Glass curtain wall processing device and method thereof

By designing lifting and adjusting adsorption components, the problems of unstable fixation and poor shock absorption in glass curtain wall processing devices have been solved. This has enabled stable fixation and safety in cutting glass of different sizes, enhanced cleaning effect and synchronization, and prevented glass from falling off.

CN118125705BActive Publication Date: 2026-06-26XUANCHENG CONCH CONSTR PHOTOVOLTAIC TECH CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Patents(China)
Current Assignee / Owner
XUANCHENG CONCH CONSTR PHOTOVOLTAIC TECH CO LTD
Filing Date
2024-03-28
Publication Date
2026-06-26

AI Technical Summary

Technical Problem

Existing glass curtain wall processing equipment suffers from problems such as unstable fixation, poor shock absorption, low cutting safety, and easy detachment of glass from the cut edges.

Method used

A glass curtain wall processing device was designed, comprising a lifting component, an adjusting adsorption component, a cutting component, a cleaning component, a fixing component, and a shock-absorbing component. The lifting component and the adjusting adsorption component achieve stable fixing, the cutting component and the cleaning component improve cutting effect and cleanliness, the fixing component prevents glass from falling off, and the shock-absorbing component adapts to different glass sizes, thus simultaneously achieving fixing, shock absorption, and cleaning.

Benefits of technology

It improves the stability and safety of glass curtain wall processing, enhances the applicability to glass of different sizes, reduces glass damage and cleaning difficulty, prevents glass from falling off, and improves the synchronization and efficiency of cutting.

✦ Generated by Eureka AI based on patent content.

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Abstract

The application discloses a glass curtain wall processing device and a method thereof, and relates to the field of glass curtain wall processing devices. The application comprises a rack, a lifting assembly, an adjusting and adsorbing assembly, a cutting assembly, a cleaning assembly, a fixing assembly and a damping assembly. The lifting assembly is arranged at the bottom of the rack, the adjusting and adsorbing assembly is arranged at the bottom of the lifting assembly, the cutting assembly is connected to one side of the adjusting and adsorbing assembly, the cleaning assembly and the fixing assembly are arranged on one side of the cutting assembly, and the damping assembly is arranged between the lifting assembly and the cutting assembly. In the process of cutting movement of the cutting knife, the third ball block is driven to move downwards, the second suction disc adsorbs the glass that is not adsorbed by the first suction disc in the process of cutting movement of the cutting knife, the cut glass is prevented from falling, and the safety hazard is prevented. In the process of returning of the cutting knife, the second suction disc is withdrawn, the glass can be cut down, and the cut glass can be continuously processed and utilized.
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Description

Technical Field

[0001] This invention relates to the field of glass curtain wall processing equipment, and in particular to a glass curtain wall processing equipment and method thereof. Background Technology

[0002] Glass curtain walls refer to building envelope or decorative structures that are supported by a structural system and can have a certain displacement capacity relative to the main structure, without sharing the load of the main structure. The walls can be single-layered or double-layered glass. Glass curtain walls are an aesthetically pleasing and novel method of building wall decoration and a prominent feature of the modernist high-rise building era. Photovoltaic glass can also be installed in glass curtain walls to generate solar power.

[0003] Glass curtain walls require cutting during production and processing. Existing glass curtain wall processing equipment consists of suction cups, a moving arm, and a diamond cutter. During cutting, the suction cups hold the glass curtain wall in place, and then the moving arm is manually rotated, which in turn moves the diamond cutter to perform the cutting. However, the following problems exist:

[0004] 1. During the glass fixing process of the glass curtain wall processing equipment, since the sizes of the glass to be cut are different and the fixing structure is not suitable, the fixing is unstable, which reduces the cutting effect and cutting safety.

[0005] 2. During the glass cutting process, the glass curtain wall processing equipment produces different vibration amplitudes on the glass because the sizes of the glass to be cut are different. Therefore, the required effect of the shock absorption structure is also different. If the shock absorption is not good, it can easily cause damage to the glass.

[0006] During the glass cutting process, the glass edges of the glass curtain wall processing equipment are prone to falling off directly due to external force after cutting, causing safety hazards and making the cut glass unusable. Summary of the Invention

[0007] The purpose of this invention is to provide a glass curtain wall processing device that can improve cutting effect, protect glass from damage, and improve cutting safety.

[0008] This invention relates to a glass curtain wall processing device, comprising a frame, a lifting assembly, an adjusting adsorption assembly, a cutting assembly, a cleaning assembly, a fixing assembly, and a shock-absorbing assembly;

[0009] The lifting assembly is located at the bottom of the frame, the adjusting adsorption assembly is located at the bottom of the lifting assembly, the cutting assembly is connected to one side of the adjusting adsorption assembly, the cleaning assembly and the fixing assembly are both located on one side of the cutting assembly, and the shock absorption assembly is located between the lifting assembly and the cutting assembly.

[0010] The adjustable adsorption assembly includes a mounting frame, a first drive screw, a dual-head motor, a first ball block, a connecting frame, a first suction cup, a first transmission pulley, and a first transmission belt. The four mounting frames are hollow inside. The first drive screw is movably disposed inside the mounting frame. The first ball block is movably disposed on the first drive screw. The top of the connecting frame is connected to the bottom of the first ball block. The first suction cup is connected to the bottom of the connecting frame. One end of the first drive screw is connected to one side of the first transmission pulley. The first transmission pulley is driven by the first transmission belt. The two ends of the dual-head motor are respectively connected to one side of the two first transmission pulleys.

[0011] The mounting bracket has four parts, arranged in pairs in parallel. Each of the four first drive screws has a first transmission pulley at one end. The two parallel first transmission pulleys are driven by a first transmission belt. The dual-head motor is connected to the two symmetrical first transmission pulleys.

[0012] The cutting assembly includes a movable frame, a connecting rod, a second drive screw, a second ball block, a blade holder, a cutting blade, and a drive motor. Several movable frames are hollow inside. The second drive screw is movably disposed inside one movable frame. The second ball block is movably disposed on the second drive screw. One end of the connecting rod is connected to one side of the connecting frame, and the other end of the connecting rod is connected to one side of the movable frame. The blade holder is disposed at the bottom of the second ball block, and the cutting blade is disposed at the bottom of the blade holder. The output end of the drive motor is connected to one end of the second drive screw.

[0013] The cleaning assembly includes a transmission unit and a blowing unit;

[0014] The transmission unit includes a first rack, a first gear, a second gear, and a second rack. The side of the first rack is connected to the side of the second ball block. The first gear and the second gear are both movably mounted on the top of the movable frame, and the first gear is connected to the second gear. The first rack meshes with the first gear, and the second rack meshes with the second gear.

[0015] The blowing unit includes a moving rod, an air cylinder body, and an air supply pipe. The air cylinder body is located on the top of the moving frame. The moving rod is connected to the output end of the air cylinder body. The moving rod is located on the side of the second rack. The tool holder is provided with an air supply chamber and an air jet hole. The air jet hole is connected to the air supply chamber. One end of the air supply pipe is connected to the output end of the air cylinder body, and the other end of the air supply pipe is connected to the air supply chamber.

[0016] The fixing assembly includes a third drive screw, a third ball block, a support frame, and a second suction cup. The third drive screw is connected to the bottom of the first gear, the third ball block is movably mounted on the third drive screw, one end of the support frame is connected to the side of the third ball block, and the other end of the support frame is connected to the top of the second suction cup.

[0017] The shock absorption assembly includes a connecting column, a third rack, a mounting column, a third gear, a fourth drive screw, a fourth ball block, a moving block, a telescopic rod, a buffer spring, and a contactor. Each end of the connecting column is connected to a connecting frame. The third rack is mounted on the outer wall of the connecting column. The mounting column is located at the bottom of the lifting assembly. The third gear is movably mounted at the bottom of the mounting column. The fourth drive screw is connected to the bottom of the third gear. The fourth ball block is movably mounted on the fourth drive screw. The moving block is located on the outer wall of the fourth ball block. The telescopic rod and the buffer spring are both located at the bottom of the moving block. The buffer spring is sleeved on the outer wall of the telescopic rod. The contactor is located at the end of the telescopic rod furthest from the moving block. The third rack meshes with the third gear.

[0018] The mounting column is installed on the lifting frame.

[0019] The lifting assembly includes a hydraulic telescopic device and a lifting frame. The fixed end of the hydraulic telescopic device is located at the bottom of the frame, and the lifting frame is connected to the movable end of the hydraulic telescopic device.

[0020] The cutting blade is located between the air jet and the second suction cup.

[0021] The jet orifice is frustum-shaped, and the diameter of the jet orifice where it communicates with the air delivery chamber is larger than the diameter of the jet orifice located at the tool holder.

[0022] A method for processing glass curtain walls includes the following steps:

[0023] S1. Install glass curtain wall;

[0024] Place the glass curtain wall below the unit, with the center of the glass curtain wall aligned with the center of the rack.

[0025] S2, Fixed glass curtain wall;

[0026] Start the dual-head motor to drive the first drive screw to rotate, which in turn drives the first ball block to move, indirectly causing the first suction cup on the connecting frame to move to fit the size of the glass. Start the hydraulic telescopic device to move the lifting frame downward. The movement of the lifting frame drives the first suction cup downward, allowing the first suction cup to adhere to the glass curtain wall and fix the glass curtain wall.

[0027] S3, Cutting glass curtain walls;

[0028] During the movement of the connecting frame, the moving frame connected to the connecting frame also moves to the place where it needs to be cut. The drive motor is started, causing the second drive screw to rotate, which indirectly drives the second ball block to move, so that the cutting blade on the blade holder moves and cuts on the glass curtain wall.

[0029] S4, shock absorption;

[0030] During the movement of the connecting frame, the connecting column and the third rack move, which in turn drives the third gear meshing with the third rack to rotate. The rotation of the third gear drives the fourth drive screw to rotate, causing the fourth ball block to move downward, which in turn drives the moving block to move downward, so that the contactor contacts the glass. When the glass size is different, the distance the connecting frame moves is different, which causes the third gear to rotate a different number of times, that is, the distance the fourth ball block moves downward is different, which causes the moving block to move a different distance. The distance between the moving block and the contactor is different, which in turn causes the extension and retraction of the telescopic rod and the buffer spring to be different, in order to adapt to different sizes of glass.

[0031] S5. Cleaning;

[0032] During the movement of the mobile frame, the first rack moves, the first rack drives the first gear to rotate, the first gear drives the second gear to rotate, the rotation of the second gear causes the second rack to move, which drives the moving rod to inflate the air cylinder body and input the gas into the air supply chamber through the air supply pipe, and then spray it out through the jet hole. Since the jet hole is close to the part of the cutting blade that cuts the glass, it will blow away the glass shards on it.

[0033] S6, Fixed;

[0034] During the cutting process, the moving frame moves, which drives the first rack to move. The first rack drives the first gear to rotate, which in turn causes the third drive screw to rotate, which in turn drives the third ball block to move downward. The downward movement of the third ball block causes the second suction cup to pick up the glass that the cutting blade is cutting but is not picked up by the first suction cup.

[0035] The present invention has the following beneficial effects:

[0036] 1. In this invention, during the movement of the moving frame, the first rack moves, the first rack drives the first gear to rotate, the first gear drives the second gear to rotate, the rotation of the second gear causes the second rack to move, which in turn drives the moving rod to inflate the air cylinder body and input the gas into the air supply chamber through the air supply pipe, and then spray it out through the jet hole. Since the jet hole is close to the part of the glass being cut by the cutting blade, it will blow away the glass shards on it, cleaning the glass and reducing the difficulty of subsequent cleaning.

[0037] 2. This invention, by starting a dual-head motor, drives the first drive screw to rotate, which in turn moves the first ball block, indirectly causing the first suction cup on the connecting frame to move to fit the size of the glass. Activating the hydraulic telescopic device moves the lifting frame downwards, which in turn moves the first suction cup downwards, allowing it to adhere to the glass curtain wall and fix it in place. This allows the glass curtain wall to adapt to various glass sizes, improving its applicability and stability, and enhancing both the cutting effect and safety.

[0038] 3. This invention improves the cleaning effect by moving the mobile frame synchronously with the air delivery and jetting process.

[0039] 4. In this invention, during the cutting process of the cutting blade, the moving frame moves, driving the first rack to move. The first rack drives the first gear to rotate, which in turn causes the third drive screw to rotate, driving the third ball block to move downward. The downward movement of the third ball block causes the second suction cup to adhere to the glass that the cutting blade is cutting but is not adhered to by the first suction cup, preventing the cut glass from falling and avoiding safety hazards. During the cutting blade's return to its original position, the second suction cup is removed, allowing the glass to be unloaded and the cut glass to be further processed and reused.

[0040] 5. This invention, during the movement of the connecting frame, drives the connecting column and the third rack to move, and drives the third gear meshing with the third rack to rotate. The rotation of the third gear drives the fourth drive screw to rotate, causing the fourth ball block to move downward, which in turn moves the moving block downward, causing the contactor to contact the glass. When the glass size is different, the distance the connecting frame moves is different, causing the third gear to rotate a different number of times, that is, the distance the fourth ball block moves downward is different, causing the moving block to move a different distance, and the distance between the moving block and the contactor is different. Therefore, the extension and retraction of the telescopic rod and the buffer spring are different, which is used to adapt to different sizes of glass, improves the shock absorption effect of different sized glass, and prevents glass damage.

[0041] 6. This invention uses a dual-head motor to drive the connecting frame to move, so that fixing the glass and shock absorption are synchronized, and cutting the glass, cleaning and preventing it from falling are synchronized, thus improving the synchronization of the device.

[0042] Of course, any product implementing this invention does not necessarily need to achieve all of the advantages described above at the same time. Attached Figure Description

[0043] To more clearly illustrate the technical solutions of the embodiments of the present invention, the accompanying drawings used in the description of the embodiments will be briefly introduced below. Obviously, the drawings described below are only some embodiments of the present invention. For those skilled in the art, other drawings can be obtained based on these drawings without creative effort.

[0044] Figure 1 This is a three-dimensional structural diagram of a glass curtain wall processing device according to the present invention;

[0045] Figure 2 This is a front view schematic diagram of a glass curtain wall processing device according to the present invention;

[0046] Figure 3 This is a side view of a glass curtain wall processing device according to the present invention;

[0047] Figure 4 For the present invention Figure 3 Partial cross-sectional view at point AA;

[0048] Figure 5 This is a schematic diagram of the fixing component and cleaning component structure of the present invention;

[0049] Figure 6 This is a schematic diagram of the shock absorption component structure of the present invention;

[0050] Figure 7 For the present invention Figure 2 Enlarged view of a section at point D;

[0051] Figure 8 This is a schematic diagram of the internal structure of the shock absorption component of the present invention;

[0052] Figure 9 This is a schematic diagram of the cleaning component structure of the present invention.

[0053] The attached diagram lists the components represented by each number as follows:

[0054] 110. Frame; 120. Lifting assembly; 1201. Hydraulic telescopic device; 1202. Lifting frame; 130. Adjustable suction assembly; 1301. Mounting frame; 1302. First drive screw; 1303. Dual-head motor; 1304. First ball bearing block; 1305. Connecting frame; 1306. First suction cup; 1307. First transmission pulley; 1308. First transmission belt; 140. Cutting assembly; 1401. Moving frame; 1402. Connecting rod; 1403. Second drive screw; 1404. Second ball bearing block; 1405. Tool holder; 1406. Cutting blade; 1407. Drive motor; 150. Cleaning assembly; 1501. First rack; 150 2. First gear; 1503. Second gear; 1504. Second rack; 1505. Moving rod; 1506. Air cylinder body; 1507. Air supply pipe; 1508. Air supply chamber; 1509. Air jet hole; 160. Fixing assembly; 1601. Third drive screw; 1602. Third ball block; 1603. Support frame; 1604. Second suction cup; 170. Shock absorption assembly; 1701. Connecting column; 1702. Third rack; 1703. Mounting column; 1704. Third gear; 1705. Fourth drive screw; 1706. Fourth ball block; 1707. Moving block; 1708. Telescopic rod; 1709. Buffer spring; 1711. Contactor. Detailed Implementation

[0055] 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.

[0056] In the description of this invention, it should be understood that the terms "upper," "middle," "outer," "inner," etc., which indicate orientation or positional relationship, are only for the convenience of describing this invention and simplifying the description, and do not indicate or imply that the components or elements referred to must have a specific orientation, or be constructed and operated in a specific orientation, and therefore should not be construed as limiting this invention.

[0057] like Figure 1-9 As shown, this embodiment of a glass curtain wall processing device includes a frame 110, a lifting assembly 120, an adjusting adsorption assembly 130, a cutting assembly 140, a cleaning assembly 150, a fixing assembly 160, and a shock-absorbing assembly 170.

[0058] The lifting assembly 120 is located at the bottom of the frame 110, the adjusting adsorption assembly 130 is located at the bottom of the lifting assembly 120, the cutting assembly 140 is connected to one side of the adjusting adsorption assembly 130, the cleaning assembly 150 and the fixing assembly 160 are both located on one side of the cutting assembly 140, and the shock absorption assembly 170 is located between the lifting assembly 120 and the cutting assembly 140.

[0059] The adjustable adsorption assembly 130 includes a mounting frame 1301, a first drive screw 1302, a dual-head motor 1303, a first ball block 1304, a connecting frame 1305, a first suction cup 1306, a first transmission pulley 1307, and a first transmission belt 1308. The four mounting frames 1301 are hollow inside. The first drive screw 1302 is movably disposed inside the mounting frame 1301. The first ball block 1304 is movably disposed on the first drive screw 1302. The top of the connecting frame 1305 is connected to the bottom of the first ball block 1304. The first suction cup 1306 is connected to the bottom of the connecting frame 1305. One end of the first drive screw 1302 is connected to one side of the first transmission pulley 1307. The first transmission pulley 1307 is driven by the first transmission belt 1308. The two ends of the dual-head motor 1303 are respectively connected to one side of the two first transmission pulleys 1307.

[0060] During operation, the dual-head motor 1303 is started, driving the first drive screw 1302 to rotate, which in turn moves the first ball block 1304, indirectly causing the first suction cup 1306 on the connecting frame 1305 to move to fit the size of the glass. The hydraulic telescopic device 1201 is then activated, causing the lifting frame 1202 to move downwards. The movement of the lifting frame 1202 drives the first suction cup 1306 downwards, allowing the first suction cup 1306 to adhere to the glass curtain wall and fix it in place. This allows the glass curtain wall to adapt to glass of various sizes, improving its applicability and making the fixation more stable, thus improving the cutting effect and cutting safety.

[0061] The mounting bracket 1301 has four parts, arranged in pairs in parallel. Each of the four first drive screws 1302 has a first transmission pulley 1307 at one end. The two parallel first transmission pulleys 1307 are driven by a first transmission belt 1308. The dual-head motor 1303 is connected to the two symmetrical first transmission pulleys 1307.

[0062] The cutting assembly 140 includes a movable frame 1401, a connecting rod 1402, a second drive screw 1403, a second ball block 1404, a blade holder 1405, a cutting blade 1406, and a drive motor 1407. The movable frames 1401 are hollow inside. The second drive screw 1403 is movably disposed inside one of the movable frames 1401. The second ball block 1404 is movably disposed on the second drive screw 1403. One end of the connecting rod 1402 is connected to one side of the connecting frame 1405, and the other end of the connecting rod 1402 is connected to one side of the movable frame 1401. The blade holder 1405 is disposed at the bottom of the second ball block 1404, and the cutting blade 1406 is disposed at the bottom of the blade holder 1405. The output end of the drive motor 1407 is connected to one end of the second drive screw 1403.

[0063] Cleaning component 150 includes a transmission unit and a blowing unit;

[0064] The transmission unit includes a first rack 1501, a first gear 1502, a second gear 1503, and a second rack 1504. The side of the first rack 1501 is connected to the side of the second ball block 1404. The first gear 1502 and the second gear 1503 are both movably mounted on the top of the movable frame 1401, and the first gear 1502 is connected to the second gear 1503. The first rack 1501 meshes with the first gear 1502, and the second rack 1504 meshes with the second gear 1503.

[0065] The blowing unit includes a moving rod 1505, an air cylinder body 1506, and an air supply pipe 1507. The air cylinder body 1506 is located on the top of the moving frame 1401. The moving rod 1505 is connected to the output end of the air cylinder body 1506. The moving rod 1505 is located on the side of the second rack 1504. The tool holder 1405 is provided with an air supply chamber 1508 and an air jet hole 1509. The air jet hole 1509 is connected to the air supply chamber 1508. One end of the air supply pipe 1507 is connected to the output end of the air cylinder body 1506, and the other end of the air supply pipe 1507 is connected to the air supply chamber 1508.

[0066] During operation, as the moving frame 1401 moves, it drives the first rack 1501 to move. The first rack 1501 drives the first gear 1502 to rotate, and the first gear 1502 drives the second gear 1503 to rotate. The rotation of the second gear 1503 causes the second rack 1504 to move, which in turn drives the moving rod 1505 to inflate the air cylinder body 1506. The gas is then fed into the air supply chamber 1508 through the air supply pipe 1507 and then ejected through the jet nozzle 1509. Since the jet nozzle 1509 is close to the part of the cutting blade 1406 that cuts the glass, it blows away the glass shards, cleaning the glass and reducing the difficulty of subsequent cleaning.

[0067] During operation, the mobile frame 1401 moves synchronously with the air delivery and jetting process, improving the cleaning effect.

[0068] The fixing assembly 160 includes a third drive screw 1601, a third ball block 1602, a support frame 1603, and a second suction cup 1604. The third drive screw 1601 is connected to the bottom of the first gear 1502. The third ball block 1602 is movably mounted on the third drive screw 1601. One end of the support frame 1603 is connected to the side of the third ball block 1602, and the other end of the support frame 1603 is connected to the top of the second suction cup 1604.

[0069] During operation, as the cutting blade 1406 moves, the moving frame 1401 moves, driving the first rack 1501 to move. The first rack 1501 drives the first gear 1502 to rotate, which in turn causes the third drive screw 1601 to rotate, causing the third ball block 1602 to move downwards. The downward movement of the third ball block 1602 causes the second suction cup 1604 to hold the glass that the cutting blade 1406 is cutting but is not held by the first suction cup 1306, preventing the cut glass from falling and avoiding safety hazards. During the return of the cutting blade 1406, the second suction cup 1604 is removed, allowing the glass to be removed and further processed and reused.

[0070] The shock absorption assembly 170 includes a connecting column 1701, a third rack 1702, a mounting column 1703, a third gear 1704, a fourth drive screw 1705, a fourth ball block 1706, a moving block 1707, a telescopic rod 1708, a buffer spring 1709, and a contactor 1711. The connecting column 1701 is connected to a connecting bracket 1705 at each end. The third rack 1702 is mounted on the outer wall of the connecting column 1701. The mounting column 1703 is located at the bottom of the lifting assembly 120. The third gear 1704 is movably mounted on the mounting column 1701. At the bottom of 03, the fourth drive screw 1705 is connected to the bottom of the third gear 1704, the fourth ball block 1706 is movably mounted on the fourth drive screw 1705, the moving block 1707 is mounted on the outer wall of the fourth ball block 1706, the telescopic rod 1708 and the buffer spring 1709 are both mounted at the bottom of the moving block 1707, the buffer spring 1709 is sleeved on the outer wall of the telescopic rod 1708, the contactor 1711 is mounted at the end of the telescopic rod 1708 away from the moving block 1707, and the third rack 1702 meshes with the third gear 1704;

[0071] During operation, as the connecting frame 1305 moves, it drives the connecting column 1701 and the third rack 1702 to move, and drives the third gear 1704, which meshes with the third rack 1702, to rotate. The rotation of the third gear 1704 drives the fourth drive screw 1705 to rotate, causing the fourth ball block 1706 to move downward, which in turn drives the moving block 1707 to move downward, so that the contactor 1711 contacts the glass. When the glass size is different, the distance the connecting frame 1305 moves is different, which causes the third gear 1704 to rotate a different number of times. That is, the distance the fourth ball block 1706 moves downward is different, which causes the moving block 1707 to move a different distance. The distance between the moving block 1707 and the contactor 1711 is different, which in turn causes the telescopic rod 1708 and the buffer spring 1709 to extend or retract differently. This is used to adapt to different sizes of glass, improve the shock absorption effect for different sizes of glass, and prevent glass damage.

[0072] Among them, the mounting column 1703 is installed on the lifting frame 1202.

[0073] The lifting assembly 120 includes a hydraulic telescopic device 1201 and a lifting frame 1202. The fixed end of the hydraulic telescopic device 1201 is located at the bottom of the frame 110, and the lifting frame 1202 is connected to the movable end of the hydraulic telescopic device 1201.

[0074] The cutting blade 1406 is located between the jet port 1509 and the second suction cup 1604.

[0075] The jet nozzle 1509 is frustum-shaped, and the diameter of the connection between the jet nozzle 1509 and the air delivery chamber 1508 is larger than the diameter of the jet nozzle 1509 located at the tool holder 1405.

[0076] A method for processing glass curtain walls includes the following steps:

[0077] S1. Install glass curtain wall;

[0078] Place the glass curtain wall below the device, with the center of the glass curtain wall aligned with the center of the rack 110;

[0079] S2, Fixed glass curtain wall;

[0080] Start the dual-head motor 1303 to drive the first drive screw 1302 to rotate, which in turn drives the first ball block 1304 to move, indirectly causing the first suction cup 1306 on the connecting frame 1305 to move to fit the size of the glass. Start the hydraulic telescopic device 1201 to move the lifting frame 1202 downward. The movement of the lifting frame 1202 drives the first suction cup 1306 downward, so that the first suction cup 1306 adheres to the glass curtain wall and fixes the glass curtain wall.

[0081] S3, Cutting glass curtain walls;

[0082] During the movement of the connecting frame 1305, the moving frame 1401 connected to the connecting frame 1305 also moves to the place where it needs to be cut. The drive motor 1407 is started, causing the second drive screw 1403 to rotate, which indirectly drives the second ball block 1404 to move, so that the cutting blade 1406 on the blade holder 1405 moves and cuts on the glass curtain wall.

[0083] S4, shock absorption;

[0084] During the movement of the connecting frame 1305, the connecting column 1701 and the third rack 1702 are moved, and the third gear 1704 meshing with the third rack 1702 is rotated. The rotation of the third gear 1704 drives the fourth drive screw 1705 to rotate, causing the fourth ball block 1706 to move downward, which in turn causes the moving block 1707 to move downward, so that the contactor 1711 contacts the glass. When the glass size is different, the distance the connecting frame 1305 moves is different, which causes the third gear 1704 to rotate a different number of times. That is, the distance the fourth ball block 1706 moves downward is different, which causes the moving block 1707 to move a different distance. The distance between the moving block 1707 and the contactor 1711 is different, so the extension and retraction of the telescopic rod 1708 and the buffer spring 1709 are different, which is used to adapt to different sizes of glass.

[0085] S5. Cleaning;

[0086] During the movement of the moving frame 1401, the first rack 1501 is moved, the first rack 1501 drives the first gear 1502 to rotate, the first gear 1502 drives the second gear 1503 to rotate, the rotation of the second gear 1503 causes the second rack 1504 to move, which drives the moving rod 1505 to inflate the air cylinder body 1506, and the gas is input into the air supply chamber 1508 through the air supply pipe 1507, and then sprayed out through the jet hole 1509. Since the jet hole 1509 is close to the part of the cutting blade 1406 that cuts the glass, it will blow away the glass shards on it.

[0087] S6, Fixed;

[0088] During the cutting process of the cutting blade 1406, the moving frame 1401 moves and drives the first rack 1501 to move. The first rack 1501 drives the first gear 1502 to rotate. The first gear 1502 causes the third drive screw 1601 to rotate, which drives the third ball block 1602 to move downward. The downward movement of the third ball block 1602 causes the second suction cup 1604 to pick up the glass that the cutting blade 1406 cuts but is not picked up by the first suction cup 1306.

[0089] The device uses a dual-head motor 1303 to drive the connecting frame 1305 to move, which synchronizes the fixing of the glass with the shock absorption, and the cutting of the glass with the cleaning and anti-falling, thus improving the synchronization of the device.

[0090] The preferred embodiments of the present invention disclosed above are merely illustrative of the invention. These preferred embodiments do not exhaustively describe all details, nor do they limit the invention to the specific implementations described. Clearly, many modifications and variations can be made based on the content of this specification. This specification selects and specifically describes these embodiments to better explain the principles and practical applications of the invention, thereby enabling those skilled in the art to better understand and utilize the invention. The invention is limited only by the claims and their full scope and equivalents.

Claims

1. A glass curtain wall processing device, characterized in that, It includes a frame (110), a lifting assembly (120), an adjusting suction assembly (130), a cutting assembly (140), a cleaning assembly (150), a fixing assembly (160), and a shock-absorbing assembly (170). The lifting assembly (120) is located at the bottom of the frame (110), the adjusting adsorption assembly (130) is located at the bottom of the lifting assembly (120), the cutting assembly (140) is connected to one side of the adjusting adsorption assembly (130), the cleaning assembly (150) and the fixing assembly (160) are both located on one side of the cutting assembly (140), and the shock absorption assembly (170) is located between the lifting assembly (120) and the cutting assembly (140). The adjustable adsorption assembly (130) includes a mounting frame (1301), a first drive screw (1302), a dual-head motor (1303), a first ball bearing block (1304), a connecting frame (1305), a first suction cup (1306), a first transmission pulley (1307), and a first transmission belt (1308). The four mounting frames (1301) are hollow inside. The first drive screw (1302) is movably disposed inside the mounting frame (1301), and the first ball bearing block (1304) is movably disposed inside the first drive screw (1302). The first drive screw (1302) is placed on the first drive screw (1302), the top of the connecting frame (1305) is connected to the bottom of the first ball block (1304), the first suction cup (1306) is connected to the bottom of the connecting frame (1305), one end of the first drive screw (1302) is connected to one side of the first transmission pulley (1307), the first transmission pulley (1307) is driven by the first transmission belt (1308), and the two ends of the dual-head motor (1303) are respectively connected to one side of the two first transmission pulleys (1307); The cutting assembly (140) includes a movable frame (1401), a connecting rod (1402), a second drive screw (1403), a second ball block (1404), a blade holder (1405), a cutting blade (1406), and a drive motor (1407). Several movable frames (1401) are hollow inside. The second drive screw (1403) is movably disposed inside one movable frame (1401). The second ball block (1404) is movably disposed on the second drive screw (1403). One end of the connecting rod (1402) is connected to one side of the connecting frame (1405), and the other end of the connecting rod (1402) is connected to one side of the movable frame (1401). The blade holder (1405) is disposed at the bottom of the second ball block (1404), and the cutting blade (1406) is disposed at the bottom of the blade holder (1405). The output end of the drive motor (1407) is connected to one end of the second drive screw (1403). The cleaning assembly (150) includes a transmission part and a blowing part; The transmission unit includes a first rack (1501), a first gear (1502), a second gear (1503), and a second rack (1504). The side of the first rack (1501) is connected to the side of the second ball block (1404). The first gear (1502) and the second gear (1503) are both movably disposed on the top of the movable frame (1401), and the first gear (1502) is connected to the second gear (1503). The first rack (1501) meshes with the first gear (1502), and the second rack (1504) meshes with the second gear (1503). The fixing component (160) includes a third drive screw (1601), a third ball block (1602), a support frame (1603), and a second suction cup (1604). The third drive screw (1601) is connected to the bottom of the first gear (1502). The third ball block (1602) is movably mounted on the third drive screw (1601). One end of the support frame (1603) is connected to the side of the third ball block (1602), and the other end of the support frame (1603) is connected to the top of the second suction cup (1604). The shock absorption assembly (170) includes a connecting column (1701), a third rack (1702), a mounting column (1703), a third gear (1704), a fourth drive screw (1705), a fourth ball block (1706), a moving block (1707), a telescopic rod (1708), a buffer spring (1709), and a contactor (1711). The connecting column (1701) is connected to a connecting frame (1305) at each end. The third rack (1702) is mounted on the outer wall of the connecting column (1701). The mounting column (1703) is located at the bottom of the lifting assembly (120). The third gear (1704) is movably mounted on the mounting column (1701). 03) At the bottom, the fourth drive screw (1705) is connected to the bottom of the third gear (1704), the fourth ball block (1706) is movably mounted on the fourth drive screw (1705), the moving block (1707) is mounted on the outer wall of the fourth ball block (1706), the telescopic rod (1708) and the buffer spring (1709) are both mounted at the bottom of the moving block (1707), the buffer spring (1709) is sleeved on the outer wall of the telescopic rod (1708), the contactor (1711) is mounted at the end of the telescopic rod (1708) away from the moving block (1707), and the third rack (1702) meshes with the third gear (1704); The lifting assembly (120) includes a hydraulic telescopic device (1201) and a lifting frame (1202). The fixed end of the hydraulic telescopic device (1201) is located at the bottom of the frame (110), and the lifting frame (1202) is connected to the movable end of the hydraulic telescopic device (1201).

2. The glass curtain wall processing device according to claim 1, characterized in that, The blowing unit includes a moving rod (1505), an air cylinder body (1506), and an air supply pipe (1507). The air cylinder body (1506) is located on the top of the moving frame (1401). The moving rod (1505) is connected to the output end of the air cylinder body (1506). The moving rod (1505) is located on the side of the second rack (1504). The knife holder (1405) is provided with an air supply chamber (1508) and an air jet hole (1509). The air jet hole (1509) is connected to the air supply chamber (1508). One end of the air supply pipe (1507) is connected to the output end of the air cylinder body (1506), and the other end of the air supply pipe (1507) is connected to the air supply chamber (1508).

3. The glass curtain wall processing device according to claim 2, characterized in that, The cutting blade (1406) is located between the air jet (1509) and the second suction cup (1604).

4. A glass curtain wall processing device according to claim 3, characterized in that, The jet hole (1509) is frustum-shaped, and the diameter of the jet hole (1509) communicating with the air delivery chamber (1508) is larger than the diameter of the jet hole (1509) located at the tool holder (1405).

5. The method of using the glass curtain wall processing device according to claim 4, characterized in that, Includes the following steps: S1. Install glass curtain wall; Place the glass curtain wall below the device, with the center of the glass curtain wall aligned with the center of the frame (110); S2, Fixed glass curtain wall; Start the dual-head motor (1303) to drive the first drive screw (1302) to rotate, which in turn drives the first ball block (1304) to move, indirectly causing the first suction cup (1306) on the connecting frame (1305) to move to fit the size of the glass. Start the hydraulic telescopic device (1201) to move the lifting frame (1202) downward. The movement of the lifting frame (1202) drives the first suction cup (1306) downward, so that the first suction cup (1306) adheres to the glass curtain wall and fixes the glass curtain wall. S3, Cutting glass curtain walls; During the movement of the connecting frame (1305), the moving frame (1401) connected to the connecting frame (1305) also moves to the place where it needs to be cut. The drive motor (1407) is started, causing the second drive screw (1403) to rotate, which indirectly drives the second ball block (1404) to move, so that the cutting blade (1406) on the blade holder (1405) moves and cuts on the glass curtain wall. S4, shock absorption; During the movement of the connecting frame (1305), the connecting column (1701) and the third rack (1702) are moved, and the third gear (1704) meshing with the third rack (1702) is rotated. The rotation of the third gear (1704) drives the fourth drive screw (1705) to rotate, causing the fourth ball block (1706) to move downward, causing the moving block (1707) to move downward, so that the contactor (1711) contacts the glass. When the glass size is different, the distance the connecting frame (1305) moves is different, causing the third gear (1704) to rotate a different number of times, that is, the distance the fourth ball block (1706) moves downward is different, causing the moving block (1707) to move a different distance. The distance between the moving block (1707) and the contactor (1711) is different, so the extension and retraction of the telescopic rod (1708) and the buffer spring (1709) are different, which is used to adapt to different sizes of glass. S5. Cleaning; During the movement of the moving frame (1401), the first rack (1501) is moved, the first rack (1501) drives the first gear (1502) to rotate, the first gear (1502) drives the second gear (1503) to rotate, the rotation of the second gear (1503) causes the second rack (1504) to move, which drives the moving rod (1505) to inflate the air cylinder body (1506), and the gas is input into the air supply chamber (1508) through the air supply pipe (1507), and then sprayed out through the jet hole (1509). Since the jet hole (1509) is close to the part of the cutting blade (1406) that cuts the glass, it will blow away the glass shards on it. S6, Fixed; During the cutting process of the cutting blade (1406), the moving frame (1401) moves and drives the first rack (1501) to move. The first rack (1501) drives the first gear (1502) to rotate. The first gear (1502) causes the third drive screw (1601) to rotate, which drives the third ball block (1602) to move downward. The downward movement of the third ball block (1602) causes the second suction cup (1604) to adhere to the glass that the cutting blade (1406) is cutting but is not adhered to by the first suction cup (1306).