A tile cutting apparatus for a hip roof tile
By introducing a dust cover into the tile cutting equipment for sloping roofs, impurities during the cutting process are isolated, solving the problems of environmental pollution and safety hazards associated with existing equipment, and achieving higher construction safety and environmental cleanliness.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- 四川省建筑机械化工程有限公司
- Filing Date
- 2025-07-30
- Publication Date
- 2026-07-14
AI Technical Summary
Existing cutting equipment generates impurities during the cutting process, polluting the environment and posing safety hazards.
A tile cutting device for sloping roof tiles was designed, comprising a workbench, a cutting module, a conveying module, and a dust cover. The dust cover isolates impurities generated during the cutting process, providing a closed processing space to prevent impurities from spilling out.
It effectively prevents small-diameter impurities from polluting the environment and large-diameter impurities from harming personnel during the cutting process, thus improving construction safety and environmental cleanliness.
Smart Images

Figure CN224489599U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of sloping roof tile technology, specifically to a tile cutting device for sloping roof tiles. Background Technology
[0002] Roof tiles are the paving components for the top of traditional tiled houses, mainly used for waterproofing and stabilizing the roof structure. Roof tiling is a crucial step in ensuring the roof's waterproofing, aesthetics, and durability, requiring strict adherence to construction specifications and attention to detail.
[0003] When tiling a sloping roof, standardized tiles are generally selected as the laying components to improve the economy of construction. However, non-standard tiles may also be used in engineering practice. In this case, non-standard tiles can be obtained by cutting standard tiles using cutting equipment.
[0004] Existing cutting equipment has the following drawbacks: it generates debris, dust and other impurities during the cutting process, which pollute the surrounding environment and require secondary cleaning, resulting in rework; if large-diameter debris such as small pieces is generated during the cutting process, it may injure nearby personnel, posing a potential safety hazard. Utility Model Content
[0005] The technical problem to be solved by this utility model is that existing cutting equipment generates impurities during operation. The purpose is to provide a tile cutting device for sloping roof tiles to solve the above-mentioned problem.
[0006] This utility model is achieved through the following technical solution:
[0007] A tile cutting device for sloping roof tiles includes a workbench, a cutting module, a conveying module, and a dust cover;
[0008] The cutting module is set on the worktable and used to cut the tiles; the conveying module is set on the worktable and used to convey the tiles.
[0009] A dust cover is installed on the workbench and covers the cutting module and the conveying module. Both ends of the conveying module extend outside the dust cover.
[0010] Accordingly, the two ends of the conveying module are used as the feeding end and the discharging end, respectively; the dust cover is equipped with a feeding door near the feeding end and a discharging door near the discharging end.
[0011] In one possible design, the dust cover has a through hole in the part facing the cutting module, and a removable transparent observation plate is provided in the through hole;
[0012] Accordingly, when a transparent observation plate is provided on the through hole, the through hole is used as an observation hole; when the transparent observation plate is removed from the through hole, the through hole is used as a maintenance hole.
[0013] In one possible design, the conveying module includes a guide rail and a conveyor seat, with the guide rail positioned along the worktable and the conveyor seat slidably mounted on the guide rail.
[0014] In one possible design, the workbench is provided with a chute, and a conveyor seat passes through the chute. The lower part of the conveyor seat is located below the workbench and is used to connect the guide rails. The upper part of the conveyor seat extends through the chute to the top of the workbench and is used to place the tiles. Accordingly, there are two guide rails, which are fixed to the bottom surface of the workbench and located on both sides of the chute.
[0015] In one possible design, the conveyor base includes a base plate, a support platform, and a connecting plate;
[0016] The substrate is inserted into the groove; two supports are provided and fixed at intervals on the top surface of the substrate. Correspondingly, the top surfaces of the two supports form a support surface adapted to the tile, and a cutting groove is formed between the two supports.
[0017] The base plate is connected to the connecting plate on the side below the slide groove. Correspondingly, there are two connecting plates located on both sides of the base plate. The connecting plates are used to connect the guide rail.
[0018] In one possible design, the feed gate and the discharge gate are each equipped with a control module for controlling their opening and closing.
[0019] In one possible design, the control module includes a control board, a reset elastic element, and a control lever;
[0020] The control panel is slidably mounted on the worktable, and correspondingly, the worktable is provided with a matching control groove; the upper end of the control panel is constructed as an additional support surface adapted to the tile.
[0021] The reset elastic element is connected to the control board and is used for resetting the control board;
[0022] The control lever is rotatably mounted on the worktable, with one end of the control lever facing the feed gate and the other end passing through the control panel;
[0023] The control panel is provided with a drive groove extending along its lifting direction, and the drive groove is connected to the control rod by a threaded or helical structure.
[0024] Accordingly, when the control plate is pressed and slides, the control plate drives the control rod to move through the drive groove to open the feed door; when the control plate is reset by the reset elastic element, the control plate drives the control rod to reset through the drive groove to close the feed door.
[0025] Accordingly, the feed gate and discharge gate are equipped with a driver for driving the gate panel to rotate and a sensor for detecting the position of the control lever, with the driver electrically connected to the sensor.
[0026] In one possible design, the control module at the discharge gate has an inclined surface on the control panel that grips upwards from the bottom in the direction from the feeding end to the discharge end.
[0027] In one possible design, the reset elastic element includes a sleeve and a spring;
[0028] The upper end of the sleeve is open and connected to the bottom surface of the workbench, while the lower end of the sleeve is closed. The closed end of the sleeve is equipped with a control handle and a piston plate. The control plate passes through the sleeve and is connected to the piston plate. The piston plate is slidably disposed in the sleeve.
[0029] The spring is located in the sleeve, with its two ends abutting against the bottom surface of the control panel and the piston plate, respectively.
[0030] Correspondingly, a limit groove is provided on the workbench, and a limit block is provided on the outer wall of the control panel, which is inserted into the limit groove.
[0031] In one possible design, when the conveyor seat is located at the feed end, along the conveying direction of the conveying module, the reset elastic element of the control module is located upstream of the connecting plate of the conveyor seat, so that the position of the reset elastic element is offset from that of the connecting plate.
[0032] Compared with the prior art, this utility model has the following advantages and beneficial effects:
[0033] The dust cover provides internal and external isolation, creating a relatively enclosed and independent processing space for the cutting module. Impurities generated during cutting are blocked by the dust cover, preventing them from moving out and affecting the outside environment. Small-diameter impurities generated during cutting will not affect or pollute the surrounding environment, avoiding environmental pollution caused by cutting operations, resulting in a better working environment and eliminating the need for subsequent cleanup, thus reducing workload. For large-diameter impurities generated during cutting operations, there is no need to worry about flying debris injuring nearby personnel, improving the safety of the cutting operation. Attached Figure Description
[0034] The accompanying drawings, which are included to provide a further understanding of the embodiments of the present invention and form part of this application, do not constitute a limitation thereof. In the drawings:
[0035] Figure 1 This is a schematic diagram of a tile cutting device for sloping roofs.
[0036] Figure 2 This is a schematic diagram showing the structure at the feed gate where the control module is pressed down by the tile.
[0037] Figure 3 This is a schematic diagram of the conveyor seat.
[0038] Figure 4 This is a schematic diagram of the structure at the feed gate, where the control module does not have tiles placed on it.
[0039] The attached diagram shows the markings and corresponding component names:
[0040] 1. Workbench; 2. Cutting module; 3. Conveying module; 301. Guide rail; 302. Conveying seat; 303. Base plate; 304. Support platform; 305. Connecting plate; 4. Dust cover; 401. Feed gate; 402. Discharge gate; 403. Transparent observation plate; 5. Control module; 501. Control board; 502. Reset elastic element; 503. Control rod; 504. Drive groove; 505. Sleeve; 506. Spring; 507. Control handle; 508. Piston plate; 509. Limit block. Detailed Implementation
[0041] To make the objectives, technical solutions, and advantages of this utility model clearer, the present utility model will be further described in detail below with reference to the embodiments and accompanying drawings. The illustrative embodiments and descriptions of this utility model are only used to explain this utility model and are not intended to limit this utility model.
[0042] Example:
[0043] like Figures 1-4 As shown, a tile cutting device for sloping roof tiles includes a workbench 1, a cutting module 2, a conveying module 3, and a dust cover 4;
[0044] Cutting module 2 is installed on workbench 1 and used to cut tiles; conveying module 3 is installed on workbench 1 and used to convey tiles.
[0045] Dust cover 4 is placed on the workbench 1 and covers the cutting module 2 and the conveying module 3. Both ends of the conveying module 3 extend outside the dust cover 4.
[0046] Accordingly, the two ends of the conveying module 3 are used as the feeding end and the discharging end, respectively; the dust cover 4 is provided with a feeding door 401 near the feeding end and a discharging door 402 near the discharging end.
[0047] Obviously, impurities generated during the tile cutting process, whether small dust particles or large-diameter fragments, are unavoidable. To address this, the tile cutting equipment for sloping roofs utilizes a dust cover 4 to isolate the impurities from their surroundings, providing a relatively enclosed and independent processing space for the cutting module 2. The dust cover 4 prevents the impurities generated during the cutting operation from moving outwards and affecting the outside environment.
[0048] Therefore, small-diameter impurities generated during cutting will not affect or pollute the surrounding environment, avoiding environmental pollution caused by cutting operations, resulting in a better construction environment and eliminating the need for subsequent cleanup, thus reducing labor. For large-diameter impurities generated during cutting operations, there is no need to worry about flying debris injuring nearby personnel, making the cutting operation safer.
[0049] Specifically, for the tile cutting equipment for sloping roofs, the workbench 1 can be equipped with sliding wheels to facilitate the movement of the equipment by workers, making it easy to transfer to a suitable location. The cutting module 2 can be any suitable existing model, offering a wide range of choices; the dust cover 4 also covers the cutting module 2, effectively preventing workers from being injured by it, thus improving construction safety. The conveying module 3 is used to transport the tiles, offering a higher degree of automation and keeping workers away from the cutting module 2, further enhancing safety.
[0050] During operation, workers place tiles at the feed end, and the conveying module 3 transports the tiles to the cutting module 2. The cutting module 2 then starts and cuts the tiles. The conveying module 3 transports the cut tiles to the discharge end, where workers can retrieve them. After the cutting operation is completed, workers clean all impurities from the tile cutting equipment used for sloping roofs.
[0051] As is easily understood, the roof tile cutting equipment also includes a control module 5. The control module 5 is used to control the operation of the cutting module 2 and the conveying module 3, thereby controlling the position of the tile relative to the cutting module 2 to ensure that the required non-standard tile is obtained after cutting. Optionally, any suitable existing equipment can be used as the control module 5.
[0052] In one possible implementation, the dust cover 4 is provided with a through hole on the part of the cutting module 2, and a removable transparent observation plate 403 is provided on the through hole;
[0053] Accordingly, when a transparent observation plate 403 is provided on the through hole, the through hole is used as an observation hole; when the transparent observation plate 403 is removed from the through hole, the through hole is used as a maintenance hole.
[0054] Based on the above design, the roof tile cutting equipment has a certain degree of automation, reducing the workload of workers, ensuring that workers are kept away from the cutting module 2, and improving construction safety. The transparent observation panel 403 facilitates workers' monitoring of the equipment's operation, allowing for timely adjustments and maintenance.
[0055] Furthermore, the transparent observation panel 403 is connected to the dust cover 4 by any suitable detachable connection method. When maintenance is required, the transparent observation panel 403 can be removed to connect the inside and outside, thereby enabling maintenance work without disassembling the dust cover 4, making the operation more convenient.
[0056] In one possible implementation, the conveying module 3 includes a guide rail 301 and a conveying seat 302. The guide rail 301 is arranged along the worktable 1, and the conveying seat 302 is slidably arranged on the guide rail 301.
[0057] Based on the above design, the guide rail 301 guides the movement direction of the conveyor seat 302, ensuring that the conveyor seat 302 conveys tiles along the designed direction. The guide rail 301 is connected to the conveyor seat 302 via any suitable slider, thereby driving the conveyor seat 302 to slide back and forth along the guide rail 301, achieving batch processing. The conveyor seat 302 can be constructed in any suitable shape to adapt to different construction requirements.
[0058] After the cutting module 2 finishes its operation, impurities are generated. Although the dust cover 4 controls the range of influence of these impurities, they can still disperse to any suitable location within the dust cover 4. The conveying module 3 is also affected by these impurities, especially the slider and guide rail 301. Therefore, the structure of the conveying module 3 is improved, specifically as follows: Figure 2 and Figure 4 As shown, the workbench 1 is provided with a slide groove, and the conveyor seat 302 passes through the slide groove. The lower part of the conveyor seat 302 is located below the workbench 1 and is used to connect the guide rail 301. The upper part of the conveyor seat 302 extends through the slide groove to the top of the workbench 1 and is used to place the tiles. Correspondingly, there are two guide rails 301. The two guide rails 301 are fixed on the bottom surface of the workbench 1 and are located on both sides of the slide groove.
[0059] Based on the above design scheme, the guide rail 301 is set on the bottom surface of the worktable 1 and is isolated by the worktable 1 to avoid the guide rail 301 and the slider from directly contacting impurities, thereby reducing the wear of impurities on the guide rail 301 and achieving the purpose of protecting the guide rail 301.
[0060] Accordingly, the structure of the conveyor 302 has been improved, specifically: as follows: Figure 3 As shown, the conveyor base 302 includes a base plate 303, a support platform 304, and a connecting plate 305;
[0061] The substrate 303 is inserted into the groove; two support platforms 304 are provided and fixed at intervals on the top surface of the substrate 303. Correspondingly, the top surfaces of the two support platforms 304 form a support surface adapted to the tile, and a cutting groove is formed between the two support platforms 304.
[0062] The substrate 303 is located on the side below the slide groove and is connected to the connecting plate 305. Accordingly, there are two connecting plates 305, which are located on both sides of the substrate 303 respectively. The connecting plates 305 are used to connect the guide rail 301.
[0063] Based on the above design, the height of the base plate 303 is greater than the thickness of the workbench 1, ensuring that the upper and lower ends of the conveyor seat 302 protrude from the workbench 1 respectively. The support platform 304 is used to place the tiles, and correspondingly, the top surface of the support platform 304 is designed to support the tiles, ensuring that the tiles remain relatively stable during transportation and cutting. Two support platforms 304 are provided and spaced apart to form a cutting groove, ensuring that the conveyor seat 302 is not damaged during the cutting operation. The connecting plate 305 is used to increase the width of the conveyor seat 302, thereby connecting it to the guide rail 301, allowing the conveyor seat 302 to slide back and forth along the groove.
[0064] It is worth noting that the support platform 304 is preferably connected to the base plate 303 by any suitable detachable connection method, so as to facilitate the replacement of the support platform 304 with a suitable one according to the type and shape of the tile, thereby improving the compatibility between the conveyor seat 302 and the tile. Accordingly, the support platform 304 is provided in several specifications for workers to choose from.
[0065] For the tile cutting equipment used for sloping roof tiles, the dust cover 4 controls the range of influence of impurities. However, during the tile cutting operation, in order not to affect the entry and exit of tiles, a feed door 401 and a discharge door 402 are provided on the dust cover 4. In other words, the corresponding door should be open when tiles are entering or exiting, and should remain closed at other times.
[0066] Preferably, the door panel adopts a passive structure, meaning that the door panel rotates and opens by moving the tiles, and the door panel returns to its original position by gravity or other forces after the tiles are removed. This achieves door panel opening and closing control while reducing energy consumption. However, the door panel may also open under other forces, such as wind, potentially causing impurities to spill out.
[0067] In one possible implementation, control modules 5 are provided at the feed door 401 and the discharge door 402 to control their opening and closing. Based on the above design, the control modules 5 are used to control the opening and closing of the feed door 401 to avoid accidental disturbance to the door panel and ensure that impurities do not overflow into the dust cover 4.
[0068] Specifically, such as Figure 2 and Figure 4 As shown, the control module 5 includes a control board 501, a reset elastic element 502, and a control lever 503;
[0069] The control panel 501 is slidably mounted on the workbench 1, and correspondingly, the workbench 1 is provided with a matching control groove; the upper end of the control panel 501 is constructed as an additional support surface adapted to the tile.
[0070] The reset elastic element 502 is connected to the control board 501 and is used to reset the control board 501;
[0071] The control lever 503 is rotatably mounted on the workbench 1, with one end of the control lever 503 facing the feed gate 401 and the other end of the control lever 503 passing through the control plate 501;
[0072] The control panel 501 is provided with a drive groove 504 extending along its lifting direction. The drive groove 504 is connected to the control rod 503 by a threaded or helical structure.
[0073] Accordingly, when the control plate 501 is pressed and slids, the control plate 501 drives the control rod 503 to move through the drive groove 504, so as to open the feed door 401; when the control plate 501 is reset through the reset elastic element 502, the control plate 501 drives the control rod 503 to reset through the drive groove 504, so as to close the feed door 401.
[0074] Accordingly, the feed gate 401 and the discharge gate 402 are equipped with a driver for driving the gate panel to rotate and a sensor for detecting the position of the control lever 503, with the driver electrically connected to the sensor.
[0075] Based on the above design scheme, and considering the movement of the tiles under the conveying module 3, the rotation time of the gate is controlled by monitoring the position of the tiles. Taking the feeding gate 401 as an example, when the tile is placed at the feeding end, both sides of the tile are located outside the conveying module 3 and press against the control plate 501. The weight of the tile causes the control plate 501 to move downwards. The downward movement of the control plate 501 drives the control rod 503 to move through the drive groove 504. After the control rod 503 moves into position, the sensor detects the position signal of the control rod 503, indicating that a tile is about to pass through the feeding gate 401, and the driver can then be ready to start.
[0076] By setting the moving speed of the conveying module 3, the time it takes for the tile to reach the feed gate 401 is controlled. The driver sets the start time according to this time, thereby opening the feed gate 401 in a timely manner and ensuring that there is no collision between the tile and the feed gate 401, avoiding tile displacement, ensuring cutting accuracy, and reducing damage to the feed gate 401.
[0077] After the conveying module 3 moves, the control board 501 is reset by the reset elastic element 502, preparing for the cutting operation of the next tile.
[0078] In one possible implementation, in the control module 5 at the discharge gate 402, the control board 501 is provided with an inclined surface that grips from bottom to top in the direction from the feeding end to the discharge end.
[0079] Based on the above design scheme, the working principle of the control module 5 at the discharge gate 402 is the same as that at the feed gate 401. The difference between the two is that at the feed gate 401, the tiles can be placed on the conveying module 3 from above, while at the discharge gate 402, the tiles move towards the control module 5 along with the conveying module 3. Therefore, an inclined surface is set on the control plate 501 at the discharge gate 402 to facilitate the contact of the tiles and their movement along the control plate 501, thereby realizing the descent of the control plate 501 and also helping to reduce the collision between the tiles and the control plate 501.
[0080] In one possible implementation, the reset elastic element 502 includes a sleeve 505 and a spring 506;
[0081] The upper end of the sleeve 505 is open and connected to the bottom surface of the workbench 1. The lower end of the sleeve 505 is closed. The closed end of the sleeve 505 is provided with a control handle 507 and a piston plate 508. The control plate 501 passes through the sleeve 505 and is connected to the piston plate 508. The piston plate 508 is slidably disposed in the sleeve 505.
[0082] Spring 506 is located in sleeve 505, and the two ends of spring 506 abut against the bottom surface of control plate 501 and piston plate 508 respectively.
[0083] Correspondingly, the workbench 1 is provided with a limiting groove, and the outer wall of the control board 501 is provided with a limiting block 509 that is inserted into the limiting groove.
[0084] Based on the above design, the tiles come in various types and models, each with different weights. Therefore, the distance between the piston plate 508 and the upper end of the sleeve 505 is controlled by the control handle 507, thereby controlling the deformation of the spring 506. A limiting block 509, which abuts against the wall of the limiting groove on the control plate 501, ensures that the control plate 501 remains relatively fixed. Thus, when the control handle 507 is adjusted, the control module 5 only controls the movement of the handle 507 and the spring 506.
[0085] When the control plate 501 is pressed down, the resistance of the tile to overcome the elastic force varies due to the different initial deformation of the spring 506, thus controlling the speed at which the tile descends. Therefore, the operator only needs to rotate the control handle 507 to move the piston plate 508, eliminating the need for frequent disassembly and replacement of the spring 506, making it more convenient to use.
[0086] In one possible implementation, when the conveyor seat 302 is located at the feed end, along the conveying direction of the conveying module 3, the reset elastic element 502 of the control module 5 is located upstream of the connecting plate 305 of the conveyor seat 302, so that the reset elastic element 502 is misaligned with the connecting plate 305. Based on the above design scheme, obstruction between components is avoided, ensuring that the tile cutting equipment for sloping roof tiles can work smoothly.
[0087] The specific embodiments described above further illustrate the purpose, technical solution, and beneficial effects of this utility model. It should be understood that the above description is only a specific embodiment of this utility model and is not intended to limit the scope of protection of this utility model. Any modifications, equivalent substitutions, improvements, etc., made within the spirit and principles of this utility model should be included within the scope of protection of this utility model.
Claims
1. A tile cutting device for sloping roof tiles, characterized in that, Includes a workbench (1), a cutting module (2), a conveying module (3), and a dust cover (4); The cutting module (2) is set on the workbench (1) and used to cut the tiles; the conveying module (3) is set on the workbench (1) and used to convey the tiles; The dust cover (4) is placed on the workbench (1) and covers the cutting module (2) and the conveying module (3). The two ends of the conveying module (3) extend to the outside of the dust cover (4); Accordingly, the two ends of the conveying module (3) are used as the feeding end and the discharging end, respectively; the dust cover (4) is provided with a feeding door (401) near the feeding end and a discharging door (402) near the discharging end.
2. The tile cutting equipment for sloping roof tiles according to claim 1, characterized in that, The dust cover (4) has a through hole aligned with the cutting module (2), and a detachable transparent observation plate (403) is provided on the through hole. Accordingly, when a transparent observation plate (403) is provided on the through hole, the through hole is used as an observation hole; when the transparent observation plate (403) is removed from the through hole, the through hole is used as a maintenance hole.
3. The tile cutting equipment for sloping roof tiles according to claim 1, characterized in that, The conveying module (3) includes a guide rail (301) and a conveying seat (302). The guide rail (301) is set along the workbench (1), and the conveying seat (302) is slidably set on the guide rail (301).
4. The tile cutting equipment for sloping roof tiles according to claim 3, characterized in that, The workbench (1) is provided with a chute, and the conveyor seat (302) passes through the chute. The lower part of the conveyor seat (302) is located below the workbench (1) and is used to connect the guide rail (301). The upper part of the conveyor seat (302) extends through the chute to the top of the workbench (1) and is used to place the tiles. Correspondingly, there are two guide rails (301). The two guide rails (301) are fixed on the bottom surface of the workbench (1) and are located on both sides of the chute.
5. The tile cutting equipment for sloping roof tiles according to claim 4, characterized in that, The conveyor base (302) includes a base plate (303), a support platform (304), and a connecting plate (305); The substrate (303) is inserted into the groove; two support platforms (304) are provided and fixed at intervals on the top surface of the substrate (303). Correspondingly, the top surfaces of the two support platforms (304) form a support surface adapted to the tile, and a cutting groove is formed between the two support platforms (304). The substrate (303) is connected to the connecting plate (305) on the side below the slide groove. Correspondingly, there are two connecting plates (305) located on both sides of the substrate (303). The connecting plates (305) are used to connect the guide rail (301).
6. The tile cutting device for sloping roof tiles according to any one of claims 1-5, characterized in that, The feed gate (401) and the discharge gate (402) are respectively equipped with control modules (5) for controlling their opening and closing.
7. The tile cutting equipment for sloping roof tiles according to claim 6, characterized in that, The control module (5) includes a control board (501), a reset elastic element (502), and a control lever (503); The control panel (501) is slidably mounted on the workbench (1), and correspondingly, the workbench (1) is provided with a suitable control groove; the upper end of the control panel (501) is constructed to be an additional support surface adapted to the tile. The reset elastic element (502) is connected to the control board (501) and is used for resetting the control board (501); The control lever (503) is rotatably mounted on the workbench (1), with one end of the control lever (503) facing the feed gate (401) and the other end of the control lever (503) passing through the control plate (501). The control panel (501) is provided with a drive groove (504) extending along its lifting direction, and the drive groove (504) is connected to the control rod (503) by a threaded or helical structure. Accordingly, when the control plate (501) is pressed and slids, the control plate (501) drives the control rod (503) to move through the drive groove (504) so that the feed door (401) opens; when the control plate (501) is reset through the reset elastic element (502), the control plate (501) drives the control rod (503) to reset through the drive groove (504) so that the feed door (401) closes. Accordingly, the feed gate (401) and the discharge gate (402) are provided with a driver for driving the gate panel to rotate and a sensor for detecting the position of the control lever (503), with the driver electrically connected to the sensor.
8. The tile cutting equipment for sloping roof tiles according to claim 7, characterized in that, In the control module (5) at the discharge gate (402), from the feeding end to the discharge end, the control board (501) is provided with an inclined surface that grips from bottom to top.
9. The tile cutting equipment for sloping roof tiles according to claim 8, characterized in that, The reset elastic element (502) includes a sleeve (505) and a spring (506); The upper end of the sleeve (505) is open and connected to the bottom surface of the workbench (1). The lower end of the sleeve (505) is closed. The closed end of the sleeve (505) is provided with a control handle (507) and a piston plate (508). The control plate (501) is inserted through the sleeve (505) and connected to the piston plate (508). The piston plate (508) is slidably disposed in the sleeve (505). The spring (506) is located in the sleeve (505), and the two ends of the spring (506) abut against the bottom surface of the control plate (501) and the piston plate (508) respectively. Accordingly, the workbench (1) is provided with a limiting groove, and the outer wall of the control board (501) is provided with a limiting block (509) inserted into the limiting groove.
10. The tile cutting equipment for sloping roof tiles according to claim 9, characterized in that, When the conveyor seat (302) is located at the feed end, along the conveying direction of the conveying module (3), the reset elastic element (502) of the control module (5) is located upstream of the connecting plate (305) of the conveyor seat (302) so that the reset elastic element (502) is offset from the connecting plate (305).