Anti-blocking device of aluminum profile notching and threading integrated machine
By designing an anti-jamming device for the aluminum profile toothing and strip threading integrated machine, automatic feeding and quick replacement of auxiliary wheels are realized, solving the problem of time-consuming automatic feeding and auxiliary wheel replacement in the existing technology, and improving production efficiency and equipment utilization.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- HAIBAISEN TIANWEI ENERGY SAVING & ENVIRONMENTAL PROTECTION TECH (SHAANXI) CO LTD
- Filing Date
- 2025-05-21
- Publication Date
- 2026-06-19
AI Technical Summary
The existing aluminum profile cutting and strip threading integrated machine cannot achieve automatic feeding, resulting in low production efficiency. In addition, the traditional method of changing auxiliary wheels is time-consuming and affects the utilization rate of the equipment.
An anti-jamming device for an integrated machine for cutting and threading aluminum profiles was designed. The automatic feeding is achieved through a transmission system driven by a motor, and a quick-change structure is adopted, including the cooperation of springs, sliding blocks and slots, to achieve quick disassembly and assembly of auxiliary wheels.
It enables automatic feeding of aluminum profiles and rapid replacement of auxiliary wheels, improving production efficiency and equipment utilization, and reducing manual operation time and equipment downtime.
Smart Images

Figure CN224373503U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of aluminum profile processing technology, and in particular to an anti-jamming device for an integrated machine for cutting and threading aluminum profiles. Background Technology
[0002] The aluminum profile serration and strip insertion integrated machine is a professional piece of equipment that integrates the serration and strip insertion processes of aluminum profiles to achieve automated continuous processing. It is widely used in door and window manufacturing and curtain wall engineering, and has significant advantages such as improving production efficiency, ensuring product quality, saving costs, and enhancing market competitiveness. The aluminum profile serration and strip insertion integrated machine is equipped with an anti-jamming device, which can ensure the continuity of processing to improve production efficiency, protect equipment to reduce failure rate and extend service life and reduce maintenance costs, improve product quality by ensuring the correct position and posture of aluminum profiles during processing, thereby improving consistency and pass rate, and ensure personnel safety by reducing the occurrence of jamming and reducing the opportunity for operators to come into contact with dangerous areas.
[0003] A search revealed Chinese Patent Publication No. CN217571156U, which discloses an integrated tooth-cutting and strip-threading machine. The machine includes a machine base, on which a clamping device, a guide wheel device, and a tooth-cutting device are sequentially arranged. The clamping device includes a first slide rail mounted on a base, on which at least two clamping components are mounted. Each clamping component has a clamping roller. The tooth-cutting device includes at least one tooth-cutting cutter and a first motor for driving the tooth-cutting cutter to rotate. A single tooth-cutting cutter and two clamping components form a tooth-cutting and strip-threading channel. The beneficial effect of this invention is that it can simultaneously tooth-cut and thread multiple aluminum profiles.
[0004] The aforementioned patent specification mentions that "by setting multiple tooth-cutting cutters and clamping components on the machine base, multiple tooth-cutting and strip-threading channels are formed for the tooth-cutting and strip-threading processing of aluminum profiles, thereby realizing the tooth-cutting and strip-threading processing of multiple aluminum profiles at one time. Compared with the prior art, which can only process one aluminum profile at a time, this greatly improves the processing efficiency of aluminum profile tooth-cutting and strip-threading." Although the aforementioned patent can process multiple aluminum profiles simultaneously, it cannot achieve automatic feeding. Therefore, an anti-jamming device for an integrated aluminum profile tooth-cutting and strip-threading machine is proposed to solve the above problem. Utility Model Content
[0005] To overcome the above shortcomings, this utility model provides an anti-jamming device for an integrated machine for cutting and threading aluminum profiles, aiming to improve the problem that automatic feeding cannot be achieved in the prior art.
[0006] To achieve the above objectives, the present invention adopts the following technical solution:
[0007] An anti-jamming device for an integrated aluminum profile toothing and strip threading machine includes a support mechanism, a strip threading mechanism fixedly connected to the top of the support mechanism, a toothing mechanism fixedly connected to the top of the support mechanism, an auxiliary mechanism fixedly connected to the top of the support mechanism, and a feeding mechanism fixedly connected to the outside of the support mechanism.
[0008] The feeding mechanism includes a conveyor belt, a support platform is fixedly connected to the outside of the conveyor belt, two outer shells are fixedly connected to the inside of the support platform, a second motor is fixedly connected to the outside of the outer shell, a driving column is fixedly connected to the driving end of the second motor, and a limiting component is fixedly connected inside the auxiliary mechanism.
[0009] The above method involves the worker placing the aluminum profile in the storage box with the toothed side facing down, starting motor two to rotate the drive column, and the aluminum profile falling into the drive column's slot and then rotating onto the conveyor belt. The conveyor belt then sends the aluminum profile to the outside of the auxiliary wheel. Motor one drives the gear to open its teeth, and after opening the teeth, the aluminum profile is brought to the bottom of the strip threader for threading. When the auxiliary wheel wears out, the sliding rod is pulled up to disengage the sliding block from the slot, the limiting ring is removed, and the auxiliary wheel is replaced. The sliding rod is then slid back to allow the spring to push the sliding block into the slot and fix it. Adjusting the adjusting plate on the connecting rod can prevent material blockage. The double gear can process two aluminum profiles simultaneously.
[0010] As a further description of the above technical solution:
[0011] The limiting component includes a spring, one end of which is fixedly connected to the inside of the auxiliary mechanism, and the other end of which is fixedly connected to a sliding block;
[0012] The above solution is as follows: In the aluminum profile toothing and strip threading integrated machine, when the auxiliary wheel needs to be replaced, pull up the sliding rod to drive the sliding block to overcome the spring force and disengage from the fixed rod slot. Remove the limiting ring for replacement. After the new auxiliary wheel is installed, the sliding rod slides in, and the inner wall of the fixed rod squeezes the sliding block until the spring rebounds at the slot and pushes it in to fix it.
[0013] As a further description of the above technical solution:
[0014] The support mechanism includes a workbench, a processing plate is fixedly connected to the top of the workbench, and a control plate is fixedly connected to the outside of the workbench.
[0015] The above solution provides stable support for the entire machine. The top processing plate serves as the bearing surface for aluminum profile cutting, strip threading, and other processing operations, ensuring stable processing. The outer control plate is used to control various components of the equipment, such as starting the motor and adjusting parameters, to achieve precise control of the cutting, strip threading, and other processing procedures.
[0016] As a further description of the above technical solution:
[0017] The strip threading mechanism includes two fixed blocks, each of which is rotatably connected to a threaded rod. An adjusting block is slidably connected to the inner side of each fixed block, and a strip threader is fixedly connected to the inside of each fixed block.
[0018] The above method involves rotating the threaded rod, which drives the adjusting block to slide inside the fixed block via the threaded transmission. This adjusts the spacing between the two sides of the strip inserter to accommodate different specifications of aluminum profiles. After the aluminum profile is toothed, it is conveyed to the bottom of the strip inserter. The strip inserter then precisely inserts the thermal insulation strip into the aluminum profile groove at the appropriate position, completing the strip inserting process.
[0019] As a further description of the above technical solution:
[0020] The gear-opening mechanism includes two motors, and each of the two motors is fixedly connected to a gear.
[0021] The above solution involves starting two motors, each driving a gear to rotate at high speed. The two gears work synchronously, simultaneously machining the teeth on both sides of the aluminum profile. The speed and direction of rotation of the gears are controlled by the drive of motor one, ensuring the accuracy and efficiency of the machining process and meeting the requirements of the subsequent strip threading process of the aluminum profile.
[0022] As a further description of the above technical solution:
[0023] The auxiliary mechanism includes multiple fixed blocks 2, each of which has a connecting rod fixedly connected inside. Three adjusting plates are slidably connected to the outside of the connecting rod. A fixed rod is fixedly connected to the top of the adjusting plate. A sliding rod is slidably connected inside the fixed rod. A limiting ring is fixedly connected to the outside of the sliding rod. Two slots are formed inside the fixed rod.
[0024] The above solution provides a sliding track for the adjusting plate by connecting rods within multiple fixed blocks. The position of the adjusting plate can be changed by sliding, preventing blockage of aluminum profile feeding. Inside the fixed rod at the top of the adjusting plate, the sliding rod can slide up and down. The limiting ring on the outside of the sliding rod is used to fix the auxiliary wheel. When the auxiliary wheel needs to be replaced, pull the sliding rod upward, causing the limiting ring to move upward, and the sliding block inside the sliding rod disengages from the fixed rod slot. After replacement, slide the sliding rod back, and the sliding block is squeezed into the slot. The spring pushes the sliding block to fix it, realizing quick disassembly and assembly and stable fixation of the auxiliary wheel.
[0025] As a further description of the above technical solution:
[0026] The outer side of the sliding block is slidably connected to the inside of the slot, and one end of the spring is fixedly connected to the inside of the sliding rod;
[0027] The above solution works as follows: When replacing the auxiliary wheel, pull up the sliding rod to move the sliding block out of the slot against the spring force. After installing the new auxiliary wheel, push the sliding rod in. The sliding block is squeezed back by the inner wall of the fixed rod. When it reaches the slot, the spring rebounds and pushes the sliding block into the slot, so that the sliding rod and the fixed rod are firmly connected, thus completing the quick installation and fixing of the auxiliary wheel.
[0028] As a further description of the above technical solution:
[0029] A storage box is fixedly connected to the top of the outer casing, and the outer side of the drive column is rotatably connected to the inside of the outer casing;
[0030] The above solution involves placing the aluminum profile into the storage box at the top of the outer casing, starting the second motor to drive the column to rotate inside the casing, and then sending the aluminum profile into the slot and onto the conveyor belt. This causes the outer side of the column to rotate in accordance with the inner wall of the casing, ensuring stable feeding. When the auxiliary wheel is replaced, the spring, through compression and rebound, helps the sliding block to accurately engage in the slot, achieving rapid fixation.
[0031] This utility model has the following beneficial effects:
[0032] 1. In this utility model, the second motor drives the drive column, which works in conjunction with the outer shell and the conveyor belt. The outer shell works in conjunction with the storage box, thereby achieving the effect of automatic feeding of aluminum profiles. Automatic feeding reduces the time spent on manual handling and placing of aluminum profiles. The second motor drives the drive column to work continuously and stably, which can quickly transfer aluminum profiles from the storage box to the conveyor belt, achieving an efficient feeding process, thereby improving the production efficiency of the entire tooth-cutting and strip-threading integrated machine and increasing the processing output per unit time.
[0033] 2. In this utility model, a fixed rod works in conjunction with a sliding rod, which in turn works with a spring and a limiting ring. The spring works with a sliding block, and the sliding block works with a slot, thus achieving the effect of quick replacement of the auxiliary wheel. During equipment operation, wear and tear on the auxiliary wheel due to prolonged use is a common problem. Traditional replacement methods require disassembling multiple parts, which takes a long time. However, with this quick replacement structure, simply pulling the sliding rod upwards allows the limiting ring to be easily removed. After replacing the auxiliary wheel, the sliding rod can be slid back to the fixed rod, greatly shortening the time for replacing the auxiliary wheel, reducing equipment downtime, and improving equipment utilization. Attached Figure Description
[0034] Figure 1 This is a three-dimensional schematic diagram of an anti-jamming device for an integrated machine for cutting and threading aluminum profiles, as proposed in this utility model.
[0035] Figure 2 This is a schematic diagram of the processing plate of the anti-jamming device for an integrated machine for cutting and threading aluminum profiles according to this utility model.
[0036] Figure 3 for Figure 2 Enlarged view of point A in the middle;
[0037] Figure 4 for Figure 2 Enlarged view of point B in the middle.
[0038] Legend:
[0039] 1. Support mechanism; 11. Workbench; 12. Control panel; 13. Processing panel; 2. Strip threading mechanism; 21. Fixing block one; 22. Threaded rod; 23. Adjusting block; 24. Strip threader; 3. Gear cutting mechanism; 31. Motor one; 32. Gear cutting; 4. Auxiliary mechanism; 41. Fixing block two; 42. Connecting rod; 43. Adjusting plate; 44. Fixing rod; 45. Sliding rod; 46. Limiting component; 461. Spring; 462. Sliding block; 47. Limiting ring; 48. Slot; 5. Unloading mechanism; 51. Conveyor belt; 52. Support platform; 53. Motor two; 54. Housing; 55. Storage box; 56. Drive column. Detailed Implementation
[0040] 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.
[0041] Reference Figure 1 , Figure 3 Figure 4 The present invention provides an embodiment of an anti-jamming device for an integrated machine for cutting and threading aluminum profiles, including a support mechanism 1, which provides a stable foundation for the whole machine and ensures that no shaking or deviation occurs during the operation of each mechanism. The top of the support mechanism 1 is fixedly connected to a threading mechanism 2. The threading mechanism 2 is precisely positioned so that the heat insulation strip can be quickly and accurately threaded into the aluminum profile groove to complete the threading process.
[0042] The top of the support mechanism 1 is fixedly connected to the tooth-opening mechanism 3. The tooth-opening mechanism 3 can efficiently complete the tooth-opening process of aluminum profiles with high-speed rotating parts, ensuring the tooth profile accuracy. The top of the support mechanism 1 is fixedly connected to the auxiliary mechanism 4. The auxiliary mechanism 4 works in coordination with auxiliary wheels and other components to ensure that the aluminum profiles maintain a stable posture during the transmission process and avoid deviation. The outside of the support mechanism 1 is fixedly connected to the unloading mechanism 5. The unloading mechanism 5 serves as the starting point for aluminum profile processing and can orderly transport the aluminum profiles to the subsequent processing station.
[0043] The feeding mechanism 5 includes a conveyor belt 51, which smoothly feeds aluminum profiles from the storage box 55 to the outside of the auxiliary wheel at a stable conveying speed. A support platform 52 is fixedly connected to the outside of the conveyor belt 51, which provides stable support for the conveyor belt 51 and prevents the conveyor belt 51 from sagging or shaking when conveying aluminum profiles. Two outer shells 54 are fixedly connected inside the support platform 52. The outer shells 54 provide a closed rotation space for the drive column 56 to prevent aluminum profiles from falling accidentally during the transmission process. A storage box 55 is fixedly connected to the top of the outer shells 54. The storage box 55 can hold a certain number of aluminum profiles, reducing frequent feeding operations and improving processing continuity.
[0044] A second motor 53 is fixedly connected to the outer side of the outer casing 54. The second motor 53 outputs stable power to drive the drive column 56 to rotate continuously, ensuring a stable and efficient aluminum profile feeding process. The drive end of the second motor 53 is fixedly connected to the drive column 56. The slot 48 on the outer side of the drive column 56 is precisely matched with the aluminum profile, which can reliably grab and transport the aluminum profile. The outer side of the drive column 56 is rotatably connected to the inside of the outer casing 54 to ensure smooth rotation of the drive column 56 and to limit the transmission path of the aluminum profile in cooperation with the outer casing 54. The auxiliary mechanism 4 is fixedly connected to the inside of the auxiliary mechanism 4. Through the cooperation of various parts, the auxiliary wheel can be quickly disassembled and assembled, which is convenient for maintenance and replacement.
[0045] Specifically, the aluminum profile toothing and strip insertion integrated machine is based on the support mechanism 1 to ensure stable operation of the whole machine. The feeding mechanism 5 is driven by the motor 53 to rotate the column 56, which sends the aluminum profile in the storage box 55 to the auxiliary mechanism 4 via the conveyor belt 51. During the transmission, the support platform 52 and the outer shell 54 ensure stable transmission and prevent the aluminum profile from falling. The auxiliary mechanism 4 adjusts the channel width through the adjustment plate 43 to avoid blockage. The limiting component 46 can realize the quick disassembly and assembly of the auxiliary wheel to ensure the stability of the aluminum profile transmission posture. The toothing mechanism 3 is driven by the motor 31 to rotate the toothing gear 32 at high speed to complete the toothing of the aluminum profile and ensure the tooth shape accuracy. Then the aluminum profile is sent to the strip insertion mechanism 2, which quickly and accurately inserts the heat insulation strip into the aluminum profile groove through precise positioning. All mechanisms work together to realize the automated continuous processing of aluminum profiles from feeding, transmission, toothing to strip insertion, improving production efficiency and product quality.
[0046] Reference Figures 1 to 4 The limiting component 46 includes a spring 461, which provides elastic restoring force and provides a power basis for the quick disassembly and assembly of the auxiliary wheel. One end of the spring 461 is fixedly connected to the inside of the auxiliary mechanism 4. The stable connection ensures that the spring 461 will not be displaced during operation and maintains its functional stability. The other end of the spring 461 is fixedly connected to a sliding block 462. When the auxiliary wheel needs to be replaced, the spring 461 can push the sliding block 462 to accurately engage or disengage from the interior of other parts.
[0047] Specifically, the limiting component 46 mainly relies on the cooperation of spring 461 and sliding block 462 to achieve its function. One end of spring 461 is firmly connected to the auxiliary mechanism 4 and maintains a fixed position during operation. Its elastic restoring force is the core power. The other end is connected to sliding block 462. When replacing the auxiliary wheel, the sliding rod 45 is pulled upward to disengage it from the slot 48 of the fixed rod 44, completing the disassembly. After installing the new auxiliary wheel, the sliding rod 45 slides into the fixed rod 44, and the sliding block 462 is squeezed back by the inner wall. When it reaches the slot 48, spring 461 releases its elastic potential energy, pushing the sliding block 462 to accurately engage in the slot 48, quickly fixing the auxiliary wheel and ensuring stable operation of the equipment.
[0048] The support mechanism 1 includes a workbench 11, which serves as the bottom load-bearing structure of the entire equipment. Its stable structure provides solid support for the operation of the equipment, ensuring that the equipment remains balanced and stable during operation. A processing plate 13 is fixedly connected to the top of the workbench 11. The processing plate 13 provides a flat and stable working surface for processing operations such as tooth cutting and strip threading of aluminum profiles, ensuring that the aluminum profiles are positioned accurately during processing. A control plate 12 is fixedly connected to the outside of the workbench 11. The control plate 12 integrates various operation and control functions of the equipment. Operators can conveniently adjust the motor operation and parameter settings through the control plate 12 to achieve precise control of the equipment operation.
[0049] Specifically, in the support mechanism 1, the workbench 11 supports the equipment with its sturdy structure, ensuring stable and balanced operation and providing solid support for the equipment. The top processing plate 13 provides a flat working surface, ensuring accurate positioning during aluminum profile processing and facilitating operations such as tooth cutting and strip threading. The outer control plate 12 integrates operation control functions, allowing operators to adjust motor operation and parameter settings to achieve precise control of the equipment, enabling all mechanisms to work together to complete aluminum profile processing.
[0050] The strip insertion mechanism 2 includes two fixed blocks 21, which form a stable frame structure, providing an installation base and support for the parts of the strip insertion mechanism 2. Each of the two fixed blocks 21 is rotatably connected to a threaded rod 22. Rotating the threaded rod 22 allows for precise adjustment of the position of the adjusting block 23 to accommodate different specifications of aluminum profiles. The adjusting block 23 is slidably connected to the inner side of the fixed block 21, allowing for smooth sliding within the fixed block 21 and flexible adjustment of the working position and spacing of the strip inserter 24. The strip inserter 24 is fixedly connected inside the two fixed blocks 21. With the stable support of the fixed blocks 21, the strip inserter 24 can accurately and efficiently insert the thermal insulation strip into the toothed aluminum profile.
[0051] Specifically, the strip insertion mechanism 2 is based on two fixed blocks 21 to construct a stable frame, providing installation and support for the parts. The internally rotatably connected threaded rod 22 can precisely adjust the position of the adjusting block 23 by rotation, thereby adapting to different specifications of aluminum profiles. The adjusting block 23 can slide smoothly inside the fixed block 21, flexibly changing the working position and spacing of the strip inserter 24. The strip inserter 24, fixedly connected inside the fixed block 21, can accurately and efficiently insert the thermal insulation strip into the aluminum profile that has completed the toothing process under stable support. The entire mechanism achieves precise control of the strip insertion operation of different specifications of aluminum profiles through the coordinated cooperation of various components, ensuring the efficiency and accuracy of the strip insertion work.
[0052] The tooth-cutting mechanism 3 includes two motors 31, which provide a strong and stable power source to ensure the continuous and efficient operation of the tooth-cutting operation. The drive ends of the two motors 31 are fixedly connected to the tooth-cutting gears 32. The motors 31 drive the tooth-cutting gears 32 to rotate at high speed. With precise speed and torque control, the tooth grooves that meet the requirements can be processed quickly and accurately on the surface of the aluminum profile. At the same time, the two tooth-cutting gears 32 can simultaneously cut the teeth of two aluminum profiles, which greatly improves the processing efficiency.
[0053] Specifically, the tooth-cutting mechanism 3 consists of two motors 31 and a tooth-cutting gear 32. The motors 31 provide strong and stable power to ensure efficient and continuous tooth-cutting operation. The tooth-cutting gear 32 connected to its drive end rotates at high speed under the drive of the motors 31. By precisely controlling the speed and torque, qualified tooth grooves are quickly and accurately processed on the surface of the aluminum profile. Moreover, the two tooth-cutting gears 32 can simultaneously cut teeth on two aluminum profiles, significantly improving processing efficiency.
[0054] The auxiliary mechanism 4 includes multiple fixed blocks 41, which form a stable support structure for the auxiliary mechanism 4, ensuring the stability of the entire auxiliary mechanism 4 during operation. Each of the multiple fixed blocks 41 is fixedly connected to a connecting rod 42, which serves as a sliding track for the adjusting plate 43, providing a smooth and stable sliding path, allowing the adjusting plate 43 to move flexibly. Three adjusting plates 43 are slidably connected to the outside of the connecting rod 42. By sliding the adjusting plates 43, the width of the aluminum profile transmission channel can be precisely adjusted, effectively avoiding material blockage.
[0055] A fixed rod 44 is fixedly connected to the top of the adjusting plate 43. The fixed rod 44 provides stable support and positioning foundation for the sliding rod 45 and the limiting ring 47. The sliding rod 45 is slidably connected inside the fixed rod 44. The sliding rod 45 can slide smoothly inside the fixed rod 44, which facilitates the replacement of the auxiliary wheel. One end of the spring 461 is fixedly connected inside the sliding rod 45. When the spring 461 is compressed, it stores elastic potential energy and provides power for the reset and fixation of the sliding block 462. The limiting ring 47 is fixedly connected to the outside of the sliding rod 45. The limiting ring 47 can effectively fix the auxiliary wheel and prevent it from shaking or shifting during operation.
[0056] The fixed rod 44 has two slots 48 inside. The slots 48 provide a precise positioning space for the sliding block 462, ensuring the stability of the auxiliary wheel after installation. The outer side of the sliding block 462 is slidably connected to the inside of the slots 48. When the sliding block 462 is engaged in the slots 48, it can firmly fix the sliding rod 45 in the fixed rod 44, realizing the reliable installation of the auxiliary wheel.
[0057] Specifically, the auxiliary mechanism 4 uses multiple fixed blocks 41 to build a stable structure, ensuring the mechanism works steadily. The connecting rod 42 is fixed inside the fixed block 41, providing a sliding track for the adjusting plate 43. By sliding the adjusting plate 43, the width of the aluminum profile transmission channel can be precisely adjusted to avoid material blockage. The fixed rod 44 at the top of the adjusting plate 43 provides support and positioning for the sliding rod 45 and the limiting ring 47. The sliding rod 45 can slide smoothly inside the fixed rod 44, facilitating the replacement of the auxiliary wheel. One end of the spring 461 is connected to the sliding rod 45. When compressed, it stores energy to power the reset and fixation of the sliding block 462. The limiting ring 47 fixes the auxiliary wheel to prevent it from shaking or shifting. The slot 48 inside the fixed rod 44 cooperates with the sliding block 462. When the sliding block 462 is engaged in the slot 48, the sliding rod 45 can be firmly fixed, achieving reliable installation and stable operation of the auxiliary wheel.
[0058] Working principle: When the operator needs to start processing the aluminum profile, the aluminum profile can be placed inside the storage box 55, with the side to be started facing down. Then, the second motor 53 is started, which drives the drive column 56 to rotate. The drive column 56 has a groove on its outer side that fits the aluminum profile. The aluminum profile will fall into the groove and, as the drive column 56 rotates, fall out of the outer casing 54 and reach the top of the conveyor belt 51. After the conveyor belt 51 is started, it can transport the aluminum profile to the outer side of multiple auxiliary wheels. Then, the first motor 31 can be started to drive the gear 32 to perform tooth cutting processing on the aluminum profile.
[0059] As the gear 32 rotates, the aluminum profile is carried to the bottom of the threader 24. The threader 24 then performs the threading operation on the aluminum profile. After the auxiliary wheel has been working for a long time, it will wear down due to the aluminum profile. At this time, the sliding rod 45 can be pulled upwards. The sliding rod 45 drives the sliding block 462 inside it, causing the sliding block 462 to disengage from the slot 48 inside the fixed rod 44. Then, the limiting ring 47 can be removed from the top of the auxiliary wheel. After the new auxiliary wheel is fitted on the outside of the fixed rod 44, the sliding rod 45 can be slid back into the fixed rod 44. When the sliding block 462 slides into the fixed rod 44, it will be pressed into the sliding rod 45 by the inner wall of the fixed rod 44. When the sliding block 462 slides to the outside of the slot 48, the spring 461 will push the sliding block 462 into the slot 48, restricting the sliding rod 45 inside the fixed rod 44, thereby realizing the quick replacement of the auxiliary wheel.
[0060] Three adjusting plates 43 are slidably connected to the outer side of the connecting rod 42. This allows for adjustment of the adjusting plates 43 on the outer side of the connecting rod 42, thus preventing material blockage. Simultaneously, two gears 32 are provided, enabling simultaneous processing of two aluminum profiles.
[0061] 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. An anti-jamming device for an integrated aluminum profile toothing and strip threading machine, comprising a support mechanism (1), characterized in that: The top of the support mechanism (1) is fixedly connected to a strip threading mechanism (2), the top of the support mechanism (1) is fixedly connected to a tooth opening mechanism (3), the top of the support mechanism (1) is fixedly connected to an auxiliary mechanism (4), and the outside of the support mechanism (1) is fixedly connected to a feeding mechanism (5). The feeding mechanism (5) includes a conveyor belt (51), a support platform (52) is fixedly connected to the outside of the conveyor belt (51), two shells (54) are fixedly connected inside the support platform (52), a second motor (53) is fixedly connected to the outside of the shell (54), a driving column (56) is fixedly connected to the driving end of the second motor (53), and a limiting component (46) is fixedly connected inside the auxiliary mechanism (4).
2. The anti-jamming device for an integrated aluminum profile toothing and strip threading machine according to claim 1, characterized in that: The limiting component (46) includes a spring (461), one end of which is fixedly connected to the inside of the auxiliary mechanism (4), and the other end of which is fixedly connected to a sliding block (462).
3. The anti-jamming device for an integrated aluminum profile toothing and strip threading machine according to claim 1, characterized in that: The support mechanism (1) includes a workbench (11), a processing plate (13) is fixedly connected to the top of the workbench (11), and a control plate (12) is fixedly connected to the outside of the workbench (11).
4. The anti-jamming device for an integrated aluminum profile toothing and strip threading machine according to claim 1, characterized in that: The strip threading mechanism (2) includes two fixed blocks (21), each of which is rotatably connected to a threaded rod (22). An adjusting block (23) is slidably connected to the inner side of each fixed block (21), and a strip threader (24) is fixedly connected to the inner side of each fixed block (21).
5. The anti-jamming device for an integrated aluminum profile toothing and strip threading machine according to claim 1, characterized in that: The gear-opening mechanism (3) includes two motors (31), and the driving ends of the two motors (31) are fixedly connected with gears (32).
6. The anti-jamming device for an integrated aluminum profile toothing and strip threading machine according to claim 2, characterized in that: The auxiliary mechanism (4) includes multiple fixed blocks (41), each of which is fixedly connected to a connecting rod (42). Three adjusting plates (43) are slidably connected to the outside of the connecting rod (42). A fixed rod (44) is fixedly connected to the top of the adjusting plate (43). A sliding rod (45) is slidably connected to the inside of the fixed rod (44). A limiting ring (47) is fixedly connected to the outside of the sliding rod (45). Two slots (48) are opened inside the fixed rod (44).
7. The anti-jamming device for an integrated aluminum profile toothing and strip threading machine according to claim 6, characterized in that: The outer side of the sliding block (462) is slidably connected to the inside of the slot (48), and one end of the spring (461) is fixedly connected to the inside of the sliding rod (45).
8. The anti-jamming device for an integrated aluminum profile toothing and strip threading machine according to claim 1, characterized in that: The top of the outer casing (54) is fixedly connected to a storage box (55), and the outer side of the drive column (56) is rotatably connected to the inside of the outer casing (54).