Processing device for curtain wall profile pieces

Abstract

The utility model discloses a curtain wall section member's processingequipment. Curtain wall section member's processingequipment includes: processing platform, including bearing station and support frame, a plurality of clamping components are installed on bearing station, and each clamping component is used for clamping curtain wall section member, cutting assembly is installed on support frame, and cutting assembly includes movable frame, mechanical arm, first rotation drive part and cutting tool, and movable frame is slidably connected in first lateral direction on support frame, and mechanical arm is rotatably installed on movable frame, and first rotation drive part is used for driving mechanical arm rotation around first rotation axis, and cutting tool is installed on mechanical arm, and cutting tool is used for contacting curtain wall section member and cutting curtain wall section member, first reciprocating drive part is used for driving movable frame along first lateral direction movement. According to curtain wall section member's processingequipment of the utility model embodiment, can adjust cutting angle, to be able to complete more complex cutting work.

Description

Technical Field

[0001] This utility model relates to the field of profile processing, and in particular to a processing device for curtain wall profiles. Background Technology

[0002] With the development and advancement of building technology, more and more irregularly shaped curtain walls are being used as new types of facade structures in construction. Irregularly shaped curtain wall structures are more complex; therefore, the curtain wall profiles for irregularly shaped curtain walls are more difficult to cut and process compared to those for ordinary curtain walls. The processing equipment for curtain wall profiles using related technologies cannot adjust the cutting angle, making it difficult to complete more complex cutting tasks. Utility Model Content

[0003] This utility model provides a processing device for curtain wall profiles, which can adjust the cutting angle to complete more complex cutting work.

[0004] This utility model provides a processing device for curtain wall profile components, comprising: a processing platform including a bearing platform and a support frame disposed on the upper side of the bearing platform; a plurality of clamping assemblies mounted on the bearing platform, the plurality of clamping assemblies being arranged along a first transverse direction, each clamping assembly being used to clamp the curtain wall profile component; a cutting assembly mounted on the support frame, the cutting assembly including a movable frame, a robotic arm, a first rotation drive component, and a cutting tool, the movable frame being slidably connected to the support frame along the first transverse direction, the robotic arm being rotatably mounted on the movable frame, wherein a first axis of rotation of the robotic arm relative to the movable frame is parallel to the first transverse direction, the first rotation drive component being mounted on the movable frame and being driveably connected to the robotic arm, the first rotation drive component being used to drive the robotic arm to rotate around the first axis of rotation, the cutting tool being mounted on the robotic arm, the cutting tool being used to contact and cut the curtain wall profile component; and a first reciprocating drive component being mounted on the support frame and being driveably connected to the movable frame, the first reciprocating drive component being used to drive the movable frame to move along the first transverse direction.

[0005] According to the foregoing embodiments of this utility model, the cutting tool is at least partially detachably connected to the robotic arm.

[0006] According to any of the foregoing embodiments of the present invention, the cutting tool includes a cutting wheel, a cutting drive component, and a transmission arm. The cutting drive component is mounted on the robotic arm, the transmission arm is connected to the cutting drive component, the cutting wheel is mounted on the transmission arm, and the cutting drive component is used to drive the cutting wheel to rotate through the transmission arm.

[0007] According to any of the foregoing embodiments of the present invention, the movable frame includes a first mounting frame, a second mounting frame, and a second reciprocating drive member. The first mounting frame is slidably connected to the support frame along the first transverse direction, and the second mounting frame is slidably connected to the first mounting frame along the longitudinal direction. The robotic arm is mounted on the second mounting frame, and the second reciprocating drive member is mounted on the first mounting frame and is connected to the second mounting frame in a transmission manner. The second reciprocating drive member is used to drive the second mounting frame to move along the longitudinal direction.

[0008] According to any of the foregoing embodiments of the present invention, the robotic arm includes a telescopic arm, a connecting arm, and a telescopic drive component. The telescopic arm and the telescopic drive component are mounted on the movable frame. The telescopic drive component is connected to the telescopic arm and is used to drive the telescopic end of the telescopic arm to telescopically extend and retract. The connecting arm is connected to the telescopic end of the telescopic arm.

[0009] According to any of the foregoing embodiments of the present invention, each of the clamping components is detachably connected to the support platform.

[0010] According to any of the foregoing embodiments of the present invention, each clamping assembly includes a base, a fixed block, a movable block, and a clamping drive component. The base can be installed on the support platform. The fixed block and the clamping drive component are installed on the base and arranged opposite to each other. The movable block is connected to the clamping drive component. The clamping drive component is used to drive the movable block to move closer to or away from the fixed block. The curtain wall profile component can be clamped between the fixed block and the movable block.

[0011] According to any of the foregoing embodiments of the present invention, the base is slidably connected to the support platform along the first transverse direction.

[0012] According to any of the foregoing embodiments of the present invention, the support platform is provided with a plurality of positioning holes arranged along the first transverse direction, and each clamping component further includes a limiting member, the limiting member being movably connected to the base, the limiting member being able to insert into and retract from the positioning hole, and the clamping component being limited along the first transverse direction when the limiting member is inserted into the positioning hole.

[0013] According to any of the foregoing embodiments of the present invention, the processing device for curtain wall profiles further includes: a control box, wherein the control box is electrically connected to the cutting assembly and the first reciprocating drive component.

[0014] The processing device for curtain wall profiles according to an embodiment of the present invention includes a processing platform, multiple clamping assemblies, a cutting assembly, and a first reciprocating drive. The clamping assemblies clamp the curtain wall profiles, temporarily fixing their position. The cutting assembly includes a movable frame, a robotic arm, a first rotary drive, and a cutting tool. The cutting tool contacts and cuts the curtain wall profiles. When the cutting tool starts operating and contacts the curtain wall profiles, the first reciprocating drive drives the movable frame to move along a first transverse direction, thereby driving the cutting assembly to move along the first transverse direction, causing the cutting tool to cut the curtain wall profiles along the first transverse direction. Before or during cutting, the first rotary drive can drive the robotic arm to rotate around a first pivot, thereby adjusting the cutting angle of the cutting tool acting on the curtain wall profiles, thus enabling the processing device for curtain wall profiles to perform more complex cutting tasks. Attached Figure Description

[0015] To more clearly illustrate the technical solutions in the embodiments of this utility model or the prior art, the drawings used in the description of the embodiments or the prior art will be briefly introduced below. Obviously, the drawings described below are only some embodiments of this utility model. For those skilled in the art, other drawings can be obtained based on the structures shown in these drawings without creative effort.

[0016] Figure 1 This is a three-dimensional schematic diagram of an embodiment of the processing device for curtain wall profiles of this utility model;

[0017] Figure 2 This is a three-dimensional schematic diagram of the cutting component in one embodiment of the processing device for curtain wall profiles of this utility model;

[0018] Figure 3 for Figure 1 A magnified view of a portion of region A in the middle.

[0019] Explanation of reference numerals in the attached figures:

[0020] 100 - Machining platform; 110 - Bearing platform; 111 - Positioning hole; 112 - Waste trough; 120 - Support frame;

[0021] 200-Clamping assembly; 210-Base; 220-Fixed block; 230-Moving block; 240-Clamping drive component; 250-Limiting component;

[0022] 300-Cutting assembly; 310-Modible frame; 311-First mounting frame; 312-Second mounting frame; 313-Second reciprocating drive component; 320-Mechanical arm; 321-Telescopic arm; 322-Connecting arm; 323-Telescopic drive component; 330-First rotary drive component; 340-Cutting tool; 341-Cutting wheel; 342-Cutting drive component; 343-Transmission arm;

[0023] 400 - First reciprocating drive component;

[0024] 500-Control Box;

[0025] 710 - First reciprocating transmission component;

[0026] 810 - First sliding component; 820 - Second sliding component; 830 - Third sliding component;

[0027] X - First horizontal direction; Y - Second horizontal direction; Z - Vertical direction.

[0028] The realization of the purpose, functional features and advantages of this utility model will be further explained in conjunction with the embodiments and with reference to the accompanying drawings. Detailed Implementation

[0029] 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.

[0030] It should be noted that all directional indicators in this utility model embodiment, such as up, down, left, right, front, back, etc., are only used to explain the relative positional relationship and movement of the components in a specific posture as shown in the attached figure. If the specific posture changes, the directional indicator will also change accordingly.

[0031] Furthermore, the use of terms such as "first" and "second" in this utility model is for descriptive purposes only and should not be construed as indicating or implying their relative importance or implicitly specifying the number of technical features indicated. Therefore, a feature defined as "first" or "second" may explicitly or implicitly include at least one of that feature. Additionally, the technical solutions of the various embodiments can be combined with each other, but only on the basis of being achievable by those skilled in the art. When the combination of technical solutions is contradictory or impossible to implement, such a combination of technical solutions should be considered non-existent and not within the scope of protection claimed by this utility model.

[0032] This utility model provides a processing device for curtain wall profile components. The device is used to perform film ring cutting on a roll assembly. The roll assembly includes a roll body and a film layer covering the outer surface of the roll body. The film layer includes an end-face film covering the end face of the roll body and a peripheral-face film covering the periphery of the roll body. In this embodiment, the roll body is taken as an example of a cap roll used for milk powder caps. This cap roll includes multiple cap bodies used as milk powder caps.

[0033] Figure 1 This is a perspective view of an embodiment of the processing device for curtain wall profiles according to the present invention. The processing device for curtain wall profiles is used to cut curtain wall profiles. The processing device for curtain wall profiles includes a processing platform 100, multiple clamping assemblies 200, a cutting assembly 300, and a first reciprocating drive 400.

[0034] The processing platform 100 includes a support platform 110 and a support frame 120 disposed on the upper side of the support platform 110. In some embodiments, the support frame 120 is located on one side above the support platform 110. A plurality of clamping assemblies 200 are mounted on the support platform 110, and the plurality of clamping assemblies 200 are arranged along a first transverse direction X, each clamping assembly 200 being used to clamp a curtain wall profile component.

[0035] Figure 2 This is a perspective view of a cutting assembly in one embodiment of the processing device for curtain wall profiles according to this utility model. The cutting assembly 300 is mounted on a support frame 120. The cutting assembly 300 includes a movable frame 310, a robotic arm 320, a first rotation drive 330, and a cutting tool 340. The movable frame 310 is slidably connected to the support frame 120 along a first transverse direction X. The robotic arm 320 is rotatably mounted on the movable frame 310, wherein a first axis of rotation of the robotic arm 320 relative to the movable frame 310 is parallel to the first transverse direction X. The first rotation drive 330 is mounted on the movable frame 310 and is driveably connected to the robotic arm 320. The first rotation drive 330 is used to drive the robotic arm 320 to rotate around the first axis. The cutting tool 340 is mounted on the robotic arm 320. The cutting tool 340 is used to contact and cut the curtain wall profile.

[0036] The first reciprocating drive 400 is mounted on the support frame 120 and is connected to the movable frame 310 in a transmission manner. The first reciprocating drive 400 is used to drive the movable frame 310 to move along the first transverse X.

[0037] The processing apparatus for curtain wall profiles according to an embodiment of the present invention includes a processing platform 100, multiple clamping assemblies 200, a cutting assembly 300, and a first reciprocating drive 400. The clamping assemblies 200 can clamp the curtain wall profiles, temporarily fixing their position. The cutting assembly 300 includes a movable frame 310, a robotic arm 320, a first rotation drive 330, and a cutting blade 340. The cutting blade 340 is used to contact and cut the curtain wall profiles. When the cutting blade 340 starts operating and contacts the curtain wall profiles, the first reciprocating drive 400 drives the movable frame 310 to move along a first transverse direction X, thereby driving the cutting assembly 300 to move along the first transverse direction X, causing the cutting blade 340 to cut the curtain wall profiles along the first transverse direction X. Before or during cutting, the first rotation drive 330 can drive the robotic arm 320 to rotate around the first rotating shaft, thereby adjusting the cutting angle of the cutting tool 340 acting on the curtain wall profile, realizing the adjustment of the cutting angle, so that the processing device of the curtain wall profile can complete more complex cutting work.

[0038] In some embodiments, the movable frame 310 is slidably mounted on the support platform 110 via a first sliding assembly 810. The first sliding assembly 810 is, for example, a first slide rail assembly, including a first slide rail disposed on the support frame 120 and extending along a first transverse direction X, and a first slider disposed on the movable frame 310, the first slider slidingly engaging with the first slide rail. In other embodiments, the first sliding assembly 810 may be other sliding guide structures, such as a guide groove structure.

[0039] In some embodiments, the first reciprocating drive 400 is connected to the movable frame 310 via a first reciprocating transmission 710. Optionally, the first reciprocating drive 400 is a motor, and the first reciprocating transmission 710 can be a known reciprocating transmission component such as a transmission belt, transmission chain, or transmission rack assembly.

[0040] In some embodiments, the cutting tool 340 is at least partially detachably connected to the robotic arm 320, making the cutting tool 340 replaceable and improving the flexibility of the cutting tool 340 configuration in the processing device for curtain wall profiles. In some embodiments, the cutting tool 340 and the robotic arm 320 are detachably connected by means of bolt connection, snap-fit ​​connection, or clamping connection.

[0041] In some embodiments, the cutting tool 340 includes a cutting wheel 341, a cutting drive 342, and a transmission arm 343. The cutting drive 342 is mounted on the robotic arm 320. The transmission arm 343 is connected to the cutting drive 342. The cutting wheel 341 is mounted on the transmission arm 343. The cutting drive 342 is used to drive the cutting wheel 341 to rotate via the transmission arm 343.

[0042] In one example, the transmission arm 343 is equipped with a transmission chain, the cutting drive 342 is a motor, the cutting wheel 341 is rotatably connected to the transmission arm 343, and the cutting wheel 341 is connected to the cutting drive 342 through the transmission chain in the transmission arm 343. The cutting drive 342 drives the cutting wheel 341 to rotate through the transmission chain.

[0043] In some embodiments, the movable frame 310 includes a first mounting frame 311, a second mounting frame 312, and a second reciprocating drive 313. The first mounting frame 311 is slidably connected to the support frame 120 along a first transverse direction X. The second mounting frame 312 is slidably connected to the first mounting frame 311 along a longitudinal direction Z. A robotic arm 320 is mounted on the second mounting frame 312. The second reciprocating drive 313 is mounted on the first mounting frame 311 and is drively connected to the second mounting frame 312. The second reciprocating drive 313 is used to drive the second mounting frame 312 to move along the longitudinal direction Z.

[0044] In some embodiments, the second mounting bracket 312 is slidably mounted on the first mounting bracket 311 via a second sliding component 820, such as a second slide rail assembly. In other embodiments, the second sliding component 820 may be other sliding guide structures, such as a guide groove structure.

[0045] In some embodiments, the second reciprocating drive 313 may be a linear drive connected to the second mounting bracket 312, thereby driving the second mounting bracket 312 to perform reciprocating linear motion. Exemplarily, the linear drive may be a linear module. In other embodiments, the second reciprocating drive 313 may be driveably connected to the second mounting bracket 312 via other transmission components.

[0046] In the above embodiment, the second reciprocating drive 313 can drive the second mounting bracket 312 to move longitudinally Z, so that the second mounting bracket 312 can drive the robotic arm 320 and the cutting tool 340 to move longitudinally Z. That is, it can also adjust the cutting tool 340 by raising and lowering, so that the cutting tool 340 has more adjustable dimensions, which further facilitates the processing device of curtain wall profile to complete more complex cutting work.

[0047] In some embodiments, the robotic arm 320 includes a telescopic arm 321, a connecting arm 322, and a telescopic drive 323. The telescopic arm 321 and the telescopic drive 323 are mounted on a movable frame 310. The telescopic drive 323 is connected to the telescopic arm 321. The telescopic drive 323 drives the telescopic end of the telescopic arm 321 to extend and retract. The connecting arm 322 is connected to the telescopic end of the telescopic arm 321. The telescopic arm 321 can employ a telescopic arm 321 structure known in the art of robotic arms 320. In one example, the telescopic drive 323 drives the telescopic end of the telescopic arm 321 to extend and retract along a first transverse direction X; in other embodiments, the telescopic end of the telescopic arm 321 can be configured to extend and retract in other directions.

[0048] In the above embodiment, the telescopic end of the telescopic arm 321 can extend and retract, so that the cutting tool 340 can extend and retract relative to the movable frame 310, making the cutting tool 340 more adjustable and further facilitating the processing device of the curtain wall profile to complete more complex cutting work.

[0049] In some embodiments, each clamping assembly 200 is detachably connected to the support platform 110, thereby enabling flexible configuration of the position and number of clamping assemblies 200 to facilitate the clamping of various types and sizes of curtain wall profiles.

[0050] Figure 3 for Figure 1 A partially enlarged schematic diagram of region A. In some embodiments, each clamping assembly 200 includes a base 210, a fixed block 220, a movable block 230, and a clamping drive member 240. The base 210 can be mounted on the support platform 110. The fixed block 220 and the clamping drive member 240 are mounted on the base 210 and disposed opposite to each other. The movable block 230 is connected to the clamping drive member 240. The clamping drive member 240 is used to drive the movable block 230 to move closer to or away from the fixed block 220. The curtain wall profile can be clamped between the fixed block 220 and the movable block 230.

[0051] When the movable block 230 moves toward the fixed block 220, the clamping assembly 200 gradually clamps, thereby clamping and fixing the curtain wall profile. When the movable block 230 moves away from the fixed block 220, the curtain wall profile can be released.

[0052] In one example, the clamping drive 240 is an electrically telescopic member, and the movable block 230 is mounted on the telescopic end of the electrically telescopic member. In other embodiments, the clamping drive 240 may be an electrically reciprocating drive member, and the movable block 230 is mounted on the reciprocating movable end of the electrically reciprocating drive member. In other embodiments, the clamping drive 240 may also be a non-electric member.

[0053] In some embodiments, the movable block 230 and the fixed block 220 are disposed opposite each other along a second transverse direction Y, which is perpendicular to the first transverse direction X.

[0054] In some embodiments, the base 210 is slidably connected to the support platform 110 along the first transverse X.

[0055] In some embodiments, the base 210 is slidably mounted on the support platform 110 via a third sliding assembly 830. The third sliding assembly 830 is, for example, a third slide rail assembly, including a third slide rail disposed on the support platform 110 and extending along a first transverse direction X, and a third slider disposed on the base 210, the third slider slidingly engaging with the third slide rail. In other embodiments, the third sliding assembly 830 may be other sliding guide structures, such as a guide groove structure.

[0056] In some embodiments, the support platform 110 is provided with a plurality of positioning holes 111 arranged along the first transverse direction X. Each clamping assembly 200 also includes a limiting member 250. The limiting member 250 is movably connected to the base 210 and can be inserted into and removed from the positioning holes 111. When the limiting member 250 is inserted into the positioning hole 111, the clamping assembly 200 is limited along the first transverse direction X. By providing the positioning holes 111 and the limiting member 250, the clamping assembly 200 can be temporarily limited along the first transverse direction X, ensuring the stability of clamping the curtain wall profile.

[0057] In some embodiments, the support platform 110 is provided with a waste trough 112 for collecting cutting waste. In one example, the clamping assembly 200 is located above the waste trough 112, and the cutting waste generated during the cutting of the curtain wall profile can fall into the waste trough 112 under its own gravity.

[0058] In some embodiments, the processing apparatus for curtain wall profiles further includes a control box 500. The control box 500 is electrically connected to the cutting assembly 300 and the first reciprocating drive 400. In some embodiments, the control box 500 is electrically connected to the cutting assembly 300 and the first reciprocating drive 400 via electrical connection lines (the electrical connection lines are omitted from the drawing). In some embodiments, the control box 500 includes a power supply component and a control component. The power supply component, i.e., a power source, provides electrical power to the electrical components in the processing apparatus for curtain wall profiles. The control component may be a computer capable of controlling the electrically connected electrical components.

[0059] In one example, the control box 500 is electrically connected to the first reciprocating drive 400, thereby controlling the working state of the first reciprocating drive 400 to drive the movable frame 310 to move along the first transverse X direction. The control box 500 is also electrically connected to the first rotary drive 330, thereby controlling the working state of the first rotary drive 330 to drive the robotic arm 320 to rotate around the first axis, thus adjusting the cutting angle. The control box 500 is also electrically connected to the cutting drive 342, thereby controlling the working state of the cutting drive 342 to drive the cutting wheel 341 to rotate. Finally, the control box 500 is electrically connected to the second reciprocating drive 313, thereby controlling the working state of the second reciprocating drive 313 to drive the second mounting frame 312 to move along the longitudinal Z direction. The control box 500 is electrically connected to the telescopic drive component 323, thereby controlling the working state of the telescopic drive component 323 to drive the telescopic end of the telescopic arm 321 to extend and retract. The control box 500 is also electrically connected to the clamping drive component 240, thereby controlling the working state of the clamping drive component 240 to drive the movable block 230 to move closer to or further away from the fixed block 220.

[0060] The above description is only a preferred embodiment of the present utility model and does not limit the patent scope of the present utility model. All equivalent structural transformations made under the concept of the present utility model and using the contents of the present utility model specification and drawings, or direct / indirect applications in other related technical fields, are included in the patent protection scope of the present utility model.

Claims

1. A processing device for curtain wall profiles, characterized in that, include: The processing platform includes a support platform and a support frame disposed on the upper side of the support platform; Multiple clamping components are installed on the support platform. The multiple clamping components are arranged along a first transverse direction, and each clamping component is used to clamp the curtain wall profile. A cutting assembly is mounted on the support frame. The cutting assembly includes a movable frame, a robotic arm, a first rotation drive, and a cutting blade. The movable frame is slidably connected to the support frame along a first transverse direction. The robotic arm is rotatably mounted on the movable frame. The first axis of rotation of the robotic arm relative to the movable frame is parallel to the first transverse direction. The first rotation drive is mounted on the movable frame and is connected to the robotic arm in a transmission manner. The first rotation drive is used to drive the robotic arm to rotate around the first axis. The cutting blade is mounted on the robotic arm and is used to contact the curtain wall profile and cut the curtain wall profile. A first reciprocating drive component is mounted on the support frame and is connected to the movable frame in a transmission manner. The first reciprocating drive component is used to drive the movable frame to move along the first transverse direction.

2. The processing apparatus for curtain wall profiles as described in claim 1, characterized in that, The cutting tool is at least partially detachably connected to the robotic arm.

3. The processing apparatus for curtain wall profiles as described in claim 1, characterized in that, The cutting tool includes a cutting wheel, a cutting drive component, and a transmission arm. The cutting drive component is mounted on the robotic arm, and the transmission arm is connected to the cutting drive component. The cutting wheel is mounted on the transmission arm, and the cutting drive component is used to drive the cutting wheel to rotate through the transmission arm.

4. The processing apparatus for curtain wall profiles as described in claim 1, characterized in that, The movable frame includes a first mounting frame, a second mounting frame, and a second reciprocating drive. The first mounting frame is slidably connected to the support frame along the first transverse direction, and the second mounting frame is slidably connected to the first mounting frame along the longitudinal direction. The robotic arm is mounted on the second mounting frame, and the second reciprocating drive is mounted on the first mounting frame and is connected to the second mounting frame in a transmission manner. The second reciprocating drive is used to drive the second mounting frame to move along the longitudinal direction.

5. The processing apparatus for curtain wall profiles as described in claim 1, characterized in that, The robotic arm includes a telescopic arm, a connecting arm, and a telescopic drive component. The telescopic arm and the telescopic drive component are mounted on the movable frame. The telescopic drive component is connected to the telescopic arm and is used to drive the telescopic end of the telescopic arm to extend and retract. The connecting arm is connected to the telescopic end of the telescopic arm.

6. The processing apparatus for curtain wall profiles as described in claim 1, characterized in that, Each of the clamping components is detachably connected to the support platform.

7. The processing apparatus for curtain wall profiles as described in claim 1, characterized in that, Each clamping assembly includes a base, a fixed block, a movable block, and a clamping drive. The base can be installed on the support platform. The fixed block and the clamping drive are installed on the base and arranged opposite to each other. The movable block is connected to the clamping drive. The clamping drive is used to drive the movable block to move closer to or away from the fixed block. The curtain wall profile can be clamped between the fixed block and the movable block.

8. The processing apparatus for curtain wall profiles as described in claim 7, characterized in that, The base is slidably connected to the support platform along the first transverse direction.

9. The processing apparatus for curtain wall profiles as described in claim 8, characterized in that, The support platform is provided with a plurality of positioning holes arranged along the first transverse direction. Each clamping component also includes a limiting member, which is movably connected to the base. The limiting member can be inserted into and removed from the positioning hole. When the limiting member is inserted into the positioning hole, the clamping component is limited along the first transverse direction.

10. The processing apparatus for curtain wall profiles as described in claim 1, characterized in that, Also includes: A control box, which is electrically connected to the cutting assembly and the first reciprocating drive component.

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