. The front part of the conveyor frame 12 is fixedly connected to the outside of the second bearing 18. The second pulley 19 is fixed inside the second bearing 18. The first pulley 14 is connected to the second pulley 19 through the second transmission belt 20. The rear part of the equipment column 02 is fixedly connected to the guide frame 21. The front part of the guide frame 21 is fixedly connected to the outside of the third bearing 22. The third pulley 23 is fixedly connected inside the third bearing 22. The two sets of transmission wheels 25 are connected through the transmission wheel belt 26. The surface of the equipment column 02 is fixedly connected to the linkage shaft bracket 27. The rear part of the linkage shaft 24 is rotatably connected inside the linkage shaft bracket 27. The front part of the guide frame 21 is fixedly connected to the outside of the fourth bearing 29. The inside of the fourth bearing 29 is fixedly connected to the fourth pulley 30. The third pulley 23 is connected to the fourth pulley 30 through the first transmission belt 31. The front part of the first transmission belt 31 corresponds to the rear part of the second transmission belt 20.

[0032] The above description is only a preferred embodiment of the present utility model and is not intended to limit the present utility model. 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 utility model, and these improvements and modifications should also be considered within the protection scope of the present utility model.

Claims

1. A heat treatment feeding device for stamping dies, characterized in that: The equipment includes a base (01), a column (02), a motor shaft (15), a second bearing (18), a third bearing (22), and a linkage shaft bracket (27). The upper part of the base (01) is fixedly connected to the column (02). The front part of the column (02) has a sub-bracket (03), the lower part of which is fixedly connected to the base (01). The upper part of the column (02) has an angle shaft groove (04), and the positioning plate (05) is located on the side. The part has an angle shaft (06), an angle shaft groove (04) adapted to the angle shaft (06), the angle shaft groove (04) connects to the angle shaft (06), the angle shaft (06) rotates inside the angle shaft groove (04), the front part of the angle shaft (06) is fixedly connected to the worm gear (07), the upper part of the equipment column (02) is fixedly connected to the worm gear frame (08), the worm gear frame (08) is adapted to the worm gear (07), the worm gear frame (08) connects to the worm gear (07), and the worm gear (07) rotates inside the worm shaft groove (04). The worm gear frame (08) rotates internally, the side of the equipment column (02) is fixedly connected to the worm gear frame (09), the worm (10) is rotatably connected inside the worm gear frame (09), the rear of the worm gear frame (09) is fixedly connected to the worm motor (11), the output shaft of the worm motor (11) is fixedly connected to the worm (10), the worm wheel (07) meshes on the upper part of the worm (10), the front of the positioning plate (05) is fixedly connected to the conveyor frame (12), and the side of the conveyor frame (12) is connected to the first shaft. The bearing (13) is externally fixedly connected. The first bearing (13) is adapted to the first pulley (14). The first bearing (13) is connected to the first pulley (14). The first pulley (14) is fixed inside the first bearing (13). The front part of the first pulley (14) has a motor shaft (15), and the rear part of the angle shaft (06) has a motor shaft groove (16). The motor shaft groove (16) is adapted to the motor shaft (15). The motor shaft groove (16) is connected to the motor shaft (15).

2. The stamping die heat treatment feeding device according to claim 1, characterized in that: The motor shaft (15) rotates inside the motor shaft groove (16). The rear part of the angle shaft (06) is fixedly connected to the drive motor (17). The output shaft of the drive motor (17) is fixedly connected to the motor shaft (15). The front part of the conveyor frame (12) is fixedly connected to the outside of the second bearing (18). The second bearing (18) is adapted to the second pulley (19).

3. The stamping die heat treatment feeding device according to claim 2, characterized in that: The second bearing (18) is connected to the second pulley (19), the second pulley (19) is fixed inside the second bearing (18), the first pulley (14) is connected to the second pulley (19) through the second transmission belt (20), the rear of the equipment column (02) is fixedly connected to the guide frame (21), and the front of the guide frame (21) is fixedly connected to the outside of the third bearing (22).

4. The stamping die heat treatment feeding device according to claim 3, characterized in that: The third pulley (23) is fixedly connected inside the third bearing (22). The rear of the third pulley (23) has a linkage shaft (24). The rear of the motor shaft (15) and the rear of the linkage shaft (24) both have transmission wheels (25). The two sets of transmission wheels (25) are connected by a transmission wheel belt (26). The surface of the equipment column (02) is fixedly connected to the linkage shaft bracket (27).

5. A stamping die heat treatment feeding device according to claim 4, characterized in that: The rear part of the linkage shaft (24) is rotatably connected inside the linkage shaft bracket (27), the front part of the guide frame (21) is fixedly connected to the outside of the fourth bearing (29), the inside of the fourth bearing (29) is fixedly connected to the fourth pulley (30), the third pulley (23) is connected to the fourth pulley (30) through the first transmission belt (31), and the front part of the first transmission belt (31) corresponds to the rear part of the second transmission belt (20).