Aluminum profile continuous conveying and cutting device

By introducing a linear drive, sprocket and chain drive, and an automatic clamping and collecting system into the aluminum profile cutting device, the problem of discontinuous feeding during mass production of aluminum materials has been solved, realizing automated continuous conveying and efficient cutting of aluminum materials, and improving processing efficiency and stability.

CN122142415APending Publication Date: 2026-06-05SHANDONG LONGKOU SANYUAN ALUMINUM CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Applications(China)
Current Assignee / Owner
SHANDONG LONGKOU SANYUAN ALUMINUM CO LTD
Filing Date
2026-03-24
Publication Date
2026-06-05

AI Technical Summary

Technical Problem

Existing continuous feeding and cutting devices for aluminum profiles require waiting for the next batch of aluminum materials to be ready before they can continue feeding when processing in large quantities. This results in uninterrupted continuous feeding, low processing efficiency, and insufficient long-term operational stability.

Method used

By employing a linear drive, sprocket and chain meshing transmission, automatic clamping and collection system, and inclined guide structure, the system achieves automated continuous conveying, positioning cutting and tail material collection of aluminum materials, avoiding manual intervention.

Benefits of technology

It enables uninterrupted continuous feeding of aluminum materials, improves processing efficiency and equipment stability, simplifies the feeding process, reduces manual operation intensity, and enhances the automation level and operational continuity of the equipment.

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Abstract

The application discloses a kind of aluminium profile continuous conveying cutting device, it is related to aluminium material cutting equipment technical field, including: base, base top end fixedly connected with cutting table, cutting table is provided with limiting piece and cutting piece, base top end fixedly connected with linear driver, linear driver movable end fixedly connected with feeding table, feeding table is provided with the clamping piece of being fixed to the clamping of aluminium material, feeding table is provided with the propelling piece of being moved to aluminium material, cutting table is provided with the collection piece of being collected to the aluminium material tail of being cut;In the application, by propelling piece, the way of sprocket and chain meshing transmission is adopted, aluminium profile directional movement can be stably pushed, the problem of jam, deviation when aluminium material is pushed is eliminated, two groups of propelling plate, when one group of tail material is pushed, another group of aluminium material placed in clamping piece is pushed, uninterrupted continuous feeding of aluminium material is realized, the continuity of aluminium profile conveying efficiency and cutting operation is improved, and long-time stable operation of device is guaranteed.
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Description

Technical Field

[0001] This invention relates to the field of aluminum cutting equipment technology, specifically to a continuous conveying and cutting device for aluminum profiles. Background Technology

[0002] Aluminum, as a lightweight, corrosion-resistant, and easy-to-process metal material, is widely used in many industries such as construction, automobiles, new energy, and electronics. Aluminum profile cutting equipment is a key piece of equipment in the aluminum processing process. It is mainly used to cut aluminum profiles to size and is an important guarantee for realizing large-scale aluminum production and ensuring processing efficiency.

[0003] Existing continuous feeding and cutting devices for aluminum profiles often require waiting for the next batch of aluminum profiles to be ready after one batch is fed before they can continue feeding when processing in large quantities. This makes it impossible to achieve uninterrupted continuous feeding and is difficult to match the efficient processing rhythm of large batches of aluminum profiles. There is still room for improvement in the operational stability of the device during long-term continuous operation. Summary of the Invention

[0004] The purpose of this invention is to address the problems of existing continuous aluminum profile feeding and cutting devices, which often require waiting for the next batch of aluminum materials to be ready after one batch is fed before continuing feeding during mass production. This makes it impossible to achieve uninterrupted continuous feeding, which is difficult to match the efficient processing rhythm of large batches of aluminum materials, and there is still room for improvement in the operational stability of the device during long-term continuous operation. The invention provides a continuous aluminum profile feeding and cutting device.

[0005] To achieve the above objectives, the present invention provides the following technical solution: a continuous conveying and cutting device for aluminum profiles, comprising: a base, a cutting table fixedly connected to the top of the base, a limiting component and a cutting component provided on the cutting table, a linear driver fixedly connected to the top of the base, a feeding table fixedly connected to the movable end of the linear driver, a clamping component for clamping and fixing aluminum material on the feeding table, a pushing component for pushing aluminum material to move on the feeding table, and a collecting component for collecting the cut aluminum material tail material on the cutting table;

[0006] The propulsion component includes a propulsion groove extending through the top of the feeding platform. A bearing seat two is fixedly connected to the top of the feeding platform. A rotating shaft two is installed through the bearing seat two. Four sets of bearing seats two are symmetrically distributed on both sides of the propulsion groove. Two sets of rotating shaft two are installed, each set penetrating two sets of bearing seats two. A set of sprockets is fixedly connected to the outer surface of each set of bearing seats two. A chain is fitted around the outer side of the two sets of sprockets, and the chain meshes with the two sets of sprockets. A motor two is fixedly connected to the side end of the feeding platform. The output end of the motor two passes through the feeding platform and is fixedly connected to one set of rotating shaft two. A connecting rod is fixedly installed on the chain. The connecting rod passes through the propulsion groove, and a propulsion plate is threadedly connected to the portion of the connecting rod that passes through the propulsion groove.

[0007] As a further embodiment of the present invention: the base has a right-angled trapezoidal cross-section with the inclined surface facing upwards. Two sets of linear actuators are provided, which are respectively arranged parallel to the length direction of the cutting table and the width direction of the base. The linear actuator adopts existing technology and is a common mechanical device used to convert rotary motion into linear motion. Its key components include a motor, a lead screw, a nut, a guide rail, and a slider. Its core working principle is that the motor drives the lead screw to rotate, and the nut on the lead screw moves along the lead screw axis during the rotation, thereby converting the rotary motion into linear motion. The nut is connected to the slider, and the slider slides along the guide rail to push the load to achieve linear motion. The moving ends of the two sets of linear actuators are fixedly connected to the feeding table.

[0008] As a further embodiment of the present invention: the limiting member includes a limiting plate that abuts against the top of the cutting table. The top of the limiting plate is provided with a clearance groove and a locking groove, and two sets of locking grooves are symmetrically distributed on both sides of the clearance groove. A connecting plate is fixedly connected to the top of the cutting table. The connecting plate passes through the clearance groove. A threaded rod is fixedly connected to the inner side of the limiting plate. One end of the threaded rod passes through the connecting plate. A nut is threadedly connected to the outer surface of the threaded rod. Two sets of nuts are provided and symmetrically distributed on both sides of the connecting plate. A screw is provided through the top of the locking groove. One end of the screw passes through the locking groove and is threadedly connected to a pre-set threaded hole on the cutting table.

[0009] As a further embodiment of the present invention: the cutting component includes a motor fixedly connected to the inside of the cutting table, a transmission wheel fixedly connected to the output end of the motor, a mounting platform fixedly connected to the bottom of the inside of the cutting table, a bearing seat fixedly connected to the bottom of the mounting platform, a rotating shaft passing through the inner side of the bearing seat, a transmission wheel and a saw blade fixedly connected to both ends of the rotating shaft, a transmission belt sleeved on the outer side of the transmission wheel and the transmission wheel, and the transmission belt meshing with the transmission wheel and the transmission wheel, respectively, a cutting groove is opened through the top of the cutting table, and the top part of the saw blade passes through the cutting groove and extends to the top of the cutting table.

[0010] As a further embodiment of the present invention: the clamping member includes a mounting plate fixedly connected to the top of the feeding table and flush with one side of the feeding table in the width direction. A hinged plate is provided through the side end of the mounting plate and is slidably inserted into the mounting plate. The hinged plate is located on the side away from the cutting table and is arc-shaped. A connecting plate is fixedly connected to the end face of the hinged plate away from the mounting plate. A clamping rod is fixedly connected to the side of the connecting plate facing the mounting plate and passes through the mounting plate and is slidably inserted into the mounting plate. A spring is sleeved on the outside of the clamping rod. The two ends of the spring are fixedly connected to the mounting plate and the connecting plate, respectively. In the initial state, the spring drives the connecting plate to move towards the mounting plate until the spring retracts to its limit position. Multiple sets of clamping rods and springs are provided.

[0011] As a further embodiment of the present invention: a screw is fixedly connected to the center position of the side end of the connecting plate, and a fixing hole is opened at the center position of the side end of the mounting plate. The fixing hole is an internally threaded hole, the screw passes through the fixing hole, and the diameter of the screw is smaller than that of the fixing hole. A fixing sleeve is threadedly connected to the outside of the screw, and the fixing sleeve is threadedly connected to the fixing hole. When it is necessary to fix the position of the clamping rod, the fixing sleeve is rotated to move the fixing sleeve along the axis of the screw towards the mounting plate until the fixing sleeve is inserted into the fixing hole and threadedly connected to the fixing hole. Two sets of clamping components are provided, symmetrically distributed at the top of the feeding table.

[0012] As a further embodiment of the present invention: the collecting component includes a telescopic groove that extends through the top of the cutting table, the telescopic groove having an angle with the width direction of the cutting table, a guide plate being provided inside the cutting table, the guide plate extending through the telescopic groove and slidably inserted into the telescopic groove, the long side of the top of the guide plate having arc surfaces on both sides, a fixing plate being fixedly connected to the side end of the guide plate, and the bottom end of the fixing plate being flush with the bottom end of the guide plate.

[0013] As a further embodiment of the present invention: four sets of fixing plates are provided, symmetrically distributed on both sides of the guide plate. A set of springs is fixedly connected to the top of each set of fixing plates. The top of the springs is fixedly connected to the bottom of the inside of the cutting table. In the initial state, the springs pull the guide plate upward, so that the arc-shaped part of the top of the guide plate passes through the telescopic groove and extends to the top of the cutting table. A collection box is fixedly connected to the side of the feeding table. The top of the collection box is flush with the top of the feeding table, and the side of the collection box is in contact with the side of the cutting table.

[0014] Compared with the prior art, the beneficial effects of the present invention are:

[0015] 1. In this invention, the aluminum profile is automatically and elastically clamped by a clamping component and a spring, eliminating the need for manual tightening and greatly simplifying the feeding process. The curved surface structure of the opening and closing plate makes it easier for workers to operate. Multiple clamping rods ensure that the aluminum material is clamped evenly, effectively preventing the aluminum material from shaking or shifting during conveying and cutting. The fixed sleeve can lock the clamping position and is compatible with aluminum profiles of different widths, improving the adaptability and feeding stability of the device and reducing the intensity of manual operation.

[0016] 2. In this invention, the propulsion component uses a sprocket and chain meshing transmission method, which ensures smooth and slip-free power transmission, precise and controllable pushing stroke, and stable directional movement of aluminum profiles. This eliminates the problems of jamming and deviation during aluminum material pushing. The two sets of propulsion plates can push the tail material while the other set pushes the next set of aluminum materials placed in the clamping component, realizing uninterrupted continuous feeding of aluminum materials, improving the conveying efficiency of aluminum profiles and the continuity of cutting operations, and ensuring the stable operation of the device for a long time.

[0017] 3. In this invention, the guide plate automatically extends and retracts using a collection component and spring two, automatically avoiding interference during aluminum material conveying and automatically resetting after cutting, without interfering with the normal cutting process. Combined with the guiding effect of the inclined surface of the cutting table and the guide plate, the aluminum profile tail material can be automatically slid down and collected in a directional manner without the need for manual shutdown for cleaning. This avoids the tail material accumulating on the cutting table and interfering with the cutting operation, keeps the worktable clean, greatly improves the automation level of the device, and ensures that continuous cutting operations are carried out efficiently and orderly. Attached Figure Description

[0018] Figure 1 This is a schematic diagram of the overall structure of the present invention;

[0019] Figure 2 This is a schematic diagram of the limiting component in this invention;

[0020] Figure 3 This is a schematic diagram of the cutting component in this invention;

[0021] Figure 4 This is a schematic diagram of the clamping component in this invention;

[0022] Figure 5 In this invention Figure 4 A schematic diagram of the structure at point A;

[0023] Figure 6 This is a schematic diagram of the propulsion component in this invention;

[0024] Figure 7 This is a schematic diagram of the propulsion plate in this invention;

[0025] Figure 8 This is a schematic diagram of the structure of the collection box in this invention;

[0026] Figure 9 This is a schematic diagram of the guide plate in this invention.

[0027] In the diagram: 1. Base; 2. Cutting table; 3. Limiting component; 31. Limiting plate; 32. Clearance groove; 33. Locking groove; 34. Connecting plate; 35. Threaded rod; 36. Nut; 37. Screw; 4. Cutting component; 41. Motor 1; 42. Transmission wheel 1; 43. Mounting platform; 44. Bearing seat 1; 45. Rotating shaft 1; 46. Transmission wheel 2; 47. Transmission belt; 48. Saw blade; 49. Cutting groove; 5. Linear actuator; 6. Feeding table; 7. Clamping component; 71. Mounting plate; 72. Opening / closing plate; 73. Linking plate; 74. Clamping rod; 75. Spring 1; 76. Fixing hole; 77. Screw; 78. Fixing sleeve; 8. Propeller; 81. Propeller groove; 82. Bearing seat 2; 83. Rotating shaft 2; 84. Sprocket; 85. Chain; 86. Motor 2; 87. Connecting rod; 88. Propeller plate; 9. Collector; 91. Telescopic groove; 92. Guide plate; 93. Fixing plate; 94. Spring 2; 95. Collector box. Detailed Implementation

[0028] 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.

[0029] Reference Figure 1 In this embodiment of the invention, a continuous conveying and cutting device for aluminum profiles includes: a base 1, wherein the cross-section of the base 1 is a right trapezoid with the inclined surface facing upwards; a cutting table 2 is fixedly connected to the top of the base 1; a limiter 3 and a cutting component 4 are provided on the cutting table 2; and a linear actuator 5 is fixedly connected to the top of the base 1. Two sets of linear actuators 5 are provided, and the two sets of linear actuators 5 are respectively arranged parallel to the length direction of the cutting table 2 and the width direction of the base 1. The linear actuator 5 adopts existing technology and is a common mechanical device used to convert rotary motion into linear motion. Its key components include a motor, a lead screw, and a nut. The core working principle of the system is that the motor drives the lead screw to rotate, and the nut on the lead screw moves along the lead screw axis during the rotation, thereby converting the rotational motion into linear motion. The nut is connected to the slider, and the slider slides along the guide rail to push the load to achieve linear motion. The moving ends of the two sets of linear actuators 5 are fixedly connected to the feeding table 6. The feeding table 6 is equipped with a clamping component 7 for clamping and fixing the aluminum material, and a pushing component 8 for pushing the aluminum material clamped by the clamping component 7 to move towards the limiting component 3. The cutting table 2 is equipped with a collecting component 9 for collecting the cut aluminum material tail.

[0030] Reference Figure 2 The limiting component 3 includes a limiting plate 31 that abuts against the top of the cutting table 2. The top of the limiting plate 31 is provided with a clearance groove 32 and a locking groove 33. The locking groove 33 is provided with two sets symmetrically distributed on both sides of the clearance groove 32. A connecting plate 34 is fixedly connected to the top of the cutting table 2. The connecting plate 34 passes through the clearance groove 32. A threaded rod 35 is fixedly connected to the inner side of the limiting plate 31. One end of the threaded rod 35 passes through the connecting plate 34. A nut 36 is threadedly connected to the outer surface of the threaded rod 35. Two sets of nuts 36 are provided and symmetrically distributed on both sides of the connecting plate 34. A screw 37 is provided through the top of the locking groove 33. One end of the screw 37 passes through the locking groove 33 and is threadedly connected to a pre-set threaded hole on the cutting table 2.

[0031] The above solution is adopted: through the cooperation of the limiting plate 31, the clearance groove 32, the locking groove 33, the connecting plate 34, the threaded rod 35, the nut 36 and the screw 37 in the limiting component 3, the position of the limiting plate 31 can be flexibly adjusted and double-locked, which can be adapted to the positioning of aluminum profiles of different lengths and specifications, ensuring accurate positioning when aluminum profiles are conveyed and cut, and effectively improving the versatility and cutting positioning accuracy of the device.

[0032] Reference Figure 3 The cutting component 4 includes a motor 41 fixedly connected to the inside of the cutting table 2. A transmission wheel 42 is fixedly connected to the output end of the motor 41. A mounting platform 43 is fixedly connected to the bottom of the inside of the cutting table 2. A bearing seat 44 is fixedly connected to the bottom of the mounting platform 43. A rotating shaft 45 is provided through the inside of the bearing seat 44. A transmission wheel 46 and a saw blade 48 are fixedly connected to both ends of the rotating shaft 45, respectively. A transmission belt 47 is sleeved on the outside of the transmission wheel 46 and the transmission wheel 42, and the transmission belt 47 is engaged with the transmission wheel 46 and the transmission wheel 42, respectively. A cutting groove 49 is provided through the top of the cutting table 2. The top part of the saw blade 48 passes through the cutting groove 49 and extends to the top of the cutting table 2.

[0033] The above solution involves the motor 41, transmission wheel 42, mounting platform 43, bearing seat 44, rotating shaft 45, transmission wheel 46, transmission belt 47, saw blade 48, and cutting groove 49 in the cutting component 4 working together to transmit power through meshing transmission. The transmission process is smooth with no slippage and low power loss, ensuring that the saw blade 48 operates at high speed and stably, resulting in a smooth and flat cutting end face of the aluminum profile, which greatly improves the cutting quality and efficiency of the aluminum profile.

[0034] Reference Figures 4 to 5The clamping component 7 includes a mounting plate 71 fixedly connected to the top of the feeding table 6 and flush with one side of the feeding table 6 in the width direction. A hinged plate 72 is provided through the side end of the mounting plate 71 and is slidably inserted into the mounting plate 71. The hinged plate 72 is located on the side away from the cutting table 2 and is curved. A connecting plate 73 is fixedly connected to the end face of the hinged plate 72 away from the mounting plate 71. A clamping rod 74 is fixedly connected to the side of the connecting plate 73 facing the mounting plate 71 and passes through the mounting plate 71 and is slidably inserted into the mounting plate 71. A spring 75 is sleeved on the outside of the clamping rod 74. The two ends of the spring 75 are fixedly connected to the mounting plate 71 and the connecting plate 73, respectively. In the initial state, the spring 75 drives the connecting plate 73 towards the mounting plate 71. The clamping rod 74 moves until the spring 75 retracts to its limit position. Multiple sets of clamping rods 74 and springs 75 are provided. A screw 77 is fixedly connected to the center of the side end of the linkage plate 73. A fixing hole 76 is opened at the center of the side end of the mounting plate 71. The fixing hole 76 is an internal threaded hole. The screw 77 passes through the fixing hole 76, and the diameter of the screw 77 is smaller than that of the fixing hole 76. A fixing sleeve 78 is threadedly connected to the outside of the screw 77, and the fixing sleeve 78 is threadedly connected to the fixing hole 76. When it is necessary to fix the position of the clamping rod 74, rotate the fixing sleeve 78 to move the fixing sleeve 78 along the axis of the screw 77 towards the mounting plate 71 until the fixing sleeve 78 is inserted into the fixing hole 76 and threadedly connected to the fixing hole 76. Two sets of clamping parts 7 are provided, symmetrically distributed at the top of the feeding table 6.

[0035] The above solution is adopted: the mounting plate 71, opening and closing plate 72, connecting plate 73, clamping rod 74, spring 75, fixing hole 76, screw 77 and fixing sleeve 78 in the clamping component 7 cooperate with each other, and the aluminum profile is automatically and elastically clamped by the spring 75 without manual tightening. The arc surface design of the opening and closing plate 72 facilitates the feeding operation, the fixing sleeve 78 can lock the clamping position, and the multiple sets of clamping rods 74 clamp the force evenly, which can be adapted to aluminum profiles of different widths and prevent the aluminum material from shifting during conveying and cutting.

[0036] Reference Figures 6 to 7The propulsion component 8 includes a propulsion groove 81 extending through the top of the feeding platform 6. A bearing housing 82 is fixedly connected to the top of the feeding platform 6. A rotating shaft 83 is inserted through the bearing housing 82. Four sets of bearing housings 82 are symmetrically distributed on both sides of the propulsion groove 81. Two sets of rotating shafts 83 are provided, each set penetrating two sets of bearing housings 82. A set of sprockets 84 is fixedly connected to the outer surface of each set of bearing housings 82. The sprockets 84 are located directly below the propulsion groove 81, and the outer surfaces of the two sets of sprockets 84 are fitted with... A chain 85 is provided, and the chain 85 is meshed with two sets of sprockets 84. A second motor 86 is fixedly connected to the side end of the feeding table 6. The output end of the second motor 86 passes through the feeding table 6 and is fixedly connected to a set of rotating shafts 83. A connecting rod 87 is fixedly provided on the chain 85. The connecting rod 87 passes through the push groove 81. The part of the connecting rod 87 that passes through the push groove 81 is threadedly connected to a push plate 88. There are two sets of connecting rods 87 and push plates 88. The spacing between the two sets of connecting rods 87 and push plates 88 on the chain 85 is the same.

[0037] The above scheme is adopted: through the cooperation of the push groove 81, bearing seat 82, rotating shaft 83, sprocket 84, chain 85, motor 86, connecting rod 87 and push plate 88 in the push component 8, the sprocket 84 and chain 85 mesh to drive the transmission, the transmission is smooth and the pushing stroke is precise and controllable. The two sets of push plates 88 can realize continuous automatic feeding of aluminum materials, replace manual pushing, and improve the stability of conveying and the continuity of operation.

[0038] Reference Figures 8 to 9The collecting component 9 includes a telescopic groove 91 extending through the top of the cutting table 2. The telescopic groove 91 forms an angle with the width direction of the cutting table 2. A guide plate 92 is installed inside the cutting table 2, passing through the telescopic groove 91 and slidably inserted into it. The long side of the top of the guide plate 92 is curved on both sides. A fixing plate 93 is fixedly connected to the side of the guide plate 92. The bottom of the fixing plate 93 is flush with the bottom of the guide plate 92. Four sets of fixing plates 93 are arranged symmetrically on both sides of the guide plate 92, and each set is fixed. A set of springs 94 is fixedly connected to the top of plate 93. The top of springs 94 is fixedly connected to the bottom of the inside of the cutting table 2. In the initial state, springs 94 pull the guide plate 92 upward, so that the arc-shaped part of the top of the guide plate 92 passes through the telescopic groove 91 and extends to the top of the cutting table 2. During cutting, the linear actuator 5 drives the feeding table 6 to move towards the saw blade 48. During the movement, the aluminum material to be cut abuts against the arc-shaped part of the top of the guide plate 92, pushing the guide plate 92 downward against the elastic force of springs 94. The guide plate 92 retracts into the telescopic groove 91 at its top, allowing the aluminum material to pass through and reset smoothly. When the aluminum material is cut to a length that does not meet the requirements, a new aluminum material is inserted between the two sets of clamping members 7, and the pusher 8 pushes the new aluminum material towards the cutting table 2. The new aluminum material pushes the previous aluminum material tail onto the cutting table 2. Once the tail is completely moved onto the cutting table 2, it loses the fixation of the clamping members 7. Since the top of the base 1 is inclined, the top of the cutting table 2 is also inclined. Furthermore, due to the telescopic groove 91 and the cutting... The width of the cutting table 2 has an angle, causing the guide plate 92 to be set at an angle. This allows the tail material on the cutting table 2 to slide along the inclined surface at the top of the cutting table 2 until it comes into contact with the guide plate 92. Guided by the inclined surface of the guide plate 92, the tail material moves towards the side of the feeding table 6 and moves out of the area where the cutting table 2 is located. A collection box 95 is fixedly connected to the side end of the feeding table 6. The top of the collection box 95 is flush with the top of the feeding table 6, and the side end of the collection box 95 is in contact with the side end of the cutting table 2, so that the tail material that moves out of the cutting table 2 falls into the collection box 95.

[0039] The above solution is adopted: through the cooperation of the telescopic groove 91, guide plate 92, fixing plate 93, spring 94 and collection box 95 in the collection component 9, the guide plate 92 is automatically extended and retracted by the spring 94, without interfering with the normal conveying and cutting of aluminum materials. With the inclined structure, the tail material is automatically slid down and guided for collection, without the need for manual shutdown for cleaning, avoiding the accumulation of tail material that affects the operation, and improving the automation level of the device and the cleanliness of the operation.

[0040] The working principle of this invention is as follows: Before using the device, the operator adjusts the limiting component 3 according to the specifications and dimensions of the aluminum profile to be cut. The operator loosens the screw 37 and the nuts 36 on both sides of the threaded rod 35, adjusts the position of the limiting plate 31 along the clearance groove 32, and determines the cutting length of the aluminum profile. After adjustment, the operator tightens the nuts 36 to fix the threaded rod 35 and the connecting plate 34, and then tightens the screw 37 to lock the limiting plate 31 onto the cutting table 2, completing the cutting positioning setting. When loading, the operator pushes the opening and closing plate 72, overcoming the elastic force of the spring 75 to drive the connecting plate 73. As the clamping rod 74 moves outward, the distance between the two sets of clamping parts 7 is increased, and the aluminum profile is placed on the feeding table 6. The opening and closing plate 72 is released, and the spring 75 rebounds, causing the clamping rod 74 to automatically clamp the aluminum profile on both sides. Then, the fixing sleeve 78 is rotated to screw it into the fixing hole 76, locking the clamping position and preventing the aluminum material from moving or shifting. After the device is started, the motor 86 of the pusher 8 operates, driving the rotating shaft 83 and the sprocket 84 to rotate. The sprocket 84 drives the chain 85, connecting rod 87 and push plate 88 to move along the push groove 81. The push plate 88 pushes the aluminum material continuously towards the limit. The positioning plate 31 moves until the end of the aluminum material is in contact with the limiting plate 31, completing the automatic feeding and positioning. Then, the two sets of linear actuators 5 work together to drive the feeding table 6 to move along the set direction, conveying the aluminum material to the cutting position. The motor 41 of the cutting part 4 runs, driving the transmission wheel 42, transmission belt 47, transmission wheel 46, rotating shaft 45 and saw blade 48 to rotate at high speed. The saw blade 48 continuously cuts the aluminum material through the cutting groove 49. When the feeding table 6 moves, the aluminum material presses against the guide plate 92, causing it to overcome the elastic force of the spring 94 and retract into the telescopic groove 91, without affecting the cutting position. The aluminum material moves normally. When the aluminum material is cut to the tail material, a new aluminum material is placed between the two sets of clamping parts 7. The pusher 8 pushes the new aluminum material to push the tail material to the cutting table 2. Under the guidance of the inclined surface and the guide plate 92, the tail material automatically slides into the collection box 95. After the single-segment cutting is completed, the linear driver 5 drives the feeding table 6 to reset. The pusher 8 continues to push the aluminum material, repeating the feeding, positioning, cutting, and tail material collection process to realize continuous automated conveying and cutting of aluminum profiles. There is no need for frequent manual feeding, positioning, and tail material cleaning throughout the process, ensuring continuous, stable, and efficient operation of the cutting operation.The aluminum profile is automatically and elastically clamped by the clamping component 7 and spring 75, eliminating the need for manual tightening and greatly simplifying the feeding process. The curved structure of the opening and closing plate 72 makes it easier for operators to operate. Multiple clamping rods 74 ensure even force distribution on the aluminum profile, effectively preventing shaking or displacement during conveying and cutting. The fixing sleeve 78 can lock the clamping position, adapting to aluminum profiles of different widths and specifications, improving the device's adaptability and feeding stability, and reducing the intensity of manual operation. Through the pushing component 8, the sprocket 84 and chain 85 mesh to drive the aluminum profile, ensuring smooth and slip-free power transmission and precise control of the pushing stroke. This allows for stable directional movement of the aluminum profile, eliminating the problems of jamming or displacement during pushing. The pusher plate 88 allows one set of aluminum profiles to be pushed into the clamping member 7 while another set pushes the tail material, enabling uninterrupted continuous feeding of aluminum profiles. This improves the efficiency of aluminum profile conveying and the continuity of cutting operations, ensuring stable operation of the device over a long period. The collecting member 9, using spring 2 94, allows the guide plate 92 to automatically extend and retract, automatically avoiding interference during aluminum profile conveying and automatically resetting after cutting, without disrupting normal cutting processes. Combined with the guiding action of the inclined surface of the cutting table 2 and the guide plate 92, the tail material of the aluminum profile can automatically slide down and be collected in a directional manner, eliminating the need for manual shutdown for cleaning. This prevents tail material from accumulating on the cutting table 2 and interfering with cutting operations, keeping the worktable clean, significantly improving the automation level of the device, and ensuring efficient and orderly continuous cutting operations.

[0041] The above description is merely a preferred embodiment of the present invention, but the scope of protection of the present invention is not limited thereto. Any equivalent substitutions or modifications made by those skilled in the art within the scope of the technology disclosed in the present invention, based on the technical solution and inventive concept of the present invention, should be covered within the scope of protection of the present invention.

Claims

1. A continuous conveying and cutting device for aluminum profiles, comprising: The base (1) is characterized in that a cutting table (2) is fixedly connected to the top of the base (1), a limiting component (3) and a cutting component (4) are provided on the cutting table (2), a linear driver (5) is fixedly connected to the top of the base (1), a feeding table (6) is fixedly connected to the movable end of the linear driver (5), a clamping component (7) for clamping and fixing aluminum material is provided on the feeding table (6), a pushing component (8) for pushing aluminum material to move is provided on the feeding table (6), and a collecting component (9) for collecting the cut aluminum material tail material is provided on the cutting table (2). The propulsion component (8) includes a propulsion groove (81) extending through the top of the feeding platform (6). A bearing seat (82) is fixedly connected to the top of the feeding platform (6). A rotating shaft (83) is installed through the bearing seat (82). There are four sets of bearing seats (82) symmetrically distributed on both sides of the propulsion groove (81). There are two sets of rotating shafts (83). Each set of rotating shafts (83) passes through two sets of bearing seats (82). A set of sprockets (84) is fixedly connected to the outer surface of each set of bearing seats (82). Two sets of sprockets (84) are fitted with chains (85) on their outer sides, and the chains (85) are meshed with the two sets of sprockets (84). A second motor (86) is fixedly connected to the side end of the feeding table (6). The output end of the second motor (86) passes through the feeding table (6) and is fixedly connected to a set of rotating shafts (83). A connecting rod (87) is fixedly installed on the chain (85). The connecting rod (87) passes through the push groove (81). The part of the connecting rod (87) that passes through the push groove (81) is threadedly connected to a push plate (88).

2. The continuous conveying and cutting device for aluminum profiles according to claim 1, characterized in that, The base (1) has a right trapezoidal cross section with the inclined surface facing upward. The linear actuator (5) is provided in two sets. The two sets of linear actuators (5) are respectively arranged parallel to the length direction of the cutting table (2) and the width direction of the base (1). The linear actuator (5) adopts existing technology and is a common mechanical device used to convert rotary motion into linear motion. Its key components include motor, lead screw, nut, guide rail, slider, etc. Its core working principle is to drive the lead screw to rotate through the motor. The nut on the lead screw moves along the axis of the lead screw during the rotation, thereby converting the rotary motion into linear motion. The nut is connected to the slider, and the slider slides along the guide rail to push the load to achieve linear motion. The moving ends of the two sets of linear actuators (5) are fixedly connected to the feeding table (6).

3. The continuous conveying and cutting device for aluminum profiles according to claim 2, characterized in that, The limiting component (3) includes a limiting plate (31) that abuts against the top of the cutting table (2). The top of the limiting plate (31) is provided with a clearance groove (32) and a locking groove (33). The locking groove (33) is provided with two sets symmetrically distributed on both sides of the clearance groove (32). The top of the cutting table (2) is fixedly connected to a connecting plate (34). The connecting plate (34) passes through the clearance groove (32). The inner side of the limiting plate (31) is fixedly connected to a threaded rod (35). One end of the threaded rod (35) passes through the connecting plate (34). The outer surface of the threaded rod (35) is threadedly connected to a nut (36). The nut (36) is provided with two sets symmetrically distributed on both sides of the connecting plate (34). The top of the locking groove (33) is provided with a screw (37). One end of the screw (37) passes through the locking groove (33) and is threadedly connected to a pre-set threaded hole on the cutting table (2).

4. The continuous conveying and cutting device for aluminum profiles according to claim 3, characterized in that, The cutting component (4) includes a motor (41) fixedly connected to the inside of the cutting table (2). The output end of the motor (41) is fixedly connected to a transmission wheel (42). The bottom of the inside of the cutting table (2) is fixedly connected to a mounting platform (43). The bottom of the mounting platform (43) is fixedly connected to a bearing seat (44). A rotating shaft (45) is provided through the inside of the bearing seat (44). The two ends of the rotating shaft (45) are fixedly connected to a transmission wheel (46) and a saw blade (48). A transmission belt (47) is sleeved on the outside of the transmission wheel (46) and the transmission wheel (42). The transmission belt (47) is meshed with the transmission wheel (46) and the transmission wheel (42) respectively. A cutting groove (49) is provided through the top of the cutting table (2). The top part of the saw blade (48) passes through the cutting groove (49) and extends to the top of the cutting table (2).

5. The continuous conveying and cutting device for aluminum profiles according to claim 4, characterized in that, The clamping member (7) includes a mounting plate (71) fixedly connected to the top of the feeding table (6) and flush with one side of the feeding table (6) in the width direction. A hinged plate (72) is provided through the side end of the mounting plate (71), and the hinged plate (72) is slidably inserted into the mounting plate (71). The hinged plate (72) is located on the side away from the cutting table (2), and the side away from the cutting table (2) is an arc surface. A connecting plate (73) is fixedly connected to the end face of the hinged plate (72) away from the mounting plate (71). The connecting plate (73) faces the mounting plate. (71) A clamping rod (74) is fixedly connected to one side, and the clamping rod (74) passes through the mounting plate (71) and is slidably inserted into the mounting plate (71). A spring (75) is sleeved on the outside of the clamping rod (74). The two ends of the spring (75) are fixedly connected to the mounting plate (71) and the connecting plate (73) respectively. In the initial state, the spring (75) drives the connecting plate (73) to move towards the mounting plate (71) until the spring (75) retracts to the limit position. There are multiple sets of clamping rods (74) and springs (75).

6. The continuous conveying and cutting device for aluminum profiles according to claim 5, characterized in that, A screw (77) is fixedly connected to the center of the side end of the connecting plate (73). A fixing hole (76) is opened at the center of the side end of the mounting plate (71). The fixing hole (76) is an internal threaded hole. The screw (77) passes through the fixing hole (76), and the diameter of the screw (77) is smaller than that of the fixing hole (76). A fixing sleeve (78) is threadedly connected to the outside of the screw (77), and the fixing sleeve (78) is threadedly connected to the fixing hole (76). When it is necessary to fix the position of the clamping rod (74), the fixing sleeve (78) is rotated, so that the fixing sleeve (78) moves along the axis of the screw (77) toward the mounting plate (71) until the fixing sleeve (78) is inserted into the fixing hole (76) and threadedly connected to the fixing hole (76). Two sets of clamping parts (7) are provided, symmetrically distributed at the top of the feeding table (6).

7. The continuous conveying and cutting device for aluminum profiles according to claim 6, characterized in that, The collecting component (9) includes a telescopic groove (91) that runs through the top of the cutting table (2). The telescopic groove (91) has an angle with the width direction of the cutting table (2). A guide plate (92) is provided inside the cutting table (2). The guide plate (92) runs through the telescopic groove (91) and is slidably inserted into the telescopic groove (91). The long side of the top of the guide plate (92) is curved on both sides. A fixing plate (93) is fixedly connected to the side of the guide plate (92). The bottom end of the fixing plate (93) is flush with the bottom end of the guide plate (92).

8. The continuous conveying and cutting device for aluminum profiles according to claim 7, characterized in that, The fixed plate (93) is provided in four sets, symmetrically distributed on both sides of the guide plate (92). Each set of fixed plates (93) is fixedly connected to a set of springs (94) at the top. The top of the springs (94) is fixedly connected to the bottom of the inside of the cutting table (2). In the initial state, the springs (94) pull the guide plate (92) upward, so that the arc part of the top of the guide plate (92) passes through the telescopic groove (91) and extends to the top of the cutting table (2). The side of the feeding table (6) is fixedly connected to a collection box (95). The top of the collection box (95) is flush with the top of the feeding table (6), and the side of the collection box (95) is in contact with the side of the cutting table (2).