ALC partition board cutting device
By designing a movable ALC partition wall cutting device, the problems of poor cutting accuracy and difficulty in moving existing equipment have been solved, achieving efficient and precise cutting results, adapting to diverse construction needs, and reducing manual labor intensity and dust diffusion.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Applications(China)
- Current Assignee / Owner
- CHINA TIESIJU CIVIL ENGINEERING GROUP CO LTD
- Filing Date
- 2026-04-27
- Publication Date
- 2026-06-05
AI Technical Summary
Existing ALC partition wall cutting equipment suffers from problems such as poor cutting accuracy, bulky and difficult-to-move equipment, high cost, and difficulty in adapting to diverse on-site cutting needs.
An ALC partition wall panel cutting device was designed, comprising a moving frame, cutting components, rotating components, and lifting components. It can flexibly switch between horizontal and vertical cutting postures, and the device can be moved by casters. It is equipped with negative pressure dust collection and laser-assisted devices to improve cutting accuracy and working environment.
It enables precise cutting of ALC partition panels, reduces manual labor intensity, adapts to various construction site requirements, improves cutting efficiency and accuracy, and reduces dust diffusion.
Smart Images

Figure CN122143227A_ABST
Abstract
Description
Technical Field
[0001] This invention relates to the field of wall panel cutting technology, and more particularly to an ALC partition wall panel cutting device. Background Technology
[0002] The statements herein provide only background information in relation to this invention and do not necessarily constitute prior art.
[0003] ALC partition wall panels (autoclaved aerated concrete panels) are a high-performance, lightweight, and environmentally friendly new type of prefabricated building wall material, widely used in the construction of non-load-bearing interior partition walls in various projects such as residential, office, and commercial buildings. In actual construction, due to site limitations such as building height, door openings, and pipeline pre-installation, some ALC partition wall panels (standard factory specifications, such as 6m length, 600mm width, 100 / 150 / 200mm thickness) require cutting and processing according to site dimensions to meet installation requirements.
[0004] Currently, there are two main traditional methods for on-site cutting of ALC partition panels: Manual cutting method: Construction workers use a handheld cutting machine to cut along the marked lines on the wall panel. This method relies on manual operation and has the following drawbacks: poor cutting accuracy, prone to skewed cuts and dimensional deviations, resulting in excessive gaps in the wall panel installation and affecting construction quality; extremely low cutting efficiency, requiring multiple segment cuts for a 6m long panel, resulting in high labor intensity and a long construction period.
[0005] Fixed large-scale cutting equipment: Some construction sites use factory-produced large gantry-type cutting equipment, requiring wall panels to be transported to fixed workstations for cutting. While this method can ensure cutting accuracy, it has the following limitations: the equipment is bulky and immobile, unable to adapt to the flexible operation needs of construction sites, requiring secondary transfer of wall panels, increasing construction costs and losses; the equipment is complex to debug, unable to adjust the cutting height in real time according to site dimensions, making it difficult to meet diverse on-site cutting needs; the equipment cost is high, making it unaffordable for small and medium-sized construction units and lacking universality.
[0006] Therefore, there is an urgent need for a specialized cutting device with a simple structure, mobility, high cutting precision, and high operating efficiency to meet the actual needs of on-site cutting of ALC partition panels in prefabricated building construction. Summary of the Invention
[0007] The purpose of this invention is to address the aforementioned shortcomings by providing an ALC partition wall cutting device.
[0008] To solve the above-mentioned technical problems, the present invention adopts the following technical solution: An ALC partition wall panel cutting device, comprising: The movable frame has legs around its four sides, with casters at the bottom of the legs. The movable frame has an inlet at the front end along its direction of movement and an outlet at the rear end. One end of the partition plate can enter the movable frame through the inlet and exit through the outlet. The movable frame has a push handle for pushing the movable frame to move. The cutting component is set inside the movable frame, with its cutting end facing the partition wall panel, and is used to cut the partition wall panel from the side. The rotating component, connected to the cutting component, is used to adjust the cutting posture of the cutting component, allowing the cutting component to switch between a transverse cutting posture and a longitudinal cutting posture; The lifting component is used to move the cutting component up and down, adjusting the cutting height of the cutting component.
[0009] Furthermore, two cutting components are provided and symmetrically arranged within the movable frame. Each cutting component includes a cutting saw blade and a cutting motor. The cutting motor is used to drive the cutting saw blade to rotate and cut the partition wall from the side of the partition wall. A gap is reserved between the cutting saw blades on the two cutting components, and the two cutting saw blades are arranged on the same plane.
[0010] Furthermore, the rotating component includes a fixed ring and a rotating ring. The rotating ring is rotatably disposed within the fixed ring, and the cutting component is fixed within the rotating ring and rotates synchronously with the rotating ring. The fixed ring is connected to the lifting component, causing the rotating ring to rise and fall together with the lifting component. The rotating ring is provided with a gear ring, and a gear meshing with it is provided on one side of the gear ring. The gear is connected to a drive motor, which drives the gear to rotate, thereby driving the rotating ring to rotate and realizing the adjustment of the posture of the cutting part.
[0011] Furthermore, the lifting component is used to synchronously adjust the height of the two cutting components, including a lifting element and a connecting assembly. The connecting assembly includes a lifting plate, guide rods symmetrically arranged on both sides of the lifting plate, and guide grooves arranged on the movable frame and adapted to the guide rods. The lifting element is connected to the lifting plate and is used to drive the lifting plate to move up and down. One end of the guide rod is fixedly connected to the lifting plate, and the other end extends downward and is connected to the corresponding fixing ring.
[0012] Furthermore, a slide rail is provided on the top of the movable frame, the slide rail is arranged along the traveling direction of the movable frame, a slide table is slidably mounted on the top of the slide rail, the slide table is located directly below the lifting plate, the lifting element is located between the slide table and the lifting plate, the guide groove is fixed on both sides of the lifting plate, a fixing block is provided at the bottom of the slide table, a screw hole is opened in the fixing block, a screw is rotatably mounted on the movable frame, one end of the screw is rotatably connected to the movable frame, the other end passes through the screw hole and is screwed into the screw hole, and a handle is provided at the end of the screw away from the fixing block.
[0013] Furthermore, multiple positioning components are provided on both sides of the bottom of the movable frame. The positioning components include positioning rods and pulleys. One end of the positioning rod is fixedly connected to the side of the movable frame, and the other end extends toward the inside of the movable frame. The pulley is installed at the end of the positioning rod and is used to make rolling contact with the side of the partition wall.
[0014] Furthermore, the length of the positioning rod is adjustable.
[0015] Furthermore, a slide is fixed at the top position of the partition wall panel within the movable frame, and multiple rollers are mounted at the bottom of the slide. The rollers are used to make rolling contact with the top surface of the partition wall panel to achieve stable support and movement of the equipment on the top of the partition wall panel.
[0016] Furthermore, the carriage includes two parallel support rods, which are fixed inside the moving frame along the moving direction of the moving frame, and each support rod is provided with clearance at the cutting component corresponding to the longitudinal cutting posture; The rollers are evenly and fixedly mounted on the bottom of the support rod, and the end of the support rod corresponding to the entrance of the moving frame is inclined upward to form a guide slope, which is used to guide the partition wall panel to smoothly enter the entrance of the moving frame.
[0017] Furthermore, the movable frame is covered with a dust cover, and the dust cover has reserved holes at the corresponding lifting components. Dustproof cloths are provided at the corresponding inlet and outlet of the movable frame to suppress the spread of dust during cutting.
[0018] The beneficial effects of this invention are reflected in: This invention can flexibly achieve precise cutting of ALC partition boards in both length and width directions according to the actual needs of on-site construction. The cutting accuracy is high, effectively avoiding problems such as skewed cuts and dimensional deviations that are prone to occur in existing technologies. At the same time, this application adopts a "fixed partition board, movable equipment" cutting method, which eliminates the need for workers to frequently move the heavy ALC partition boards, greatly reducing the intensity of manual labor. Furthermore, the entire equipment can be moved flexibly via casters, making it adaptable to various construction site working environments and more convenient to use. Attached Figure Description
[0019] Figure 1 This is a schematic diagram of the operation of the ALC partition wall cutting equipment described in this application; Figure 2 This is a schematic diagram of the ALC partition wall cutting equipment described in this application; Figure 3 This is a schematic diagram of the lifting component described in this application; Figure 4This is a schematic diagram of the structure of the rotating component described in this application; Figure 5 This is a schematic diagram showing the position of the fixing block described in this application; Figure 6 This is a schematic diagram of the structure of the carriage described in this application.
[0020] In the picture: 1. Moving frame; 11. Support legs; 12. Casters; 13. Dust cover; 14. Push handle; 15. Slide rail; 16. Slide table; 161. Fixing block; 17. Screw; 18. Handle; 2. Cutting components; 3. Rotating components; 31. Fixed ring; 32. Rotating ring; 321. Gear ring; 33. Gear; 34. Drive motor; 4. Lifting components; 41. Lifting plate; 42. Guide rod; 43. Guide groove; 44. Lifting element; 5. Positioning components; 51. Positioning rod; 52. Pulley; 6. Carriage; 61. Support rod; 62. Roller; 7. Partition wall panels. Detailed Implementation
[0021] 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 a part of the embodiments of the present invention, and not all of them. Unless otherwise specified, the embodiments and features in the embodiments of this application can be combined with each other. 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.
[0022] Please see Figures 1-6 This invention discloses an ALC partition wall panel cutting device, comprising: The movable frame 1 has legs 11 around its perimeter and casters 12 at the bottom of the legs 11. The movable frame 1 has an inlet at the front end along its moving direction and an outlet at the rear end. One end of the partition wall 7 can enter the movable frame 1 through the inlet and exit through the outlet. The movable frame 1 has a push handle 14, which makes it easy for workers to hold and push the movable frame 1 to move smoothly along the length of the partition wall 7. The cutting component 2 is set inside the movable frame 1, with its cutting end facing the partition wall 7, and is used to cut the partition wall 7 from the side of the partition wall 7. The rotating component 3 is connected to the cutting component 2 and is used to adjust the cutting posture of the cutting component 2, so that the cutting component 2 can switch between the horizontal cutting posture and the vertical cutting posture to adapt to the cutting requirements of the partition wall panel 7 in different directions. The lifting component 4 is used to move the cutting component 2 up and down to adjust the cutting height of the cutting component 2.
[0023] In specific implementation, such as Figure 1 As shown, the partition wall 7 is placed upright on the ground (a single partition wall 7 can be placed at a time, or multiple partition wall 7 can be placed side by side for simultaneous cutting according to construction needs). The worker holds the push handle 14 and pushes the moving frame 1 to move along the length of the partition wall 7, so that one end of the partition wall 7 enters the equipment from the entrance at the front of the moving frame 1. The cutting component 2 located in the moving frame 1 starts the cutting operation from the side of the partition wall 7 at the same time.
[0024] Based on the attitude adjustment function of the rotating component 3, the equipment can flexibly switch between two cutting modes: when it is necessary to reduce the width of the ALC partition 7, the rotating component 3 is used to adjust the cutting component 2 to a horizontal cutting posture, and then the lifting component 4 is used to adjust the cutting component 2 to the preset cutting height. The operator continuously pushes the moving frame 1 to move smoothly, and the cutting component 2 makes continuous cuts along the length of the partition 7 to complete the precise reduction of the width of the partition 7; when it is necessary to vertically divide the length of the ALC partition 7, the rotating component 3 is used to adjust the cutting component 2 to a vertical cutting posture, the moving frame 1 is pushed to the preset cutting position and fixed (a caster 12 with locking function can be used), and then the lifting component 4 drives the cutting component 2 to move up and down in the vertical direction to complete the vertical division of the length of the partition 7.
[0025] This application can flexibly achieve precise cutting of ALC partition wall panels 7 in both length and width directions according to actual needs and on-site construction requirements. The cutting accuracy is high, effectively avoiding problems such as skewed cuts and dimensional deviations that are prone to occur in existing technologies. At the same time, this application adopts a cutting method of "fixing partition wall panels 7 and moving equipment", which eliminates the need for workers to frequently move the heavy ALC partition wall panels 7 (a single 6m long and 100mm thick partition wall panel 7 weighs about 230~240kg), greatly reducing the intensity of manual labor. Moreover, the entire equipment can be moved flexibly via casters 12, which can adapt to various construction site working environments and is more convenient to use.
[0026] In one embodiment, two cutting components 2 are provided and symmetrically arranged within the movable frame 1. Each cutting component 2 includes a cutting saw blade and a cutting motor. The cutting motor is used to drive the cutting saw blade to rotate and cut the partition wall 7 from the side of the partition wall 7. A gap is reserved between the cutting saw blades on the two cutting components 2, and the two cutting saw blades are arranged on the same plane.
[0027] In practice, the gap between the two cutting saw blades is 5mm-10mm: this avoids interference between the two cutting saw blades. After the cutting is completed, the construction personnel only need to apply a small amount of external force to make the partition wall 7 break smoothly along the cutting marks.
[0028] Preferably, in order to suppress the spread of dust generated during the cutting operation, the cutting component 2 adopts a dust-collecting cutting structure with negative pressure dust collection function, which can simultaneously collect the dust generated during the cutting of ALC partition 7 and improve the working environment.
[0029] Preferably, the cutting component 2 further includes a synchronous cutting laser auxiliary device (not shown), which is used to emit laser markings to help construction workers observe the height position of the wall panel being cut, thereby further improving the cutting accuracy.
[0030] In one embodiment, the rotating component 3 includes a fixed ring 31 and a rotating ring 32. The rotating ring 32 is rotatably disposed inside the fixed ring 31. The cutting component 2 is fixed inside the rotating ring 32 and rotates synchronously with the rotating ring 32. The fixed ring 31 is connected to the lifting component 4, which drives the rotating ring 32 to rise and fall together with the lifting component 4. The rotating ring 32 is provided with a gear ring 321, and a gear 33 meshing with it is provided on one side of the gear ring 321. The gear 33 is connected to a drive motor 34. The drive motor 34 drives the gear 33 to rotate, thereby driving the rotating ring 32 to rotate, so as to adjust the posture of the cutting component 2.
[0031] During operation, the drive motor 34 outputs power to drive the gear 33 to rotate. The meshing transmission between the gear 33 and the gear ring 321 drives the rotating ring 32 to rotate relative to the fixed ring 31, thereby driving the cutting component 2 fixed in the rotating ring 32 to rotate synchronously, realizing the precise switching between the two postures of the cutting component 2 in horizontal cutting and vertical cutting.
[0032] Preferably, there are two rotating rings 32, each corresponding to one of the two cutting components 2.
[0033] Preferably, the gear ring 321 is located on the outer side, and the fixing ring 31 is designed to make way for the gear ring 321 at the corresponding position, and the drive motor 34 is fixed on the fixing ring 31.
[0034] In one embodiment, the lifting component 4 is used to synchronously adjust the height of the two cutting components 2, including a lifting element 44 and a connecting assembly. The connecting assembly includes a lifting plate 41, guide rods 42 symmetrically arranged on both sides of the lifting plate 41, and a guide groove 43 arranged on the movable frame 1 and adapted to the guide rods 42. The guide rods 42 and the guide groove 43 slide together to provide guidance and limit for the lifting of the lifting plate 41. The lifting element 44 is connected to the lifting plate 41 and is used to drive the lifting plate 41 to move up and down. One end of the guide rod 42 is fixedly connected to the lifting plate 41, and the other end extends downward and is connected to the corresponding fixing ring 31, so that the lifting of the lifting plate 41 can synchronously drive the guide rod 42, the fixing ring 31 and the cutting component 2 to rise and fall together, thereby realizing the synchronous adjustment of the height of the two cutting components 2.
[0035] In specific implementation, the lifting element 44 can adopt the structure of a screw and nut, which drives the lifting plate 41 to lift by rotating the screw. However, considering that when the cutting part 2 is in the longitudinal cutting posture, the required lifting distance is large (greater than 600mm), the screw and nut structure is difficult to efficiently adapt to the large stroke lifting requirement. Therefore, this application uses an electric telescopic rod, a pneumatic telescopic rod or a hydraulic telescopic rod as the lifting element 44. The lifting plate 41 is driven to lift smoothly by the telescopic movement of the telescopic rod, which is suitable for large stroke lifting scenarios and is convenient to operate and lifts smoothly.
[0036] Preferably, each side has two guide rods 42, which are located on both sides of the corresponding fixing ring 31. This provides symmetrical support for the fixing ring 31, ensuring the stability of the fixing ring 31 and the cutting component 2 as they move up and down with the lifting plate 41, preventing skewing and shaking, and ensuring cutting accuracy.
[0037] In one embodiment, when the cutting component 2 is in a longitudinal cutting posture, in order to ensure that the cutting component 2 can be accurately positioned at the scribing cutting position, this application further provides a positioning fine-tuning structure, the specific technical solution of which is as follows: The top of the movable frame 1 is provided with a slide rail 15, which is arranged along the traveling direction of the movable frame 1. A slide table 16 is slidably mounted on the top of the slide rail 15. The slide table 16 is located directly below the lifting plate 41. The lifting element 44 is located between the slide table 16 and the lifting plate 41. The guide groove 43 is fixed on both sides of the lifting plate 41. A fixing block 161 is provided at the bottom of the slide table 16. A screw hole is opened in the fixing block 161. A screw 17 is rotatably provided on the movable frame 1. One end of the screw 17 is rotatably connected to the movable frame 1, and the other end passes through the screw hole and is screwed into the screw hole. A handle 18 is provided at the end of the screw 17 away from the fixing block 161.
[0038] In practice, the operator first moves the movable frame 1 to the vicinity of the pre-defined marking and cutting area, then rotates the handle 18, which drives the screw 17 to rotate around its own axis. Since the screw 17 is rotatably connected to the movable frame 1 and screw-fitted to the fixed block 161, the rotation of the screw 17 is converted into a horizontal linear displacement of the slide table 16 along the slide rail 15. This, in turn, drives the lifting element 44, lifting plate 41, guide rod 42, fixing ring 31, and cutting component 2 to synchronously make horizontal fine adjustments, ultimately ensuring that the cutting component 2 is precisely positioned at the marking and cutting point. This positioning and fine-tuning structure offers high positioning accuracy and convenient operation, effectively improving the accuracy of longitudinal cutting and preventing cut deviation.
[0039] In one embodiment, multiple positioning components 5 are provided on both sides of the bottom of the movable frame 1. Each positioning component 5 includes a positioning rod 51 and a pulley 52. One end of the positioning rod 51 is fixedly connected to the side of the movable frame 1, and the other end extends toward the inside of the movable frame 1. The pulley 52 is installed at the end of the positioning rod 51 and is used to make rolling contact with the side of the partition wall 7.
[0040] In practice, each side of the movable frame 1 is equipped with two positioning components 5, which are respectively arranged at the entrance and exit ends of the movable frame 1 to form a symmetrical positioning structure. Through the rolling contact between the pulley 52 and the side of the partition plate 7, the moving direction of the movable frame 1 can be limited and guided, ensuring that the movable frame 1 does not deviate during the pushing process and always moves smoothly along the length direction of the partition plate 7, further ensuring the regularity of the cutting trajectory and avoiding skewed cuts due to equipment deviation.
[0041] Preferably, the positioning rod 51 adopts an adjustable length structure (e.g., an outer rod sleeve an inner rod, with the relative positions of the inner and outer rods fixed by bolts). The extension length of the positioning rod 51 can be flexibly adjusted according to the ALC partition wall panels 7 of different thicknesses, so that the pulley 52 is always in close contact with the side of the partition wall panel 7, adapting to the cutting needs of partition wall panels 7 of various thicknesses, and improving the versatility and positioning stability of the equipment.
[0042] In one embodiment, a slide 6 is fixedly provided inside the movable frame 1 at the top position corresponding to the partition wall 7. The bottom of the slide 6 is equipped with a plurality of rollers 62, which are used to roll in contact with the top surface of the partition wall 7 to achieve stable support and movement of the equipment on the top of the partition wall 7.
[0043] In practice, considering that some ALC partition boards 7 may be raised by pads during storage, resulting in a certain gap between the bottom of the partition board 7 and the ground, the staff can lift the movable frame 1 and place it above the partition board 7, so that the rollers 62 at the bottom of the slide 6 contact the top surface of the partition board 7. Relying on the support of the slide 6 and the rollers 62, the equipment can be placed stably and the cutting operation can be carried out normally without the need to adjust the storage height of the partition board 7, thus adapting to more construction scenarios.
[0044] Specifically, the carriage 6 includes two parallel support rods 61, which are fixed inside the moving frame 1 along the moving direction of the moving frame 1. Each support rod 61 is made to give way to the cutting component 2 in the longitudinal cutting posture to avoid interference between the support rod 61 and the cutting component 2, and to provide more space for the up and down movement of the cutting component 2, so as to ensure that the cutting operation is carried out smoothly. The rollers 62 are evenly fixedly assembled at the bottom of the support rods 61, and the end of the support rod 61 corresponding to the entrance of the moving frame 1 is inclined upward to form a guide slope, which is used to guide the partition wall 7 to smoothly enter the entrance of the moving frame 1, reducing the risk of jamming when the partition wall 7 is fed.
[0045] Preferably, each support rod 61 is positioned at the cutting component 2 in the longitudinal cutting posture by adopting a break-off structure to make way for it. This structure is simple and easy to process, which can effectively avoid interference with the cutting component 2 and ensure the overall structural strength of the support rod 61, thus ensuring stable support for the roller 62.
[0046] In one embodiment, the movable frame 1 is covered with a dust cover 13. The dust cover 13 has a reserved hole at the position of the corresponding lifting component 4. The dust cover 13 is provided with dustproof cloth at the position of the inlet and outlet of the movable frame 1 to suppress the spread of dust during cutting and improve the working environment.
[0047] In practice, the dust cover 13 can be rigid or made of flexible material.
[0048] It should be noted that if the embodiments of the present invention involve directional indicators (such as up, down, left, right, front, back, etc.), the directional indicators are only used to explain the relative positional relationship and movement of the components in a certain specific posture (as shown in the figure). If the specific posture changes, the directional indicators will also change accordingly.
[0049] Furthermore, if the embodiments of this invention involve descriptions such as "first" or "second," these descriptions are 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 with "first" or "second" may explicitly or implicitly include at least one of those features. Additionally, the technical solutions of the various embodiments can be combined with each other, but this must be based on the ability of those skilled in the art to implement them. If the combination of technical solutions is contradictory or impossible to implement, it should be considered that such a combination of technical solutions does not exist and is not within the scope of protection claimed by this invention.
[0050] Additionally, "multiple" refers to two or more.
[0051] The above description is only a preferred embodiment of the present invention and is not intended to limit the present invention. Any modifications, equivalent substitutions, improvements, etc., made within the spirit and principles of the present invention should be included within the protection scope of the present invention.
Claims
1. An ALC partition wall panel cutting device, characterized in that, include: The movable frame (1) has legs (11) around its perimeter, and casters (12) are provided at the bottom of the legs (11). The movable frame (1) has an entrance at the front end along its moving direction and an exit at the rear end. One end of the partition wall (7) can enter the movable frame (1) from the entrance and exit from the exit. The movable frame (1) has a push handle (14) for pushing the movable frame (1) to move. The cutting component (2) is set inside the movable frame (1), with its cutting end facing the partition wall (7), and is used to cut the partition wall (7) from the side of the partition wall (7); The rotating component (3) is connected to the cutting component (2) and is used to adjust the cutting posture of the cutting component (2) so that the cutting component (2) can switch between the horizontal cutting posture and the vertical cutting posture. The lifting component (4) is used to move the cutting component (2) up and down and adjust the cutting height of the cutting component (2).
2. The ALC partition wall panel cutting equipment according to claim 1, characterized in that, The cutting components (2) are provided in two symmetrically arranged within the movable frame (1). The cutting components (2) include a cutting saw blade and a cutting motor. The cutting motor is used to drive the cutting saw blade to rotate and cut the partition wall (7) from the side of the partition wall (7). A gap is reserved between the cutting saw blades on the two cutting components (2), and the two cutting saw blades are arranged on the same plane.
3. The ALC partition wall panel cutting equipment according to claim 1 or 2, characterized in that, The rotating component (3) includes a fixed ring (31) and a rotating ring (32). The rotating ring (32) is rotatably disposed inside the fixed ring (31). The cutting component (2) is fixed inside the rotating ring (32) and rotates synchronously with the rotating ring (32). The fixed ring (31) is connected to the lifting component (4) and drives the rotating ring (32) to rise and fall together with the lifting component (4). The rotating ring (32) is provided with a gear ring (321), and a gear (33) meshing with it is provided on one side of the gear ring (321). The gear (33) is connected to a drive motor (34). The drive motor (34) drives the gear (33) to rotate, thereby driving the rotating ring (32) to rotate, so as to realize the adjustment of the posture of the cutting component (2).
4. The ALC partition wall panel cutting equipment according to claim 3, characterized in that, The lifting component (4) is used to synchronously adjust the height of the two cutting components (2), including a lifting element (44) and a connecting component. The connecting component includes a lifting plate (41), guide rods (42) symmetrically arranged on both sides of the lifting plate (41), and a guide groove (43) arranged on the moving frame (1) and adapted to the guide rods (42). The lifting element (44) is connected to the lifting plate (41) and is used to drive the lifting plate (41) to move up and down. One end of the guide rod (42) is fixedly connected to the lifting plate (41), and the other end extends downward and is connected to the corresponding fixing ring (31).
5. The ALC partition wall panel cutting equipment according to claim 4, characterized in that, The top of the movable frame (1) is provided with a slide rail (15), which is arranged along the traveling direction of the movable frame (1). A slide table (16) is slidably mounted on the top of the slide rail (15). The slide table (16) is located directly below the lifting plate (41). The lifting element (44) is located between the slide table (16) and the lifting plate (41). The guide groove (43) is fixed on both sides of the lifting plate (41). A fixing block (161) is provided at the bottom of the slide table (16). A screw hole is opened in the fixing block (161). A screw rod (17) is rotatably provided on the movable frame (1). One end of the screw rod (17) is rotatably connected to the movable frame (1), and the other end passes through the screw hole and is screwed into the screw hole. A handle (18) is provided at the end of the screw rod (17) away from the fixing block (161).
6. The ALC partition wall panel cutting equipment according to claim 1 or 2, characterized in that, Multiple positioning components (5) are provided on both sides of the bottom of the movable frame (1). The positioning component (5) includes a positioning rod (51) and a pulley (52). One end of the positioning rod (51) is fixedly connected to the side of the movable frame (1), and the other end extends toward the inside of the movable frame (1). The pulley (52) is installed at the end of the positioning rod (51) and is used to make rolling contact with the side of the partition wall (7).
7. The ALC partition wall panel cutting equipment according to claim 6, characterized in that, The length of the positioning rod (51) is adjustable.
8. The ALC partition wall panel cutting equipment according to claim 1 or 2, characterized in that, A slide (6) is fixedly installed inside the movable frame (1) at the top position corresponding to the partition wall (7). The bottom of the slide (6) is equipped with multiple rollers (62). The rollers (62) are used to roll in contact with the top surface of the partition wall (7) to achieve stable support and movement of the equipment on the top of the partition wall (7).
9. The ALC partition wall panel cutting equipment according to claim 8, characterized in that, The carriage (6) includes two parallel support rods (61). The support rods (61) are fixed in the moving frame (1) along the moving direction of the moving frame (1). Each support rod (61) is made to give way to the cutting component (2) in the longitudinal cutting posture. The rollers (62) are uniformly fixedly assembled at the bottom of the support rod (61), and the support rod (61) is inclined upward at one end corresponding to the entrance of the moving frame (1) to form a guide slope, which is used to guide the partition wall panel (7) to smoothly enter the entrance of the moving frame (1).
10. The ALC partition wall panel cutting equipment according to claim 1 or 2, characterized in that, The movable frame (1) is covered with a dust cover (13). The dust cover (13) has a reserved hole at the position of the corresponding lifting component (4). The dust cover (13) is provided with a dustproof cloth at the position of the inlet and outlet of the movable frame (1) to suppress the spread of dust during cutting.