An artificial stone panel filling apparatus
By pre-mixing minerals and adhesives in a mixing pipe within the artificial stone slab filling equipment, and achieving uniform filling through a moving structure and control system, the problem of uneven filling is solved, filling efficiency and texture effect are improved, and production costs are reduced.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Patents(China)
- Current Assignee / Owner
- VEEGOO TECH CO LTD
- Filing Date
- 2023-11-09
- Publication Date
- 2026-07-14
AI Technical Summary
The existing filling device has uneven filling, which makes it easy to have insufficient or excessive material during the filling process, affecting the appearance and texture of the artificial stone slab.
The system employs a mineral supply device, an adhesive supply device, and a mixing pipe to premix the minerals and adhesives within the mixing pipe, forming an adhesive mixture. This mixture is then filled along a pre-set texture trajectory on the slab using a moving structure and control system, while a scraping device ensures uniform filling.
It solves the problem of uneven filling, improves filling efficiency and texture richness, makes artificial stone slabs more beautiful and textures more natural, and reduces equipment complexity and production costs.
Smart Images

Figure CN117341044B_ABST
Abstract
Description
Technical Field
[0001] This invention relates to the field of artificial stone manufacturing equipment, and more particularly to a filling device for artificial stone slabs. Background Technology
[0002] In existing technologies, there are two main methods for creating textures in artificial stone slabs: one is by directly spraying color powder, and the other is by directly spraying color paste, thus achieving different texture effects. However, the textures produced by these two methods lack volume; the colorant can only form very narrow colored lines on the surface, resulting in insufficient filling of fine lines, stiff and unnatural textures, and difficulty in creating gradient effects through adjustment. Moreover, the slabs only have relatively simple fine lines, failing to achieve a greater sense of depth and layering, and thus unable to meet the needs of slabs with a wider range of texture effects.
[0003] Currently, some manufacturers pre-define texture grooves when pouring the mineral mixture into the board mold frame during board preparation. They then use a filling device to fill the texture grooves with the pre-mixed, slightly moist mineral mixture to create the texture. However, this method results in uneven filling, and the filling process is prone to insufficient or excessive material, affecting the final appearance of the product. Furthermore, the pre-mixed, slightly moist mineral mixture requires additional mixing equipment, has poor fluidity, and necessitates a material feeding device to convey the material onto the surface. This makes the process more complex and increases the cost of equipment and textured board production. Summary of the Invention
[0004] The purpose of this invention is to provide a filling device for artificial stone slabs to solve the problem that the existing filling devices do not fill the material evenly, which leads to insufficient or excessive material during the filling process and ultimately affects the appearance of the product.
[0005] To achieve this objective, the present invention adopts the following technical solution:
[0006] This invention provides a filling device for artificial stone slabs, including a moving structure, a filling mechanism, a support platform, and a control system;
[0007] The filling mechanism includes a fixed frame, a mineral supply device, an adhesive supply device, and a mixing pipe; the mineral supply device, the adhesive supply device, and the mixing pipe are respectively disposed on the fixed frame; the upper end of the mixing pipe is provided with a feed inlet, and the lower end of the mixing pipe is provided with a discharge outlet; the discharge outlet of the mineral supply device and the discharge outlet of the adhesive supply device are respectively connected to the feed inlet of the mixing pipe.
[0008] The movable structure is mounted on top of the support platform, and the fixed frame is connected to the drive end of the movable structure. The support platform is used to support the artificial stone slab blank. The control system is connected to the movable structure and the filling mechanism respectively, and is used to control the movable structure and the filling mechanism, so that the movable structure drives the filling mechanism to move along the preset texture trajectory of the slab blank on the support platform, and makes the filling mechanism fill the slab blank on the support platform with a mixture of minerals and adhesives.
[0009] The filling mechanism further includes a scraping device, which includes a scraping unit and a scraping drive. The scraping drive is mounted on a fixed frame, one end of the scraping unit is connected to the drive end of the scraping drive, and the other end of the scraping unit extends into the mixing pipe.
[0010] In the artificial stone slab filling equipment, the scraping unit includes a connecting rod and a scraping component. One end of the connecting rod is connected to the driving end of the scraping drive component, and the other end of the connecting rod is inserted into the mixing pipe. The other end of the connecting rod is provided with a scraping component that is adapted to the inner cavity of the mixing pipe.
[0011] In the artificial stone slab filling equipment, the adhesive supply device includes an adhesive reservoir and an injector, which are connected by a pipeline, and the injection port of the injector is connected to the feed port of the mixing pipeline.
[0012] In the artificial stone slab filling equipment, the mineral supply device includes a mineral storage device, a mineral supply drive component, and a receiving hopper;
[0013] The mineral storage device includes a hopper, a supply channel, and a discharge channel. The hopper is used to store minerals. One end of the supply channel is connected to the discharge channel, and the mineral supply drive is located at the other end of the supply channel. A screw is provided inside the supply channel, and the drive end of the mineral supply drive is connected to the screw and extends into the supply channel. The receiving hopper is located below the discharge channel, and the discharge port of the receiving hopper is connected to the inlet of the mixing pipe.
[0014] In the artificial stone slab filling equipment, the mineral supply device includes a vibrator, which is installed in the receiving hopper.
[0015] The artificial stone slab filling equipment also includes a control system, which is located on one side of the support platform. The control system is electrically connected to the moving structure and the filling mechanism, and is used to control the moving structure and the filling mechanism so that the moving structure drives the filling mechanism to move along the preset texture trajectory of the slab on the support platform, and fills the slab on the support platform with a mixture of minerals and adhesives.
[0016] In the artificial stone slab filling equipment, the moving structure includes a transverse moving component and a longitudinal moving component. The transverse moving component includes a transverse moving bracket, a transverse driving device, and a moving crossbeam. The transverse moving bracket is disposed on both sides of the support platform, and the transverse moving bracket is provided with movable guide rails along the conveying direction of the support platform. The two ends of the moving crossbeam are slidably assembled with the movable guide rails at corresponding positions. The transverse driving device is disposed at one end of the moving crossbeam, and the transverse driving device is used to drive the transverse moving bracket to move along the movable guide rails.
[0017] The longitudinal movement assembly includes a longitudinal drive device, and the fixed frame is slidably mounted on the moving crossbeam; the longitudinal drive device is disposed on the fixed frame, and the drive end of the longitudinal drive device passes through the fixed frame and is drivenly connected to the moving crossbeam, and the longitudinal drive device is used to drive the fixed frame to move along the moving crossbeam.
[0018] In the artificial stone slab filling equipment, the support platform includes a frame and a conveyor belt. The conveyor belt is disposed on the frame, and the movable structure is assembled on the frame and located above the conveyor belt.
[0019] One of the technical solutions in this invention can have the following beneficial effects:
[0020] The artificial stone slab filling equipment is equipped with a mineral supply device, an adhesive supply device, and a mixing pipe, allowing the minerals and adhesives to be pre-mixed in the mixing pipe to form an adhesive mixture. The adhesive mixture has good fluidity and can fill the textured grooves reserved in the slab, making the texture filling process more uniform and the filling effect better. It solves the problem of uneven filling in the prior art, which easily leads to insufficient or excessive material during the filling process, resulting in a more beautiful appearance and richer texture of the final artificial stone. Moreover, the minerals and adhesives do not need to be pre-mixed before being loaded into the filling device, which can achieve a mixing effect while filling, improving the filling efficiency. Attached Figure Description
[0021] Figure 1 This is a schematic diagram of the structure of one embodiment of the present invention;
[0022] Figure 2 This is a top view of one embodiment of the present invention;
[0023] Figure 3 yes Figure 2 A magnified view of a section at point A in the middle;
[0024] Figure 4 This is a schematic diagram of the packing mechanism in one embodiment of the present invention;
[0025] Figure 5 This is a front view of the packing mechanism in one embodiment of the present invention;
[0026] Figure 6 This is a schematic diagram of the adhesive supply device in one embodiment of the present invention;
[0027] Figure 7 This is a schematic diagram of the appearance of artificial stone slabs produced in the existing technology;
[0028] Figure 8 This is a schematic diagram of the appearance of an artificial stone slab produced according to one embodiment of the present invention;
[0029] In the attached diagram: 1. Moving structure; 2. Filling mechanism; 3. Support platform; 4. Control system.
[0030] 20. Fixture frame; 21. Mineral supply device; 22. Adhesive supply device; 23. Mixing pipe; 24. Scraping device; 31. Frame; 32. Conveyor belt;
[0031] Lateral moving support 111, lateral driving device 112, moving crossbeam 113; longitudinal driving device 121;
[0032] Fixed frame body 201, rotary table 202; mineral supply drive 211, receiving hopper 212, vibrator 213; adhesive storage tank 221, sprayer 222; scraping unit 241, scraping drive 242; rotary motor 251, transmission wheel 252, transmission belt 253;
[0033] 2101 hopper, 2102 supply channel, 2103 discharge channel, 2104 screw. Detailed Implementation
[0034] Embodiments of the present invention are described in detail below. Examples of these embodiments are shown in the accompanying drawings, wherein the same or similar reference numerals denote the same or similar elements or elements having the same or similar functions throughout. The embodiments described below with reference to the accompanying drawings are exemplary and are only used to explain the present invention, and should not be construed as limiting the present invention.
[0035] In the description of this invention, it should be understood that the terms "longitudinal," "lateral," "upper," "lower," "bottom," "inner," and "outer," etc., indicate the orientation or positional relationship based on the orientation or positional relationship shown in the accompanying drawings. They are used only for the convenience of describing this invention and for simplifying the description, and do not indicate or imply that the device or element referred to must have a specific orientation, or be constructed and operated in a specific orientation. Therefore, they should not be construed as limitations on this invention. Furthermore, features defined with "first" and "second" may explicitly or implicitly include one or more of these features, used to distinguish and describe features, without any order or emphasis.
[0036] In the description of this invention, it should be noted that, unless otherwise explicitly specified and limited, the terms "installation," "connection," and "linking" should be interpreted broadly. For example, they can refer to a fixed connection, a detachable connection, or an integral connection; they can refer to a mechanical connection or an electrical connection; they can refer to a direct connection or an indirect connection through an intermediate medium; and they can refer to the internal connection of two components. Those skilled in the art can understand the specific meaning of the above terms in this invention based on the specific circumstances.
[0037] Please refer to Figures 1-8 The present invention provides a filling device for artificial stone slabs, including a moving structure 1, a filling mechanism 2, a support platform 3 and a control system 4;
[0038] The filling mechanism 2 includes a fixed frame 20, a mineral supply device 21, an adhesive supply device 22, and a mixing pipe 23; the mineral supply device 21, the adhesive supply device 22, and the mixing pipe 23 are respectively disposed on the fixed frame 20; the upper end of the mixing pipe 23 is provided with a feed inlet, and the lower end of the mixing pipe 23 is provided with a discharge outlet; the discharge outlet of the mineral supply device 21 and the discharge outlet of the adhesive supply device 22 are respectively connected to the feed inlet of the mixing pipe 23;
[0039] The movable structure 1 is mounted on top of the support platform 3. The fixed frame 20 is connected to the drive end of the movable structure 1. The support platform 3 is used to support the artificial stone slab. The control system 4 is connected to the movable structure 1 and the filling mechanism 2 respectively. It is used to control the movable structure 1 and the filling mechanism 2, so that the movable structure 1 drives the filling mechanism 2 to move along the preset texture trajectory of the slab on the support platform 3, and fills the slab on the support platform 3 with a mixture of minerals and adhesives.
[0040] The filling mechanism 2 further includes a scraping device 24, which includes a scraping unit 241 and a scraping drive 242. The scraping drive 242 is mounted on the fixed frame 20. One end of the scraping unit 241 is connected to the drive end of the scraping drive 242, and the other end of the scraping unit 241 extends into the mixing pipe 23.
[0041] The artificial stone slab filling equipment is equipped with a mineral supply device 21, an adhesive supply device 22, and a mixing pipe 23, so that the minerals and adhesives are pre-mixed in the mixing pipe 23 to form an adhesive mixture. The adhesive mixture has good fluidity and can fill the texture grooves reserved in the slab blank, making the texture filling process more uniform and the filling effect better. It solves the problem of uneven filling in the prior art, which leads to insufficient or excessive material during the filling process, and makes the final artificial stone more beautiful in appearance and rich in texture. Moreover, the minerals and adhesives do not need to be pre-mixed before being loaded into the filling mechanism 2, which can achieve the effect of filling and mixing at the same time, improving the filling efficiency.
[0042] The support platform 3 supports the artificial stone slab and, in conjunction with the moving structure 1 and the filling mechanism 2, achieves automatic filling. The moving structure 1 drives the fixed frame 20 along the preset texture track of the slab, thereby moving the filling mechanism 2 so that the adhesive mixture flowing from the mixing pipe 23 fills the pre-reserved texture grooves in the slab. The control system 4 is connected to the moving structure 1 and the filling mechanism 2 via wiring, issuing commands to control the moving structure 1 to move along the preset texture track of the slab on the support platform 3, thereby moving the filling mechanism 2; simultaneously, it controls the filling mechanism 2 to fill the slab with adhesive mixture on the surface of the support 3. The artificial stone slab filling equipment, through the control system 4, controls the moving structure 1 and the filling mechanism 2, enabling them to cooperate with each other and fill textures according to production needs, thus producing artificial stone with different texture effects.
[0043] Specifically, the scraping unit 241 includes a connecting rod and a scraping component. One end of the connecting rod is connected to the driving end of the scraping drive 242, and the other end of the connecting rod is inserted into the mixing pipe 23. The other end of the connecting rod is provided with a scraping component that is adapted to the inner cavity of the mixing pipe 23.
[0044] The drive end of the scraper drive 242 drives the scraper unit 241 to reciprocate up and down inside the mixing pipe 23, thereby achieving the effect of scraping the wall and scraping off the adhesive mixture adhering to the inner wall of the mixing pipe 23. This allows the adhesive mixture to be quickly discharged from the mixing pipe 23, preventing the adhesive mixture from accumulating in the mixing pipe 23 and causing blockage. In a specific embodiment of the present invention, the scraper drive 242 is a pneumatic cylinder. The scraper can be a scraper rod or a scraper blade.
[0045] Specifically, the filling mechanism 2 further includes a rotating device, which includes a rotary motor 251, a transmission wheel 252, and a transmission belt 253; the fixed frame 20 includes a fixed frame body 201 and a rotating platform 202; the rotating platform 202 is rotatably mounted on the fixed frame body 201, and the fixed frame body 201 is connected to the drive end of the moving structure 1; the mineral supply device 21, the adhesive supply device 22, and the mixing pipe 23 are disposed on the rotating platform 202;
[0046] The transmission wheel 252 is disposed at the bottom of the rotary table 202; the rotary motor 251 is disposed on the fixed frame body 201, and the driving end of the rotary motor 251 passes through the fixed frame body 201; the transmission belt 253 is sleeved on the driving end of the rotary motor 251 and the outside of the transmission wheel 252.
[0047] With the above structure, the rotary motor 251 drives the rotary table 202 to rotate through the transmission belt 253, which enables the mineral supply device 21, the adhesive supply device 22 and the mixing pipe 23 to rotate. This allows the artificial stone slab filling equipment to rotate the mixing pipe 23 while discharging the adhesive mixture according to production needs. In conjunction with the moving structure 1, more textures can be produced.
[0048] Specifically, the adhesive supply device 22 includes an adhesive reservoir 221 and an injector 222, which are connected by a pipe. The nozzle of the injector 222 is connected to the inlet of the mixing pipe 23.
[0049] The adhesive reservoir 221 stores the adhesive, while the injector 222 provides the adhesive with spraying power, improving its flowability. The adhesive enters the mixing pipe 23 through the spraying power provided by the injector 222 and mixes with the minerals without the need for additional stirring equipment.
[0050] Specifically, the mineral supply device 21 includes a mineral storage device, a mineral supply drive 211, and a receiving hopper 212;
[0051] The mineral storage device includes a hopper 2101, a supply channel 2102, and a discharge channel 2103. The hopper 2101 is used to store minerals. One end of the supply channel 2102 is connected to the discharge channel 2103. The mineral supply drive 211 is disposed at the other end of the supply channel 2102. A screw 2104 is provided inside the supply channel 2102. The drive end of the mineral supply drive 211 is connected to the screw 2104 and extends into the supply channel 2102. The receiving hopper 212 is located below the discharge channel 2103, and the discharge port of the receiving hopper 212 is connected to the inlet of the mixing pipe 23.
[0052] The fixed frame 20 is equipped with a fixed rod, and the receiving hopper 212 is connected to the fixed frame 20 through the fixed rod, so that the receiving hopper 212 can be installed between the discharge channel 2103 and the inlet of the mixing pipe 23, so that the receiving hopper 212 can play the role of receiving minerals and guiding them, so as to transport the minerals from the discharge channel 2103 to the mixing pipe 23.
[0053] The hopper 2101 delivers minerals to the receiving hopper 28 via the mineral supply drive 211. The hopper 2101 is used to store minerals. The mineral supply drive 211 drives the screw 2104 to rotate. Since the screw has a threaded plate on its outer side, when the screw 2104 rotates, it can move the minerals towards the discharge channel 2103. When the minerals move to the inlet of the discharge channel 2103, they fall into the receiving hopper 28 through the discharge channel 2103, so that the minerals enter the mixing pipe 23 through the receiving hopper 28.
[0054] The receiving hopper 212 has the function of adjusting the weight of minerals entering the mixing pipe 23 per unit time. The receiving hopper 212 can make the minerals enter the mixing pipe 23 quantitatively and evenly. The flow rate of minerals can be adjusted by replacing the receiving hopper 212 with different outlet sizes.
[0055] Specifically, the mineral supply device 21 includes a vibrator 213, which is disposed on the outside of the receiving hopper 212.
[0056] With the above structure, vibration can be generated by the vibrator 213, allowing the minerals to enter the mixing pipe 23 more smoothly from the receiving hopper 212. In a specific embodiment of the present invention, the vibrator 213 is specifically a pneumatic vibrator.
[0057] Specifically, the moving structure 1 includes a lateral moving component and a longitudinal moving component. The lateral moving component includes a lateral moving bracket 111, a lateral driving device 112, and a moving crossbeam 113. The lateral moving bracket 111 is disposed on both sides of the support platform 3, and the lateral moving bracket 111 is provided with movable guide rails along the conveying direction of the support platform 3. The two ends of the moving crossbeam 113 are slidably assembled with the movable guide rails at corresponding positions. The lateral driving device 112 is disposed at one end of the moving crossbeam 113, and the lateral driving device 112 is used to drive the lateral moving bracket 111 to move along the movable guide rails.
[0058] The longitudinal movement assembly includes a longitudinal drive device 121, and the fixed frame 20 is slidably mounted on the moving crossbeam 113. The longitudinal drive device 121 is disposed on the fixed frame 20, and the drive end of the longitudinal drive device 121 passes through the fixed frame 20 and is drivenly connected to the moving crossbeam 113. The longitudinal drive device 121 is used to drive the fixed frame 20 to move along the moving crossbeam 113.
[0059] The transverse and longitudinal movement components can refer to the transverse movement mechanism and longitudinal movement structure of existing machine tools. The transverse drive device 112 drives the moving crossbeam 113 to move along the movable guide rail of the transverse movement support 111, thereby realizing the transverse movement of the moving crossbeam 113.
[0060] Specifically, the support platform 3 includes a frame 31 and a conveyor belt 32. The conveyor belt 32 is disposed on the frame 31, and the moving structure 1 is assembled on the frame 31 and located above the conveyor belt 32.
[0061] The conveyor belt 32 can refer to the existing conveyor belt structure, including a transmission belt, a drive device, a driven roller and at least one drive roller; the driven roller is located at one end of the frame 31, the drive roller is located at the other end of the frame 31, the transmission belt is sleeved on the outside of the driven roller and the drive roller, the drive device is located on one side of the drive roller and is drivenly connected to the drive roller.
[0062] The artificial stone slab filling equipment conveys the slab blanks via conveyor belt 32, while the frame 31 serves to support and connect the various components.
[0063] The technical principles of the present invention have been described above with reference to specific embodiments. These descriptions are merely for explaining the principles of the invention and should not be construed as limiting the scope of protection of the invention in any way. Based on this explanation, those skilled in the art can readily conceive of other specific embodiments of the invention without inventive effort, and these equivalent variations or substitutions are all included within the scope defined by the claims of this application.
Claims
1. A filling device for artificial stone slabs, characterized in that, It includes a moving structure (1), a filling mechanism (2), a support platform (3), and a control system (4); The filling mechanism (2) includes a fixed frame (20), a mineral supply device (21), an adhesive supply device (22), and a mixing pipe (23); the mineral supply device (21), the adhesive supply device (22), and the mixing pipe (23) are respectively disposed on the fixed frame (20); the upper end of the mixing pipe (23) is provided with a feed inlet, and the lower end of the mixing pipe (23) is provided with a discharge outlet; the discharge outlet of the mineral supply device (21) and the discharge outlet of the adhesive supply device (22) are respectively connected to the feed inlet of the mixing pipe (23); The movable structure (1) is mounted above the support platform (3), the fixed frame (20) is connected to the drive end of the movable structure (1), and the support platform (3) is used to support the artificial stone slab blank; the control system (4) is connected to the movable structure (1) and the filling mechanism (2) respectively, and is used to control the movable structure (1) and the filling mechanism (2), so that the movable structure (1) drives the filling mechanism (2) to move along the preset texture trajectory of the slab blank on the support platform (3), and makes the filling mechanism (2) fill the slab blank on the support platform (3) with a mixture of minerals and adhesives; The filling mechanism (2) further includes a scraping device (24), which includes a scraping unit (241) and a scraping drive (242). The scraping drive (242) is mounted on a fixed frame (20). One end of the scraping unit (241) is connected to the drive end of the scraping drive (242), and the other end of the scraping unit (241) extends into the mixing pipe (23).
2. The artificial stone slab filling equipment according to claim 1, characterized in that, The scraping unit (241) includes a connecting rod and a scraping component. One end of the connecting rod is connected to the driving end of the scraping drive (242), and the other end of the connecting rod is inserted into the mixing pipe (23). The other end of the connecting rod is provided with a scraping component that is adapted to the inner cavity of the mixing pipe (23).
3. The artificial stone slab filling equipment according to claim 1, characterized in that, The filling mechanism (2) further includes a rotating device, which includes a rotary motor (251), a transmission wheel (252), and a transmission belt (253); the fixed frame (20) includes a fixed frame body (201) and a rotating platform (202); the rotating platform (202) is rotatably mounted on the fixed frame body (201), and the fixed frame body (201) is connected to the drive end of the moving structure (1); the mineral supply device (21), the adhesive supply device (22), and the mixing pipe (23) are disposed on the rotating platform (202). The transmission wheel (252) is located at the bottom of the rotary table (202); the rotary motor (251) is located on the fixed frame body (201), and the drive end of the rotary motor (251) passes through the fixed frame body (201); the transmission belt (253) is sleeved on the drive end of the rotary motor (251) and the outside of the transmission wheel (252).
4. The artificial stone slab filling equipment according to claim 1, characterized in that, The adhesive supply device (22) includes an adhesive reservoir (221) and an injector (222), which are connected by a pipe. The nozzle of the injector (222) is connected to the inlet of the mixing pipe (23).
5. The artificial stone slab filling equipment according to claim 1, characterized in that, The mineral supply device (21) includes a mineral storage device, a mineral supply drive (211), and a receiving hopper (212). The mineral storage device includes a hopper (2101), a supply channel (2102), and a discharge channel (2103). The hopper (2101) is used to store minerals. One end of the supply channel (2102) is connected to the discharge channel (2103). The mineral supply drive (211) is located at the other end of the supply channel (2102). A screw (2104) is provided inside the supply channel (2102). The drive end of the mineral supply drive (211) is connected to the screw (2104), and the drive end of the mineral supply drive (211) extends into the supply channel (2102). The receiving hopper (212) is located below the discharge channel (2103), and the discharge port of the receiving hopper (212) is connected to the inlet of the mixing pipe (23).
6. The artificial stone slab filling equipment according to claim 5, characterized in that, The mineral supply device (21) includes a vibrator (213) disposed in the receiving hopper (212).
7. The artificial stone slab filling equipment according to claim 1, characterized in that, The moving structure (1) includes a lateral moving component and a longitudinal moving component. The lateral moving component includes a lateral moving bracket (111), a lateral driving device (112), and a moving crossbeam (113). The lateral moving bracket (111) is disposed on both sides of the support platform (3). The lateral moving bracket (111) is provided with a movable guide rail along the conveying direction of the support platform (3). The two ends of the moving crossbeam (113) are slidably assembled with the movable guide rails at corresponding positions. The lateral driving device (112) is disposed at one end of the moving crossbeam (113), and the lateral driving device (112) is used to drive the moving crossbeam (113) to move along the movable guide rail. The longitudinal moving assembly includes a longitudinal driving device (121), and the fixed frame (20) is slidably mounted on the moving crossbeam (113). The longitudinal driving device (121) is disposed on the fixed frame (20), and the driving end of the longitudinal driving device (121) passes through the fixed frame (20) and is drivenly connected to the moving crossbeam (113). The longitudinal driving device (121) is used to drive the fixed frame (20) to move along the moving crossbeam (113).
8. The artificial stone slab filling equipment according to claim 1, characterized in that, The support platform (3) includes a frame (31) and a conveyor belt (32), the conveyor belt (32) is disposed on the frame (31), and the moving structure (1) is assembled on the frame (31) and located above the conveyor belt (32).