Horizontal press bending and roll forming die
By designing a horizontal pressing, bending, and rolling die, and utilizing a servo motor to drive the guide thread rod and sprocket mechanism, the problem of insufficient limiting in existing dies is solved, realizing automated feeding and unloading, and improving stamping efficiency and forming quality.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Patents(China)
- Current Assignee / Owner
- HANGZHOU KAIBEI NAITE TECH CO LTD
- Filing Date
- 2023-10-23
- Publication Date
- 2026-06-05
AI Technical Summary
Existing rolling and bending dies cannot effectively limit the movement of materials during the opposing movement of the dies, resulting in material slippage, inaccurate docking, and easy jamming of the formed material, requiring manual assistance for unloading, which affects stamping efficiency.
A horizontal pressing, bending, and rolling die is adopted. The guide thread rod and sprocket mechanism are driven by a servo motor to realize the coordinated movement of the upper and lower dies. Combined with the feeding sliding plate and the material blocking baffle, the material is accurately fed and discharged to prevent jamming.
It has achieved automated material feeding and unloading, improved stamping efficiency, ensured the forming qualification rate, reduced manual intervention, and reduced mold wear.
Smart Images

Figure CN117340131B_ABST
Abstract
Description
Technical Field
[0001] This invention relates to the field of rolling die technology, specifically a horizontal pressing, bending, and rolling die. Background Technology
[0002] Molds refer to various molds and tools used to obtain desired products through injection molding, blow molding, extrusion, die casting or forging, smelting, stamping and other methods. Different types of molds can stamp materials into workpieces of different shapes, including workpieces that are bent or rolled.
[0003] Publication number CN212019113U discloses a rolling and bending die. The bending shaft is installed in the extrusion chamber. The change in the die structure during the bending and extrusion process drives the change in the shape of the product. It transforms the traditional static die into a dynamic die, transforms the original V-shaped curve into a circle, and can complete 360-degree circular bending. It changes the traditional hand-made process, improves work efficiency, reduces production and labor costs, and is easy to operate.
[0004] However, the above-mentioned rolling and bending dies for materials still have the following problems in actual operation: the material is rolled in a circular cavity by the opposing movement of the upper and lower dies. However, the internal part of the upper and lower dies cannot be effectively limited during the opposing movement. The bent part will slide due to the resistance of the circular cavity, which will result in the rolled end not being able to be connected or being connected too much. At the same time, the dies are prone to jamming the formed material in the cavity during stamping, requiring manual assistance to unload the material, which will cause wear on the inner wall of the die and will not improve the stamping efficiency.
[0005] Therefore, we propose a horizontal pressing, bending, and rolling die to solve the problems mentioned above. Summary of the Invention
[0006] The purpose of this invention is to provide a horizontal pressing, bending, and rolling die to solve the problems mentioned in the background art. In the current method, the material is rolled in a circular cavity by the opposing movement of the upper and lower dies. However, during the opposing movement of the upper and lower dies, the internal space cannot be effectively limited. The bent section will slide due to the resistance of the circular cavity, resulting in the rolled end not being able to be properly aligned or being over-aligned. At the same time, this type of die is prone to jamming the formed material in the cavity during stamping, requiring manual assistance to unload the material, which causes wear on the inner wall of the die and does not improve the stamping efficiency.
[0007] To achieve the above objectives, the present invention provides the following technical solution: a horizontal pressing, bending and rolling die, comprising a bearing platform and guide threaded rods rotatably disposed on the front and rear sides of the top surface of the bearing platform via bearings, and a servo motor is fixedly disposed on the rear right side of the top surface of the bearing platform;
[0008] A main bearing vertical plate is fixedly installed on the left side of the top surface of the bearing platform, and a lower mold body is fixedly installed at the center position of the right side of the main bearing vertical plate.
[0009] The top right side of the bearing platform is provided with a secondary bearing vertical plate, and the upper mold body is slidably provided at the center position of the left side of the secondary bearing vertical plate;
[0010] Among them, a feeding bracket is fixedly installed on the left side of the top surface of the bearing platform, and a guide groove is opened on the right side of the top surface of the feeding bracket, and a feeding sliding plate is slidably installed in the guide groove on the top surface of the feeding bracket.
[0011] A material discharge slot is provided at the center of the left side of the bearing platform, and a material blocking baffle is slidably installed above the material discharge slot. The front and rear sides of the right end of the material blocking baffle are connected to the inner wall of the right side of the material discharge slot through traction springs. The material discharge slot can be closed and opened by sliding the material blocking baffle.
[0012] The right ends of the guide thread rods on the front and rear sides of the top of the bearing platform are meshed with each other through the first sprocket mechanism, and the right end of the rear guide thread rod is fixedly connected to the output shaft end of the servo motor. The middle thread of the guide thread rods on the front and rear sides is connected to the outer end of the auxiliary bearing vertical plate.
[0013] The top left end of the bearing platform is equipped with a drive shaft on both the front and rear sides via bearings. The top of the drive shaft is connected to the outer left side of the guide thread rod via a bevel gear set. A sector gear is fixedly installed on the lower outer wall of the drive shaft. The front and rear sides of the top of the bearing platform are equipped with drive gears via torsion springs.
[0014] The sector gears on the front and rear sides of the top of the bearing platform are respectively meshed and connected to the outer wall of the drive gear. The shafts at the top of the front and rear drive gears are all connected to the outer end of the traction steel cable. The inner ends of the front and rear traction steel cables are all fixedly connected to the right outer wall of the material blocking baffle inside the material discharge trough.
[0015] The upper mold body is fixedly installed at both the front and rear ends of the left side of the auxiliary bearing vertical plate;
[0016] The main supporting vertical plate has a lower mold body at both the front and rear ends on the right side, and the joint between the symmetrically arranged upper mold body and the lower mold body has an inclined structure for extrusion and pushing.
[0017] Preferably, the auxiliary support vertical plate and the internal upper mold body are connected to each other by a reset spring.
[0018] Preferably, the main bearing vertical plate has limiting slide rods fixedly installed on both the front and rear sides, and the outer walls of the limiting slide rods on both the front and rear sides are slidably connected to the left end of the lower mold body. The lower mold body on both the front and rear sides is connected to the limiting slide rods by limiting springs, and the inner center of the lower mold body on both the front and rear sides is provided with a rolling guide groove.
[0019] Preferably, a drive gear is rotatably mounted on the left inner center position of the lower mold body via a bearing, and driven racks are slidably mounted on both the front and rear ends of the left inner side of the lower mold body. The outer ends of the driven racks on both the front and rear sides are fixedly connected to the inner end of the lower mold body, and the driven racks on both the front and rear sides are meshed with the drive gear.
[0020] Preferably, a top material pusher plate is slidably arranged inside the right side of the lower mold body, and lifting sleeves are rotatably arranged at both the front and rear ends of the right side of the lower mold body through bearings. Guide gears are fixedly arranged at the left ends of the lifting sleeves on both the front and rear sides, and the guide gears on both the front and rear sides are meshed with the driven racks on the front and rear sides inside the lower mold body. Lifting thread rods are threadedly connected inside the lifting sleeves, and the right ends of the lifting thread rods on both the front and rear sides are fixedly connected to the inner wall of the top material pusher plate.
[0021] Preferably, the front and rear sides of the top of the feeding bracket are rotatably provided with a winding shaft via bearings, and the left ends of the front and rear winding shafts are meshed with the left ends of the front and rear guide threaded rods via a second sprocket mechanism. The right outer wall of the front and rear winding shafts is wound around and connected to the top of the traction rope, and the bottom ends of the front and rear traction ropes are fixedly connected to the outer wall of the feeding sliding plate.
[0022] Compared with the prior art, the beneficial effects of the present invention are as follows: This horizontal pressing, bending, and rolling die, through the merging and detachment of the upper die body and the lower die body on the top of the supporting platform, and the linkage of the feeding sliding plate inside the feeding bracket to deliver the workpiece to the designated position, and after stamping, the unloading slot opens to allow the rolled workpiece to fall and be discharged, ensuring the qualified rate of material forming, and eliminating the tedious steps of manual loading and unloading. The specific details are as follows:
[0023] 1. By setting up the feeding bracket and feeding sliding plate above the support platform, the upper die body can be raised in conjunction with the upper die body during movement, so that the manually put material can be slid through the feeding groove in the feeding sliding plate to the right outer wall of the lower die body, thus completing the feeding before stamping. The feeding sliding plate ensures that the material is always in the center position, preventing the two ends of the material from being of different lengths after rolling. The rising and falling feeding operation can be repeated when performing the next stamping step.
[0024] 2. By setting up a material discharge slot and a material blocking baffle inside the bearing platform, the material blocking baffle can be driven to block the upper part of the material discharge slot during the die closing and stamping process of the upper and lower die bodies to prevent the unformed workpiece from falling off, and will automatically open after stamping to discharge the formed workpiece.
[0025] 3. The upper mold body is elastically connected to keep it in contact with the material. The lower mold body, which can slide on the left and right sides of the lower mold body, can resist the upper mold body from sliding inward when the upper mold body moves. This will drive the ejector plate inside the lower mold body to collect the material, ensuring the qualified rate of the material forming. After the workpiece is formed, the lower mold bodies on both sides drive the ejector plate to push the workpiece out, preventing jamming and other situations. Attached Figure Description
[0026] Figure 1 This is a schematic diagram of the overall three-dimensional structure of the present invention;
[0027] Figure 2 This is a three-dimensional structural diagram of the feeding bracket of the present invention;
[0028] Figure 3 This is a three-dimensional structural diagram of the feeding sliding plate of the present invention;
[0029] Figure 4 This is a schematic diagram of the three-dimensional structure of the upper mold body of the present invention;
[0030] Figure 5 This is a schematic diagram of the winding shaft mounting structure of the present invention;
[0031] Figure 6 This is a schematic diagram of the three-dimensional cross-sectional structure of the feeding sliding plate of the present invention;
[0032] Figure 7 This is a schematic diagram of the three-dimensional structure of the material-blocking baffle of the present invention;
[0033] Figure 8 This is a schematic diagram of the three-dimensional structure of the lower mold body of the present invention;
[0034] Figure 9 This is a schematic diagram of the installation structure of the top material pusher plate of the present invention;
[0035] Figure 10 This is a schematic diagram of the three-dimensional cross-sectional structure of the lower mold body of the present invention;
[0036] Figure 11 This is a schematic diagram of the mounting structure of the lower mold body of the present invention.
[0037] In the diagram: 1. Bearing platform; 2. Guide threaded rod; 3. Servo motor; 4. Main bearing vertical plate; 5. Lower mold body; 6. Secondary bearing vertical plate; 7. Upper mold body; 8. Feeding bracket; 9. Guide slide; 10. Feeding sliding plate; 11. First sprocket mechanism; 12. Return spring; 13. Limiting slide rod; 14. Lower mold body; 15. Limiting spring; 16. Rolling guide groove; 17. Driving gear; 18. Driven rack; 19. Top push plate; 20. Lifting threaded rod; 21. Guide gear; 22. Rewinding shaft; 23. Second sprocket mechanism; 24. Traction rope; 25. Discharge slot; 26. Material blocking baffle; 27. Traction spring; 28. Drive shaft; 29. Sector gear; 30. Drive gear; 31. Traction cable; 32. Upper mold body; 33. Bevel gear group; 34. Lifting sleeve. Detailed Implementation
[0038] The technical solutions of the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings. Obviously, the described embodiments are only some embodiments of the present invention, and not all embodiments. Based on the embodiments of the present invention, all other embodiments obtained by those skilled in the art without creative effort are within the scope of protection of the present invention.
[0039] Please see Figures 1-11 The present invention provides a technical solution: a horizontal pressing, bending, and rolling die, comprising a supporting platform 1, and guide threaded rods 2 rotatably mounted on the front and rear sides of the top surface of the supporting platform 1 via bearings, and a servo motor 3 fixedly mounted on the rear right side of the top surface of the supporting platform 1; drive shafts 28 are rotatably mounted on the front and rear sides of the left end of the top surface of the supporting platform 1 via bearings, and the top end of the drive shafts 28 is meshed with the outer left side of the guide threaded rods 2 via a bevel gear set 33, and a sector gear 29 is fixedly mounted on the lower outer wall of the drive shafts 28; and drive gears 30 are rotatably mounted on the front and rear sides of the top surface of the supporting platform 1 via torsion springs; the sector gears 29 on the front and rear sides of the top surface of the supporting platform 1 are respectively meshed with the outer walls of the drive gears 30, and the shafts at the top ends of the drive gears 30 on both the front and rear sides are wound around and connected to the outer ends of traction steel cables 31; Figures 1-2 , Figure 7 As shown, the servo motor 3 on the top surface of the bearing platform 1 drives the meshing guide thread rod 2 to rotate through the first sprocket mechanism 11, and then drives the drive shaft 28 and the sector gear 29 to rotate through the bevel gear group 33, and then drives the traction steel cable 31 to relax when the drive gear 30 is meshed.
[0040] The inner ends of the front and rear traction steel cables 31 are fixedly connected to the right outer wall of the material blocking baffle 26 inside the material discharge trough 25; a material discharge trough 25 is provided at the center of the left side of the bearing platform 1, and a material blocking baffle 26 is slidably arranged above the material discharge trough 25. The front and rear sides of the right end of the material blocking baffle 26 are connected to the right inner wall of the material discharge trough 25 through traction springs 27, and the bottom ends of the front and rear traction ropes 24 are fixedly connected to the outer wall of the feeding sliding plate 10; Figure 7 As shown, the traction cable 31 is released, causing the material-blocking baffle 26 inside the discharge chute 25 to be pushed to the left by the reset of the traction spring 27 when no longer under traction. This causes the material-blocking baffle 26 to seal the discharge chute 25, facilitating subsequent material feeding. Figures 1-2 As shown, the reverse-rotating guide thread rod 2 drives the traction steel cable 31 to wind in the opposite direction again, thereby driving the material blocking baffle 26 fixedly connected to the inner end to slide to the right, so that the material discharge slot 25 is in the open state so that the stamped workpiece can be discharged.
[0041] A feeding bracket 8 is fixedly installed on the left side of the top surface of the supporting platform 1, and a guide groove 9 is opened on the right side of the top surface of the feeding bracket 8. A feeding sliding plate 10 is slidably installed in the guide groove 9 on the top surface of the feeding bracket 8. A winding shaft 22 is rotatably installed on both the front and rear sides of the top surface of the feeding bracket 8 via bearings. The left ends of the winding shafts 22 on both the front and rear sides are meshed with the left ends of the guide threaded rods 2 on both the front and rear sides via a second sprocket mechanism 23. The right outer wall of the winding shafts 22 on both the front and rear sides is wound around and connected to the top end of the traction rope 24. Figures 5-6 As shown, the guide thread rod 2 drives the winding shaft 22 at the top of the feeding bracket 8 to rotate through the second sprocket mechanism 23. The winding shaft 22 drives the traction rope 24 wound around the outer wall to wind up, so that the feeding sliding plate 10 at the bottom of the traction rope 24 slides up and down along the guide groove 9 to the outer wall away from the lower mold body 5 under traction. This allows the material that is manually put in to slide through the feeding groove in the feeding sliding plate 10 to the right outer wall of the lower mold body 5. The feeding sliding plate 10 ensures that the material is always in the center position, preventing the two ends of the material from being of different lengths after being rolled up.
[0042] A main bearing vertical plate 4 is fixedly installed on the left side of the top surface of the bearing platform 1, and a lower mold body 5 is fixedly installed at the center of the right side of the main bearing vertical plate 4; limit slide rods 13 are fixedly installed on both the front and rear sides of the interior of the main bearing vertical plate 4, and the outer walls of the limit slide rods 13 on both the front and rear sides are slidably connected to the left end of the lower mold body 14, and the lower mold body 14 on both the front and rear sides is connected to the limit slide rods 13 by limit springs 15, and a rolling guide groove 16 is opened in the middle of the inner side of the lower mold body 14 on both the front and rear sides; Figure 8 , Figure 11As shown, the upper mold body 32 first contacts the lower mold body 14 on both sides of the main bearing vertical plate 4, and the lower mold body 14 on both sides of the front and rear sides slides inward by continuous sliding and pressing, so that it drives the driven rack 18 on the inner side to push inward along the limiting slide bar 13.
[0043] A secondary support vertical plate 6 is provided on the right side of the top surface of the support platform 1, and an upper mold body 7 is slidably provided at the center position of the left side of the secondary support vertical plate 6; the right ends of the guide thread rods 2 on the front and rear sides of the top surface of the support platform 1 are meshed with each other through the first sprocket mechanism 11, and the right end of the rear guide thread rod 2 is fixedly connected to the output shaft end of the servo motor 3, and the middle threads of the guide thread rods 2 on the front and rear sides are threaded through and connected to the outer end of the secondary support vertical plate 6, and the secondary support vertical plate 6 and the internal upper mold body 7 are connected to each other through the return spring 12, and the upper mold body 32 is fixedly provided at both the front and rear ends of the left side of the secondary support vertical plate 6; Figure 4 , Figure 8 As shown, the servo motor 3 on the top surface of the bearing platform 1 drives the meshing guide thread rod 2 to rotate through the first sprocket mechanism 11. The rotating guide thread rod 2 drives the threaded auxiliary bearing vertical plate 6, the upper mold body 7, and the upper side mold body 32 to slide to the left. First, the upper side mold body 32 contacts the lower side mold body 14 on both sides of the main bearing vertical plate 4.
[0044] A drive gear 17 is rotatably mounted on the left inner center of the lower mold body 5 via a bearing. Driven racks 18 are slidably mounted on both the front and rear ends of the left inner side of the lower mold body 5. The outer ends of the driven racks 18 on both the front and rear sides are fixedly connected to the inner ends of the lower mold body 14, and both the driven racks 18 on both the front and rear sides are meshed with the drive gear 17. A push plate 19 is slidably mounted on the right inner side of the lower mold body 5. Lifting sleeves 34 are rotatably mounted on both the front and rear ends of the right inner side of the lower mold body 5 via bearings. Guide gears 21 are fixedly mounted on the left ends of both the front and rear lifting sleeves 34, and both the guide gears 21 on both the front and rear sides are meshed with the driven racks 18 on both the front and rear sides inside the lower mold body 5. Lifting threaded rods 20 are threadedly connected to the inside of each lifting sleeve 34, and the right ends of the lifting threaded rods 20 on both the front and rear sides are fixedly connected to the inner wall of the push plate 19. Figures 9-10As shown, the material is pressed against the surface of the lower mold body 5 by the upper mold body 7 to prevent displacement. The upper mold body 32 continuously presses the lower mold body 14 to slide inward, so that it pushes the driven rack 18 inward along the limiting slide rod 13. During this process, the driven rack 18 drives the guide gear 21 and the lifting sleeve 34 to rotate. The lifting threaded rod 20, which is threaded to the lifting sleeve 34, drives the top material push plate 19 to slide to the left and be stored inside the lower mold body 5. At the same time, the extensibility of the return spring 12 keeps the upper mold body 7 and the lower mold body 5 in contact with the material, so as not to affect the molding of the material.
[0045] The upper mold bodies 32 on both the front and rear sides are correspondingly distributed with the lower mold bodies 14 on both the front and rear sides, and the joints between the symmetrically arranged upper mold bodies 32 and lower mold bodies 14 have an inclined structure to achieve the effect of extrusion and pushing; for example Figure 8 As shown, the inwardly moving lower die body 14 allows the two ends of the material to be placed in the rolling guide groove 16 opened on its inner side, and the inward pressure of the lower die body 14 bends the two ends of the material. This bend can be rolled along the rolling guide groove 16 to form a specific desired bend and roll.
[0046] Working principle: Before using this type of horizontal pressing, bending, and rolling die, it is necessary to check the overall condition of the device to ensure it can operate normally. Figure 1 - Figure 11 As shown, firstly, the servo motor 3 drives the guide thread rod 2 to rotate through the first sprocket mechanism 11. The bevel gear group 33 drives the drive shaft 28, the sector gear 29, and the drive gear 30 to loosen the traction steel cable 31, so that the material blocking baffle 26 blocks the feeding slot 25 to facilitate subsequent feeding.
[0047] The top of the feeding bracket 8 rotates the winding shaft 22, causing the feeding sliding plate 10 at the bottom of the traction rope 24 to slide up and down along the guide groove 9 to the outer wall away from the lower die body 5 under traction. This allows the material to be manually fed through the feeding groove in the feeding sliding plate 10 to slide to the right outer wall of the lower die body 5, thus completing the feeding before stamping. The feeding sliding plate 10 ensures that the material is always in the center position, preventing the two ends of the material from being of different lengths after being rolled.
[0048] The material is pressed against the surface of the lower mold body 5 by the upper mold body 7 to prevent it from shifting. The upper mold body 32 continuously presses the lower mold body 14 on both sides to slide inward. During this process, the driven rack 18 drives the guide gear 21 and the lifting sleeve 34 to rotate. The lifting threaded rod 20, which is threaded to the lifting sleeve 34, drives the top push plate 19 to slide to the left and be stored inside the lower mold body 5. At the same time, the extensibility of the return spring 12 keeps the upper mold body 7 and the lower mold body 5 in contact with the material, so as not to affect the stamping of the material and ensure the qualification rate of the material forming.
[0049] The lower mold body 14 allows the two ends of the material to be placed in the rolling guide groove 16 opened on its inner side, and the lower mold body 14 moves inward to bend the two ends of the material. This bending can be rolled along the rolling guide groove 16 to form a specific required bend and roll. At the same time, it can also ensure that the material will not be displaced or misaligned during the rolling process.
[0050] When the lower die body 14 is extended by the limit spring 15, it resets and pushes the ejector plate 19 to slide the workpiece outward. At the same time, the blocking baffle 26 slides to the right, so that the unloading slot 25 is open so that the stamped workpiece can be unloaded, thus forming a complete stamping, bending and rolling process, saving the tedious steps of manual loading and unloading.
[0051] In the description of this invention, unless otherwise stated, "a plurality of" means two or more; the terms "upper," "lower," "left," "right," "inner," "outer," "front end," "rear end," "head," "tail," etc., indicate the orientation or positional relationship based on the orientation or positional relationship shown in the accompanying drawings, and are only for the convenience of describing the 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, and therefore should not be construed as a limitation of the invention. Furthermore, the terms "first," "second," "third," etc., are used for descriptive purposes only and should not be construed as indicating or implying relative importance.
[0052] In the description of this invention, it should be noted that, unless otherwise explicitly specified and limited, the terms "connected" and "linked" should be interpreted broadly. For example, they can refer to a fixed connection, a detachable connection, or an integral connection; they can refer to a mechanical connection or an electrical connection; they can refer to a direct connection or an indirect connection through an intermediate medium. Those skilled in the art can understand the specific meaning of the above terms in this invention based on the specific circumstances.
[0053] Although the present invention 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 invention should be included within the protection scope of the present invention.
Claims
1. A horizontal pressing, bending and rolling die, comprising a bearing platform (1) and guide threaded rods (2) rotatably disposed on the front and rear sides of the top surface of the bearing platform (1) via bearings, and a servo motor (3) is fixedly disposed on the rear right side of the top surface of the bearing platform (1). The main bearing vertical plate (4) is fixedly installed on the left side of the top surface of the bearing platform (1), and the lower mold body (5) is fixedly installed at the center position of the right side of the main bearing vertical plate (4). Its features are, Also includes: The top right side of the bearing platform (1) is provided with a secondary bearing vertical plate (6), and the upper mold body (7) is slidably provided at the center position of the left side of the secondary bearing vertical plate (6). Among them, a feeding bracket (8) is fixedly installed on the left side of the top surface of the bearing platform (1), and a guide groove (9) is opened on the right side of the top surface of the feeding bracket (8), and a feeding sliding plate (10) is slidably installed in the guide groove (9) on the top surface of the feeding bracket (8). A material discharge slot (25) is provided at the center of the left side of the bearing platform (1), and a material blocking baffle (26) is slidably provided above the material discharge slot (25). The front and rear sides of the right end of the material blocking baffle (26) are connected to the inner wall of the right side of the material discharge slot (25) by a traction spring (27). The material discharge slot (25) is closed and opened by sliding the material blocking baffle (26). The right ends of the guide thread rods (2) on the front and rear sides of the top of the bearing platform (1) are connected to each other by the first sprocket mechanism (11), and the right end of the rear guide thread rod (2) is fixedly connected to the output shaft end of the servo motor (3), and the middle thread of the guide thread rods (2) on the front and rear sides is connected to the outer end of the auxiliary bearing vertical plate (6). The top left end of the bearing platform (1) is provided with a drive shaft (28) on both the front and rear sides via bearings. The top end of the drive shaft (28) is connected to the left outer wall of the guide thread rod (2) via a bevel gear set (33). A sector gear (29) is fixedly provided on the lower outer wall of the drive shaft (28). The front and rear sides of the top of the bearing platform (1) are provided with a drive gear (30) via a torsion spring. The sector gears (29) on the front and rear sides of the top of the bearing platform (1) are respectively meshed and connected to the outer wall of the drive gear (30), and the shafts at the top of the drive gears (30) on both the front and rear sides are connected to the outer end of the traction cable (31), and the inner ends of the traction cables (31) on both the front and rear sides are fixedly connected to the right outer wall of the material blocking baffle (26) inside the material discharge slot (25). The upper mold body (32) is fixedly installed at both the front and rear ends of the left side of the auxiliary bearing vertical plate (6). The main bearing vertical plate (4) has a lower mold body (14) at both the front and rear ends on the right side, and the upper mold body (32) and the lower mold body (14) are symmetrically arranged and their joints are in an inclined structure for extrusion and pushing.
2. The horizontal pressing, bending, and rolling die according to claim 1, characterized in that: The secondary support vertical plate (6) and the internal upper mold body (7) are connected to each other by a reset spring (12).
3. The horizontal pressing, bending, and rolling die according to claim 1, characterized in that: The main bearing vertical plate (4) is fixedly provided with limiting slide rods (13) on both the front and rear sides. The outer walls of the limiting slide rods (13) on both the front and rear sides are slidably connected to the left end of the lower mold body (14). The lower mold body (14) on both the front and rear sides is connected to the limiting slide rods (13) by limiting springs (15). The inner middle of the lower mold body (14) on both the front and rear sides is provided with a rolling guide groove (16).
4. A horizontal pressing, bending, and rolling die according to claim 3, characterized in that: The lower mold body (5) has a drive gear (17) rotatably mounted on the left inner center position via a bearing, and the lower mold body (5) has driven racks (18) slidably mounted on both the front and rear ends of the left inner side. The outer ends of the driven racks (18) on both the front and rear sides are fixedly connected to the inner end of the lower mold body (14), and the driven racks (18) on both the front and rear sides are meshed with the drive gear (17).
5. A horizontal pressing, bending, and rolling die according to claim 4, characterized in that: The lower mold body (5) has a sliding push plate (19) inside the right side, and the lower mold body (5) has lifting sleeves (34) rotating through bearings at both the front and rear ends of the right side. The left ends of the lifting sleeves (34) on both the front and rear sides are fixedly provided with guide gears (21), and the guide gears (21) on both the front and rear sides are meshed with the driven racks (18) on both the front and rear sides inside the lower mold body (5). The lifting sleeves (34) are threaded with lifting thread rods (20), and the right ends of the lifting thread rods (20) on both the front and rear sides are fixedly connected to the inner wall of the push plate (19).
6. A horizontal pressing, bending, and rolling die according to claim 1, characterized in that: The top front and rear sides of the feeding bracket (8) are provided with a winding shaft (22) through bearings. The left ends of the winding shafts (22) on the front and rear sides are connected to the left ends of the guide thread rods (2) on the front and rear sides through a second sprocket mechanism (23). The right outer wall of the winding shafts (22) on the front and rear sides is connected to the top of the traction rope (24). The bottom ends of the traction ropes (24) on the front and rear sides are fixedly connected to the outer wall of the feeding sliding plate (10).