A continuous cutting apparatus for steel structural member machining

By combining the clamping round block with the auxiliary clamping top block, the problem of existing cutting equipment being unable to continuously cut square steel pipes is solved, achieving an efficient and safe cutting process and improving cutting accuracy and stability.

CN122142791APending Publication Date: 2026-06-05QINGDAO TANGEN METAL CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Applications(China)
Current Assignee / Owner
QINGDAO TANGEN METAL CO LTD
Filing Date
2026-05-06
Publication Date
2026-06-05

AI Technical Summary

Technical Problem

Existing cutting equipment cannot achieve continuous cutting of square steel pipes, requiring frequent manual adjustments to the clamps and positions, resulting in low cutting efficiency and safety issues.

Method used

The design employs a combination of a clamping circular block and an auxiliary clamping top block. By having the clamping circular block closely adhere to the side wall of the square steel pipe and the auxiliary clamping top block extend and retract, continuous cutting is achieved. The rotation of the clamping circular block drives the steel pipe to move, enabling position adjustment. The meshing of the toothed plate and gears drives the clamping circular block to rotate in the same or opposite directions, ensuring cutting stability and positional accuracy.

Benefits of technology

It enables continuous cutting of square steel pipes, improving cutting efficiency and safety, reducing manual intervention, and ensuring cutting accuracy and stability.

✦ Generated by Eureka AI based on patent content.

Smart Images

  • Figure CN122142791A_ABST
    Figure CN122142791A_ABST
Patent Text Reader

Abstract

The application relates to the field of cutting equipment, and discloses a continuous cutting equipment for machining steel structure parts, which comprises a workbench, a cutting groove is formed in the middle of the workbench, a cutting mechanism is installed at the top end of the workbench, symmetrical side clamping assemblies are installed at the top end of the workbench, the cutting mechanism comprises a portal frame fixedly installed at the top end of the workbench, a linear movement module is installed on the portal frame, a cutting machine is installed on the linear movement module, the linear movement module can drive the cutting machine to move along the cutting groove, the side clamping assemblies comprise two sliding tables, the two sliding tables are symmetrically arranged on the two sides of the cutting groove, and a side groove is formed on the side where the two sliding tables are close to each other, the application can tightly clamp a square steel pipe through a clamping round block and the side wall of the square steel pipe, and after an auxiliary clamping top block is extended outward, the auxiliary clamping top block is tightly clamped with the side wall of the square steel pipe through the rotation of the clamping round block, and auxiliary clamping is realized.
Need to check novelty before this filing date? Find Prior Art

Description

Technical Field

[0001] This invention belongs to the field of cutting equipment, specifically a continuous cutting device for processing steel structure components. Background Technology

[0002] In the field of steel structure processing, square steel pipes, due to their excellent mechanical properties, stable structural strength, and convenient splicing characteristics, are widely used in various industries such as building curtain walls, bridge engineering, machinery manufacturing, rail transit, and heavy equipment. They are one of the core basic components constituting steel structure frames and supporting members. In the processing of square steel pipes, the cutting process is an indispensable key step. According to actual construction and assembly requirements, long strips of square steel pipes need to be cut into sections of different lengths and specifications, laying the foundation for subsequent bending, welding, drilling, and other processes. Currently, there are many types of equipment on the market for cutting square steel pipes, mainly including flame cutting machines, plasma cutting machines, laser cutting machines, and sawing equipment. Their core working principle is to cut the square steel pipe through the high temperature or mechanical force generated by the cutting mechanism. However, in practical applications, especially when facing the need for multiple continuous cuts of square steel pipes, existing cutting equipment still has the following shortcomings: To ensure cutting accuracy and prevent the square steel pipe from shifting or shaking during the cutting process, which could lead to quality problems such as tilted cuts and dimensional deviations, a special clamp is usually used to clamp and fix the square steel pipe to ensure that it maintains a stable posture during the cutting process. However, when the square steel pipe needs to be cut multiple times, the existing equipment cannot adjust the position in the fixed state. After each cut, the clamp must be released from the square steel pipe first, and then the position of the square steel pipe to be cut must be adjusted manually or by a simple feeding mechanism. After the adjustment is in place, the clamp is restarted to clamp and fix it before the next cutting operation can be carried out. This makes continuous cutting impossible and results in low cutting efficiency. Summary of the Invention

[0003] In view of the above situation and to overcome the defects of the prior art, the present invention provides a continuous cutting device for processing steel structure components, which effectively solves the problems existing in the background art.

[0004] To achieve the above objectives, the present invention provides the following technical solution: a continuous cutting device for processing steel structure components, including a worktable, a cutting groove in the middle of the worktable, a cutting mechanism installed at the top of the worktable, and side clamping components symmetrically installed at the top of the worktable; The cutting mechanism includes a gantry frame fixedly installed on the top of the worktable, a linear motion module installed on the gantry frame, a cutting machine installed on the linear motion module, and the linear motion module can drive the cutting machine to move along the cutting groove. The side clamping assembly includes two sliding tables, which are symmetrically arranged on both sides of the cutting groove. Each sliding table has a side groove on the side that is close to the other, and a clamping moving part is provided inside the sliding table. The clamping moving part includes a sliding block that is slidably installed inside the sliding table. A clamping round block is fixedly installed on the top of the sliding block. One side of the sliding block is fixedly connected to the output end of the clamping cylinder. The clamping cylinder is installed on the sliding table. The clamping round blocks on the two side clamping components move closer to each other to clamp the steel structure. An eccentric clamping component is provided on the clamping round block. A rotation drive component is provided between the two sliding blocks. When the eccentric clamping component unfolds, it provides auxiliary clamping for the steel structure component. When the eccentric clamping component retracts, the clamping block rotates, which can drive the steel structure component to move and adjust its position after cutting, making it convenient to cut again and achieving continuous cutting effect.

[0005] Preferably, a rotating shaft is coaxially mounted on the bottom end of the clamping block, the rotating shaft is rotatably mounted inside the rotating groove, the rotating groove is opened inside the sliding block, a gear is coaxially mounted on the rotating shaft, and a plate groove is opened on one side of the rotating groove.

[0006] Preferably, the eccentric clamping member includes a storage groove formed inside the clamping block, an auxiliary clamping top block is slidably installed inside the storage groove, and a top groove is formed at the top of the storage groove.

[0007] Preferably, a longitudinal sliding frame is fixedly installed at the top of the clamping block, a slider is slidably installed inside the longitudinal sliding frame, a first connecting rod is hinged to one side of the slider, one end of the first connecting rod is hinged to the auxiliary clamping top block, a longitudinal screw is rotatably installed inside the longitudinal sliding frame, the longitudinal screw is threadedly connected to the slider, the top of the longitudinal screw is fixedly connected to the output shaft of the first motor, and the first motor is fixedly installed at the top of the longitudinal sliding frame.

[0008] Preferably, the ends of the storage grooves on the two clamping blocks extend to the side of the two clamping blocks that are close to each other, and the longitudinal sliding frame is arranged on the center line of the storage groove, and the center line of the storage groove passes through the center of the clamping block.

[0009] Preferably, the rotation drive includes a connecting plate fixedly installed between two sliding blocks, a toothed plate is provided above the connecting plate, and a transverse sliding frame is fixedly installed on the side of the two connecting plates on the two side clamping assemblies that are far apart from each other. A support slide is slidably installed on the transverse sliding frame, wherein a moving drive is provided between the transverse sliding frame and the support slide, and a relative moving component is provided between the support slide and the toothed plate.

[0010] Preferably, the toothed plate component includes two toothed plate bodies, which are slidably installed inside two plate grooves and are meshed with two gears respectively. Two guide rods are symmetrically installed at one end of one toothed plate body, and guide grooves are symmetrically opened inside the other end of the toothed plate body. The guide rods are slidably installed inside the guide grooves.

[0011] Preferably, the moving drive component includes a transverse screw rotatably mounted inside the transverse sliding frame, the transverse screw being threadedly connected to the support slide, one end of the transverse screw being fixedly connected to the output shaft of the second motor, and the second motor being mounted at one end of the transverse sliding frame.

[0012] Preferably, the relative moving component includes a push cylinder mounted on the support slide, the output end of the push cylinder pointing towards the gap between the two toothed plate bodies, a push plate fixedly mounted on the output end of the push cylinder, and two second connecting rods symmetrically hinged on the push plate, the ends of the two second connecting rods being respectively hinged to the two toothed plate bodies.

[0013] Compared with the prior art, the beneficial effects of the present invention are: This invention clamps a square steel pipe by tightly pressing a clamping round block against the side wall of the square steel pipe. After the auxiliary clamping top block extends outward, the clamping round block rotates so that the end of the auxiliary clamping top block is tightly pressed against the side wall of the square steel pipe, thereby achieving auxiliary clamping. The invention also limits the position of the clamping round block, reducing its rotation during clamping and improving the cutting stability of the square steel pipe. This invention, by removing the auxiliary clamping top block and rotating the clamping round block, can drive the end of the auxiliary clamping top block to fit tightly against the side wall of the square steel pipe, thereby improving clamping stability. After the auxiliary clamping top block is retracted, the clamping round block rotates, which can drive the square steel pipe to move under the action of friction, thereby realizing the adjustment of the cutting position. Fang Baini can achieve continuous cutting without the need for manual adjustment, thus improving processing safety. In this invention, when the auxiliary clamping top block is moved out, the two clamping round blocks rotate in opposite directions, so that when auxiliary clamping is needed, the two clamping round blocks generate opposite frictional forces on the steel pipe, ensuring that the position of the square steel pipe is stable during auxiliary clamping. When the auxiliary clamping top block is retracted, the two clamping round blocks rotate in the same direction, generating frictional forces in the same direction, which facilitates the movement of the square steel pipe. In this invention, two toothed plates are respectively connected to two gears. When the two toothed plates move relative to each other, they can easily drive two clamping blocks to rotate in opposite directions, thereby achieving auxiliary clamping. When the two toothed plates move in the same direction, they can easily drive the two clamping blocks to rotate synchronously in the same direction, thereby achieving workpiece movement and adjustment. Attached Figure Description

[0014] The accompanying drawings are provided to further illustrate the invention and form part of the specification. They are used together with the embodiments of the invention to explain the invention and do not constitute a limitation thereof.

[0015] In the attached diagram: Figure 1 This is a schematic diagram of the continuous cutting equipment for processing steel structure components according to the present invention; Figure 2 This is a schematic diagram of the side clamping assembly structure of the present invention; Figure 3 This is a schematic diagram of the clamping and moving part structure of the present invention; Figure 4 This is a schematic diagram of the connection structure between the clamping circular block and the sliding block of the present invention; Figure 5 This is a schematic diagram of the internal structure of the clamping circular block of the present invention; Figure 6 This is a schematic diagram of the rotating drive component structure of the present invention; Figure 7 This is a schematic diagram of the toothed plate structure of the present invention; In the diagram: 1. Workbench; 2. Cutting groove; 3. Gantry frame; 4. Cutting machine; 5. Side clamping assembly; 501. Sliding table; 502. Side groove; 503. Clamping moving part; 5031. Sliding block; 5032. Clamping round block; 5033. Clamping cylinder; 5034. Rotary groove; 5035. Rotating shaft; 5036. Gear; 5037. Plate groove; 5038. Storage groove; 5039. Auxiliary clamping top block; 50310. Top groove; 50311. Longitudinal sliding frame; 503 12. Slider; 50313. First connecting rod; 50314. Longitudinal screw; 50315. First motor; 504. Rotation drive component; 5041. Connecting plate; 5042. Toothed plate component; 50421. Toothed plate body; 50422. Guide groove; 50423. Guide rod; 5043. Push plate; 5044. Second connecting rod; 5045. Push cylinder; 5046. Support slide; 5047. Transverse sliding frame; 5048. Transverse screw; 5049. Second motor. Detailed Implementation

[0016] The technical solutions of the present invention will be clearly and completely described below with reference to the accompanying drawings of the embodiments of the present invention. Obviously, the described embodiments are only some embodiments of the present invention, and not all embodiments. All other embodiments obtained by those skilled in the art based on the embodiments of the present invention without creative effort are within the scope of protection of the present invention.

[0017] Example 1, by Figure 1The present invention relates to a continuous cutting device for processing steel structure components, comprising a worktable 1, a cutting groove 2 formed in the middle of the worktable 1, a cutting mechanism mounted on the top of the worktable 1, and side clamping components 5 symmetrically mounted on the top of the worktable 1. The cutting mechanism includes a gantry frame 3 fixedly mounted on the top of the worktable 1, a linear motion module mounted on the gantry frame 3, and a cutting machine 4 mounted on the linear motion module. The linear motion module can drive the cutting machine 4 to move along the cutting groove 2.

[0018] Depend on Figure 2 As shown, the side clamping assembly 5 includes two sliding tables 501, which are symmetrically arranged on both sides of the cutting groove 2. The two sliding tables 501 are provided with side grooves 502 on the side that is close to each other. A clamping moving part 503 is provided inside the sliding table 501. Depend on Figure 3 The clamping moving component 503 includes a sliding block 5031 slidably installed inside the sliding table 501. A clamping round block 5032 is fixedly installed on the top of the sliding block 5031. One side of the sliding block 5031 is fixedly connected to the output end of the clamping cylinder 5033. The clamping cylinder 5033 is installed on the sliding table 501. The clamping round blocks 5032 on the two side clamping components 5 approach each other to clamp the steel structure. An eccentric clamping component is provided on the clamping round block 5032. A rotation driving component 504 is provided between the two sliding blocks 5031. When the eccentric clamping component is unfolded, it provides auxiliary clamping for the steel structure. When the eccentric clamping component is retracted, the clamping round block 5032 rotates, which can drive the steel structure to move and adjust its position after cutting, so as to facilitate recutting and achieve continuous cutting effect.

[0019] Depend on Figure 4 As shown, a rotating shaft 5035 is coaxially mounted on the bottom end of the clamping block 5032. The rotating shaft 5035 is rotatably mounted inside the rotating groove 5034. The rotating groove 5034 is opened inside the sliding block 5031. A gear 5036 is coaxially mounted on the rotating shaft 5035. A plate groove 5037 is opened on one side of the rotating groove 5034.

[0020] Depend on Figure 5The eccentric clamping component includes a receiving groove 5038 formed inside the clamping block 5032. An auxiliary clamping top block 5039 is slidably installed inside the receiving groove 5038. The clamping block 5032 is in close contact with the side wall of the square steel tube to clamp the square steel tube. After the auxiliary clamping top block 5039 extends outward, the clamping block 5032 rotates so that the end of the auxiliary clamping top block 5039 is in close contact with the side wall of the square steel tube, thus achieving auxiliary clamping and limiting the clamping block 5032 to reduce rotation of the clamping block 5032 during clamping, thereby improving the cutting stability of the square steel tube. The top of the receiving groove 5038... A top groove 50310 is provided. A longitudinal sliding frame 50311 is fixedly installed on the top of the clamping block 5032. A slider 50312 is slidably installed inside the longitudinal sliding frame 50311. A first connecting rod 50313 is hinged to one side of the slider 50312. One end of the first connecting rod 50313 is hinged to the auxiliary clamping top block 5039. A longitudinal screw 50314 is rotatably installed inside the longitudinal sliding frame 50311. The longitudinal screw 50314 is threadedly connected to the slider 50312. The top of the longitudinal screw 50314 is fixedly connected to the output shaft of the first motor 50315. Motor 50315 is fixedly mounted on the top of longitudinal sliding frame 50311. The ends of the receiving grooves 5038 on the two clamping blocks 5032 respectively extend to the side of the two clamping blocks 5032 that are close to each other. The longitudinal sliding frame 50311 is set on the center line of the receiving grooves 5038, and the center line of the receiving grooves 5038 passes through the center of the clamping blocks 5032. After the auxiliary clamping top block 5039 is moved out, the clamping blocks 5032 rotate, which can drive the end of the auxiliary clamping top block 5039 to be tightly pressed against the side wall of the square steel pipe, improving the clamping stability. After the auxiliary clamping top block 5039 is retracted, the clamping blocks 50311... The 32-rotation mechanism drives the square steel tube to move under friction, enabling adjustment of the cutting position. This allows for continuous cutting without manual adjustment, improving processing safety. Simultaneously, when the auxiliary clamping top block 5039 moves out, the two clamping round blocks 5032 rotate in opposite directions. This generates opposite frictional forces on the steel tube when auxiliary clamping is needed, ensuring the square steel tube remains stable during auxiliary clamping. Conversely, when the auxiliary clamping top block 5039 retracts, the two clamping round blocks 5032 rotate in the same direction, generating frictional forces in the same direction, facilitating the movement of the square steel tube.

[0021] Depend on Figure 6As shown, the rotation drive component 504 includes a connecting plate 5041 fixedly installed between two sliding blocks 5031. A toothed plate component 5042 is provided above the connecting plate 5041. A transverse sliding frame 5047 is fixedly installed on the side of the two connecting plates 5041 on the two side clamping assemblies 5 that are far apart from each other. A support slide 5046 is slidably installed on the transverse sliding frame 5047. A moving drive component is provided between the transverse sliding frame 5047 and the support slide 5046. A relative moving component is provided between the support slide 5046 and the toothed plate component 5042.

[0022] Depend on Figure 7 The toothed plate component 5042 includes two toothed plate bodies 50421, which are slidably installed inside two plate grooves 5037. The two toothed plate bodies 50421 are respectively meshed with two gears 5036. Two guide rods 50423 are symmetrically installed at one end of one toothed plate body 50421, and guide grooves 50422 are symmetrically opened inside the other end of the toothed plate body 50421. The guide rods 50423 are slidably installed inside the guide grooves 50422. The two toothed plate bodies 50421 are respectively meshed with two gears 5036. When the two toothed plate bodies 50421 move relative to each other, it is convenient to drive the two clamping blocks 5032 to rotate in opposite directions, thereby achieving auxiliary clamping. When the two toothed plate bodies 50421 move in the same direction, it is convenient to drive the two clamping blocks 5032 to rotate synchronously in the same direction, thereby achieving workpiece movement adjustment.

[0023] Depend on Figure 6 The moving drive component includes a transverse screw 5048 rotatably mounted inside the transverse sliding frame 5047. The transverse screw 5048 is threadedly connected to the support slide 5046. One end of the transverse screw 5048 is fixedly connected to the output shaft of the second motor 5049, which is mounted on one end of the transverse sliding frame 5047.

[0024] Depend on Figure 6 The relative moving component includes a push cylinder 5045 mounted on a support slide 5046. The output end of the push cylinder 5045 points to the gap between the two toothed plate bodies 50421. A push plate 5043 is fixedly mounted on the output end of the push cylinder 5045. Two second connecting rods 5044 are symmetrically hinged on the push plate 5043. The ends of the two second connecting rods 5044 are respectively hinged to the two toothed plate bodies 50421.

[0025] Working principle: When in use, place the square steel pipe to be cut between the two side clamping components 5, and then open the clamping cylinder 5033, so that the clamping round blocks 5032 on both sides of the square steel pipe move towards one side of the square steel pipe to clamp the square steel pipe. Then, the second motor 5049 is turned on, driving the transverse screw 5048 to rotate, which in turn drives the support slide 5046 to move along the transverse sliding frame 5047, which in turn drives the two toothed plate bodies 50421 to move along the plate groove 5037. The two toothed plate bodies 50421 are respectively meshed with the two gears 5036, so that the two clamping round blocks 5032 on the same side clamping assembly 5 rotate in the same direction, while the two clamping round blocks 5032 on the two sides of the side clamping assembly 5 rotate in opposite directions. Thus, under the action of friction, the square steel pipe is driven to move along its length direction, and the position of the square steel pipe to be cut is moved to the position corresponding to the cutting groove 2. After moving to the cutting position, the first motor 50315 is activated, driving the longitudinal screw 50314 to rotate. The longitudinal screw 50314 is threadedly connected to the slider 50312, thereby driving the slider 50312 to move downward along the longitudinal sliding frame 50311. This, in turn, pushes the auxiliary clamping top block 5039 outward through the first connecting rod 50313. At this time, the two auxiliary clamping top blocks 5039 on the two clamping round blocks 5032 on the same side clamping assembly 5 move closer to each other. Then, the push cylinder 5045 is activated. The push plate 5043 is pushed to move towards the toothed plate body 50421. The two toothed plate bodies 50421 are pushed away from each other by the two second connecting rods 5044, which in turn pushes the two clamping blocks 5032 to rotate in opposite directions until the end of the auxiliary clamping top block 5039 clamps the square steel pipe, and prevents the clamping blocks 5032 from rotating arbitrarily, thus ensuring cutting stability. Since the two clamping blocks 5032 rotate in opposite directions, they generate opposite frictional forces on the square steel pipe, thereby ensuring the positioning effect of the square steel pipe. Then the cutting machine 4 is turned on, and then the cutting machine 4 is driven to move along the length of the cutting groove 2 through the linear motion module to cut the square steel pipe. After the cutting is completed, repeat the above steps. After the auxiliary clamping top block 5039 is retracted, the two toothed plate bodies 50421 rotate synchronously in the same direction, driving the square steel pipe to move along the length direction, and moving the next cutting position to the position corresponding to the cutting groove 2, so as to realize continuous cutting, improve cutting and blanking, and eliminate the need for manual adjustment of position during two consecutive cuts, thereby improving work safety.

[0026] It should be noted that, in this document, relational terms such as "first" and "second" are used only to distinguish one entity or operation from another, and do not necessarily require or imply any such actual relationship or order between these entities or operations. Furthermore, the terms "comprising," "including," or any other variations thereof are intended to cover non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements includes not only those elements but also other elements not expressly listed, or elements inherent to such process, method, article, or apparatus.

[0027] Although embodiments of the invention have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made to these embodiments without departing from the principles and spirit of the invention, the scope of which is defined by the appended claims and their equivalents.

Claims

1. A continuous cutting device for processing steel structure components, comprising a worktable (1), characterized in that: The workbench (1) has a cutting groove (2) in the middle, a cutting mechanism is installed at the top of the workbench (1), and side clamping components (5) are symmetrically installed at the top of the workbench (1). The cutting mechanism includes a gantry (3) fixedly installed on the top of the workbench (1), a linear motion module is installed on the gantry (3), a cutting machine (4) is installed on the linear motion module, and the linear motion module can drive the cutting machine (4) to move along the cutting groove (2); The side clamping assembly (5) includes two sliding tables (501), which are symmetrically arranged on both sides of the cutting groove (2). The two sliding tables (501) are provided with side grooves (502) on the side that is close to each other. The sliding table (501) is provided with a clamping moving part (503). The clamping moving part (503) includes a sliding block (5031) slidably installed inside the sliding table (501). A clamping round block (5032) is fixedly installed on the top of the sliding block (5031). One side of the sliding block (5031) is fixedly connected to the output end of the clamping cylinder (5033). The clamping cylinder (5033) is installed on the sliding table (501). The clamping round blocks (5032) on the two side clamping assemblies (5) approach each other to clamp the steel structure. An eccentric clamping part is provided on the clamping round block (5032). A rotation driving part (504) is provided between the two sliding blocks (5031). When the eccentric clamping component unfolds, it provides auxiliary clamping for the steel structure component. When the eccentric clamping component retracts, the clamping block (5032) rotates, which can drive the steel structure component to move and adjust its position after cutting, making it convenient to cut again and achieve continuous cutting effect.

2. The continuous cutting equipment for processing steel structure components according to claim 1, characterized in that: The bottom end of the clamping block (5032) is coaxially mounted with a rotating shaft (5035), which is rotatably mounted inside a rotating groove (5034). The rotating groove (5034) is opened inside a sliding block (5031). A gear (5036) is coaxially mounted on the rotating shaft (5035), and a plate groove (5037) is opened on one side of the rotating groove (5034).

3. The continuous cutting equipment for processing steel structure components according to claim 1, characterized in that: The eccentric clamping member includes a storage groove (5038) opened inside the clamping block (5032), an auxiliary clamping top block (5039) is slidably installed inside the storage groove (5038), and a top groove (50310) is opened at the top of the storage groove (5038).

4. The continuous cutting equipment for processing steel structure components according to claim 3, characterized in that: A longitudinal sliding frame (50311) is fixedly installed at the top of the clamping block (5032). A slider (50312) is slidably installed inside the longitudinal sliding frame (50311). A first connecting rod (50313) is hinged to one side of the slider (50312). One end of the first connecting rod (50313) is hinged to the auxiliary clamping top block (5039). A longitudinal screw (50314) is rotatably installed inside the longitudinal sliding frame (50311). The longitudinal screw (50314) is threadedly connected to the slider (50312). The top of the longitudinal screw (50314) is fixedly connected to the output shaft of the first motor (50315). The first motor (50315) is fixedly installed at the top of the longitudinal sliding frame (50311).

5. The continuous cutting equipment for processing steel structure components according to claim 4, characterized in that: The ends of the storage grooves (5038) on the two clamping blocks (5032) respectively extend to the side of the two clamping blocks (5032) that are close to each other. The longitudinal sliding frame (50311) is set on the center line of the storage groove (5038), and the center line of the storage groove (5038) passes through the center of the clamping block (5032).

6. The continuous cutting equipment for processing steel structure components according to claim 1, characterized in that: The rotation drive (504) includes a connecting plate (5041) fixedly installed between two sliding blocks (5031). A toothed plate (5042) is provided above the connecting plate (5041). A transverse sliding frame (5047) is fixedly installed on the side of the two connecting plates (5041) on the two side clamping assemblies (5) that are far apart from each other. A support slide (5046) is slidably installed on the transverse sliding frame (5047). A moving drive is provided between the transverse sliding frame (5047) and the support slide (5046), and a relative moving member is provided between the support slide (5046) and the toothed plate (5042).

7. The continuous cutting equipment for processing steel structure components according to claim 6, characterized in that: The toothed plate component (5042) includes two toothed plate bodies (50421), which are slidably installed inside two plate grooves (5037) respectively, and the two toothed plate bodies (50421) are meshed with two gears (5036) respectively. Two guide rods (50423) are symmetrically installed at the end of one toothed plate body (50421), and guide grooves (50422) are symmetrically opened inside the other toothed plate body (50421). The guide rods (50423) are slidably installed inside the guide grooves (50422).

8. The continuous cutting equipment for processing steel structure components according to claim 6, characterized in that: The moving drive component includes a transverse screw (5048) rotatably mounted inside the transverse sliding frame (5047), the transverse screw (5048) being threadedly connected to the support slide (5046), one end of the transverse screw (5048) being fixedly connected to the output shaft of the second motor (5049), and the second motor (5049) being mounted at one end of the transverse sliding frame (5047).

9. A continuous cutting device for processing steel structure components according to claim 6, characterized in that: The relative moving component includes a push cylinder (5045) mounted on a support slide (5046). The output end of the push cylinder (5045) points to the gap between the two toothed plate bodies (50421). A push plate (5043) is fixedly mounted on the output end of the push cylinder (5045). Two second connecting rods (5044) are symmetrically hinged on the push plate (5043). The ends of the two second connecting rods (5044) are respectively hinged to the two toothed plate bodies (50421).