Silica mud material transport device
By introducing a telescopic column and cleaning roller structure of the pusher plate into the silica mud material transportation equipment, combined with anti-sticking agent coating, the problem of silica mud sticking during transportation is solved, realizing automatic discharge and anti-sticking effects, and improving the transportation efficiency and reliability of the equipment.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Patents(China)
- Current Assignee / Owner
- ANHUI MAGSONTE NEW ENERGY TECH CO LTD
- Filing Date
- 2025-12-08
- Publication Date
- 2026-06-23
Smart Images

Figure CN121493559B_ABST
Abstract
Description
Technical Field
[0001] This invention belongs to the field of silica mud processing technology, specifically a silica mud material transportation device. Background Technology
[0002] Silica mud is a material with organosilicon or inorganic silicon as its main components. It is soft, highly malleable, and easy to shape. It is commonly used in industrial sealing and filling materials. Some types of silica mud have high viscosity and are prone to sticking during transportation. Therefore, special silica mud material transportation equipment is used.
[0003] When existing silica mud material transportation equipment is used, silica mud tends to stick to the surface of the transport container. If it is not cleaned in time, the silica mud will dehydrate and turn into a solid during long-term use, which will cause the silica mud to accumulate on the surface of the transport container. This will result in silica mud of different hardness inside the transported silica mud, affecting normal use.
[0004] Therefore, the present invention provides a silica mud material transportation device. Summary of the Invention
[0005] In order to overcome the shortcomings of the prior art, at least one technical problem raised in the background art is solved.
[0006] The technical solution adopted by the present invention to solve its technical problem is as follows: The present invention provides a silica mud material transportation device, including a conveying frame. The top of the conveying frame is rotatably connected to multiple sprockets through a connecting plate. A rotating component is installed on one side of the connecting plate of the conveying frame. The output shaft of the rotating component is fixedly connected to the rotating shaft of one of the sprockets. Two sets of chains are sleeved on the outside of the multiple sprockets. Multiple material boxes are arranged at equal intervals on the outside of the chains. Two connecting blocks are fixed at the bottom of the material boxes. The bottom ends of the two connecting blocks are rotatably connected to the inside of the chains.
[0007] The material handling box is slidably connected to a pusher plate. A first telescopic column is fixed to the bottom end of the pusher plate. The first telescopic column passes through the inside of the material handling box. A first spring is sleeved on the outside of the first telescopic column. The bottom end of the first spring is fixedly connected to the first telescopic column. The top end of the first spring is fixedly connected to the material handling box. A second support frame is fixed to the top of the conveying frame on the side away from the rotating component. A support plate is fixed to one side of the second support frame. A first arc surface is provided on one side of the top end of the support plate.
[0008] When the material handling box rotates to the top of the first arc surface, the arc surface of the first arc surface pushes the first telescopic column to extend into the material handling box, so that the pusher plate unloads material into the material handling box.
[0009] Preferably, a cleaning roller is rotatably connected to the top of the conveyor frame below the second support frame, and the top of the cleaning roller can contact the conveying box and the pusher plate.
[0010] Preferably, both ends of the sprocket shaft near the second support frame are fixed with first pulleys, and both ends of the cleaning roller are fixed with second pulleys. The first pulley and the second pulley on the same side are connected by a belt.
[0011] Preferably, a second arc surface is provided on the side of the bottom end of the support plate near the first arc surface, and the distance between the bottom end point of the second arc surface and the center hole is greater than the distance between the top end point of the first arc surface and the center hole;
[0012] The first telescopic column maintains its state when it slides on the second arc surface.
[0013] Preferably, a first support frame is fixed inside the conveyor frame on the side near the second support frame. A hydraulic telescopic rod is installed at the bottom inside the first support frame. Liquid storage tanks are provided on both sides of the hydraulic telescopic rod inside the first support frame. A lifting frame is provided at the top of the hydraulic telescopic rod. A first brush is provided above the lifting frame.
[0014] Preferably, a liquid distribution tube is fixed at the top of the lifting frame, the first brush cotton is wrapped around the top of the liquid distribution tube, and a first infusion tube is connected to both sides of the bottom end of the liquid distribution tube. The bottom ends of the two first infusion tubes are connected to a feeding assembly.
[0015] Preferably, the liquid distribution tube is provided with a movable tube inside, the top end of the movable tube is fitted with a second brush cotton, the two sides of the bottom end of the second brush cotton are connected to a second infusion tube, the bottom end of the second infusion tube is also connected to the feeding component, and the top end of the hydraulic telescopic rod is provided with a movable component.
[0016] The moving component drives the moving tube to move horizontally inside the dispensing tube.
[0017] Preferably, the moving assembly includes a lifting shell fixed to the top of the hydraulic telescopic rod, a guide strip fixed to the bottom of the middle part of the lifting frame, the lifting shell slidably connected to the outside of the guide strip, two sliding plates fixed to the middle of the bottom end of the moving tube by a connecting rod, the sliding plates slidably connected to the inside of the guide strip, a sliding column fixed to one side of the sliding plate, guide holes opened on both sides of the lifting shell, the sliding column slidably connected to the inside of the guide holes, and a second spring fixed to both sides of the bottom end inside the lifting shell, the top of the second spring being fixedly connected to the guide strip.
[0018] Preferably, the feeding assembly includes a liquid extraction shell fixed on both sides inside the lifting frame. The top of the liquid extraction shell is provided with two liquid outlet pipes, which are respectively connected to a first liquid inlet pipe and a second liquid inlet pipe on the same side. A one-way valve is provided at the connection between the liquid outlet pipe and the liquid extraction shell. A liquid inlet pipe is provided on one side of the liquid extraction shell, which is connected to the interior of the liquid storage tank. A one-way valve is provided at the connection between the liquid inlet pipe and the liquid extraction shell. A piston is provided inside the liquid extraction shell. A third spring is fixed to the top of the piston. A second telescopic column passes through the bottom of the liquid extraction shell, and the top of the second telescopic column is fixedly connected to the bottom of the piston.
[0019] Preferably, top blocks are fixed on both sides of the lifting shell, and the two top blocks are located directly below the two second telescopic columns.
[0020] The beneficial effects of this invention are as follows:
[0021] 1. The silica mud material transport equipment of the present invention uses a first brush and a second brush to coat the surfaces of the transport box and the pusher plate with an anti-sticking agent, which can prevent some silica mud from adhering to the inside of the transport box and the pusher plate when the silica mud is discharged from the inside of the transport box. The coating is applied after each use, thereby making it easier to transport silica mud.
[0022] 2. The silica mud material transport equipment of the present invention guides the first telescopic column through the first arc surface, so that when the first telescopic column passes the position of the first arc surface, it drives the pusher plate, and the pusher plate squeezes out the silica mud inside the transport box, thereby realizing the function of automatic material discharge. Attached Figure Description
[0023] The invention will now be further described with reference to the accompanying drawings.
[0024] Figure 1 This is a perspective view of the present invention;
[0025] Figure 2 This is a schematic diagram of the internal structure of the material handling box in this invention;
[0026] Figure 3 This is a schematic diagram of the sprocket structure in this invention;
[0027] Figure 4 This is a schematic diagram of the support plate structure in this invention;
[0028] Figure 5 This is a schematic diagram of the support frame structure in this invention;
[0029] Figure 6 This is a schematic diagram of the lifting frame structure in this invention;
[0030] Figure 7 This is a schematic diagram of the internal structure of the lifting shell in this invention;
[0031] Figure 8 This is a schematic diagram of the internal structure of the liquid extraction shell in this invention.
[0032] In the diagram: 1. Conveyor frame; 11. First support frame; 12. Sprocket; 121. Chain; 122. First pulley; 123. Second support frame; 124. Support plate; 125. First arc surface; 126. Second arc surface; 13. Material box; 131. Connecting block; 132. Push plate; 133. First telescopic column; 134. First spring; 14. Rotating assembly; 15. Cleaning roller; 151. Second pulley; 2. Hydraulic telescopic rod; 21. Lifting frame; 21 1. Dispensing tube; 212. First brush; 213. First infusion tube; 214. Guide strip; 22. Moving tube; 221. Second brush; 222. Second infusion tube; 223. Sliding plate; 224. Sliding column; 23. Lifting shell; 231. Top block; 232. Guide hole; 233. Second spring; 24. Liquid extraction shell; 241. Third spring; 242. Piston; 243. Inlet tube; 244. Outlet tube; 245. Second telescopic column; 25. Storage tank. Detailed Implementation
[0033] To make the technical means, creative features, objectives and effects of this invention easier to understand, the invention will be further described below in conjunction with specific embodiments.
[0034] like Figures 1 to 4 As shown in the figure, a silica mud material transportation device according to an embodiment of the present invention includes a conveying frame 1. The top of the conveying frame 1 is rotatably connected to a plurality of sprockets 12 via a connecting plate. A rotating assembly 14 is installed on one side of the connecting plate of the conveying frame 1. The output shaft of the rotating assembly 14 is fixedly connected to the rotating shaft of one of the sprockets 12. Two sets of chains 121 are sleeved on the outside of the plurality of sprockets 12. A plurality of material boxes 13 are arranged at equal intervals on the outside of the chains 121. Two connecting blocks 131 are fixed at the bottom of the material boxes 13. The bottom ends of the two connecting blocks 131 are rotatably connected to the inside of the chains 121.
[0035] The material handling box 13 has a sliding connection to a pusher plate 132 inside. The bottom end of the pusher plate 132 is fixed with a first telescopic column 133. The first telescopic column 133 passes through the inside of the material handling box 13. A first spring 134 is sleeved on the outside of the first telescopic column 133. The bottom end of the first spring 134 is fixedly connected to the first telescopic column 133. The top end of the first spring 134 is fixedly connected to the material handling box 13. A second support frame 123 is fixed on the side of the top of the conveyor frame 1 away from the rotating component 14. A support plate 124 is fixed on one side of the second support frame 123. A first arc surface 125 is provided on one side of the top of the support plate 124.
[0036] When the material box 13 rotates to above the first arc surface 125, the arc surface of the first arc surface 125 pushes the first telescopic column 133 to extend into the material box 13, so that the pusher plate 132 unloads material into the material box 13.
[0037] When processing silica sludge, it needs to be transported to the processing station. Material handling equipment is used to transport the silica sludge from the unloading station to the loading station. When the equipment is in use, the conveyor frame 1 is installed between the unloading and loading stations, and an anti-sticking agent is applied to the inside of the material box 13 to prevent silica sludge from adhering to it. At this time, the end of the conveyor frame 1 closest to the rotating assembly 14 is the unloading station, and the external unloading equipment moves towards the current position... Silica sludge is placed inside the material container 13. During this process, the rotating component 14 is paused. When the material container 13 is full of silica sludge, the rotating component 14 drives the sprocket 12 to rotate, the sprocket 12 drives the chain 121 to roll, and the chain 121 moves the material container 13. When the material container 13 filled with silica sludge moves to the next station, the rotating component 14 stops rotating. At this time, silica sludge can be placed inside the next material container 13. This process of continuously placing silica sludge into the material container 13 continues until the material container filled with silica sludge reaches the next station. When the first telescopic column 133 moves to the end of the conveyor frame 1 away from the rotating assembly 14, it will first pass the top of the support plate 124. At this time, the support plate 124 and the first telescopic column 133 are not in contact. The first telescopic column 133 continues to move, and the current conveying box 13 rotates around the axis of the sprocket 12. At this time, the first telescopic column 133 will pass the surface of the first arc surface 125. The first arc surface 125 guides the first telescopic column 133, causing it to extend into the interior of the conveying box 13, while simultaneously squeezing the first spring. Spring 134, at this time, the first telescopic column 133 moves the pusher plate 132 from the inside of the conveying box 13 to the outside. The pusher plate 132 can push the silica mud inside the conveying box 13 to the outside, thereby automatically discharging the silica mud to the loading station. When the conveying box 13 is separated from the first arc surface 125, the first spring 134 pushes the first telescopic column 133 and the pusher plate 132 to automatically reset. In this way, the amount of silica mud conveyed can be controlled more accurately, and at the same time, a large amount of silica mud can be prevented from remaining inside the conveying box 13.
[0038] like Figures 1 to 4 As shown, a cleaning roller 15 is rotatably connected to the top of the conveyor frame 1 below the second support frame 123. The top of the cleaning roller 15 can contact the material box 13 and the push plate 132.
[0039] The cleaning roller 15 cleans the opening of the material box 13 and the surface of the push plate 132, which can remove the residual silica mud on the surface of the material box 13 and the push plate 132, thereby further preventing the residual silica mud on the surface of the material box 13.
[0040] like Figures 1 to 4 As shown, both ends of the sprocket 12 shaft near the second support frame 123 are fixed with first pulleys 122, and both ends of the cleaning roller 15 are fixed with second pulleys 151. The first pulley 122 and the second pulley 151 on the same side are connected by a belt.
[0041] When the sprocket 12 rotates, it drives the first pulley 122 to rotate. At this time, the first pulley 122 drives the second pulley 151 to rotate through the belt. The second pulley 151 drives the cleaning roller 15 to rotate, which allows the cleaning roller 15 to rotate while cleaning the material box 13 and the push plate 132, thereby further improving the cleaning efficiency of the cleaning roller 15 and making the material box 13 and the push plate 132 cleaner.
[0042] like Figures 1 to 4 As shown, a second arc surface 126 is provided on the side of the bottom end of the support plate 124 near the first arc surface 125. The distance between the bottom end point of the second arc surface 126 and the center hole is greater than the distance between the top end point of the first arc surface 125 and the center hole.
[0043] The first telescopic column 133 will maintain its state when it slides on the surface of the second arc surface 126.
[0044] When the cleaning roller 15 cleans the conveying box 13 and the pusher plate 132, it needs to be able to contact the pusher plate 132. Therefore, it is necessary to keep the pusher plate 132 inside the conveying box 13. Guided by the second arc surface 126, the first telescopic column 133 can remain inserted inside the conveying box 13 during the process of the conveying box 13 rotating downward 90°, thereby maintaining... Figure 3 The pusher plate 132 and the conveying box 13 are in a certain state. The bottom of the support plate 124 can keep the pusher plate 132 in a certain state for a distance, which makes it easier for the cleaning roller 15 to clean the conveying box 13 and the pusher plate 132.
[0045] like Figures 1 to 6 As shown, a first support frame 11 is fixed inside the conveyor frame 1 on the side near the second support frame 123. A hydraulic telescopic rod 2 is installed at the bottom inside the first support frame 11. Liquid storage tanks 25 are provided inside the first support frame 11 on both sides of the hydraulic telescopic rod 2. A lifting frame 21 is provided at the top of the hydraulic telescopic rod 2. A first brush cotton 212 is provided above the lifting frame 21.
[0046] To prevent silica sludge from adhering to the inside of the material box 13, an anti-sticking agent needs to be brushed onto the inner wall of the material box 13. After the material box 13 is cleaned by the cleaning roller 15, it moves above the hydraulic telescopic rod 2. At this time, the pusher plate 132 returns to the inside of the material box 13. Then, the hydraulic telescopic rod 2 pushes the lifting frame 21 to extend into the inside of the material box 13. At this time, the first brush cotton 212 above the lifting frame 21 can apply anti-sticking agent to the inner wall of the material box 13, thereby restoring the anti-sticking effect inside the material box 13 and preventing silica sludge from adhering to the inside of the material box 13.
[0047] like Figures 1 to 6 As shown, a liquid distribution pipe 211 is fixed at the top of the lifting frame 21, a first brush cotton 212 is wrapped around the top of the liquid distribution pipe 211, and a first infusion pipe 213 is connected to both sides of the bottom end of the liquid distribution pipe 211. A feeding component is connected to the bottom end of both first infusion pipes 213.
[0048] When the first brush 212 is applied, the feeding component extracts the anti-sticking agent from the storage tank 25 and injects it into the distribution tube 211 through the first delivery tube 213. This allows the agent to be evenly distributed to the inside of the first brush 212 through the distribution tube 211, keeping the inside of the first brush 212 wet and making it easier to apply the coating to the inside of the material box 13.
[0049] like Figures 1 to 6 As shown, a movable tube 22 is provided inside the liquid distribution tube 211. A second brush cotton 221 is sleeved on the top end of the movable tube 22. The two sides of the bottom end of the second brush cotton 221 are connected to the second infusion tube 222. The bottom end of the second infusion tube 222 is also connected to the feeding component. A movable component is provided on the top end of the hydraulic telescopic rod 2.
[0050] Among them, the moving component drives the moving tube 22 to move horizontally inside the dispensing tube 211;
[0051] When the first brush 212 is coated, there are dead corners in the middle that are not coated. Therefore, a moving tube 22 is set up. The feeding component will simultaneously deliver anti-sticking agent to the moving tube 22 through the second infusion tube 222. The moving tube 22 injects the anti-sticking agent into the interior of the second brush 221 and moves the moving tube 22 horizontally through the moving component. At this time, the moving tube 22 drives the second brush 221 to coat the surface of the push plate 132 with anti-sticking agent, thereby achieving the coating of anti-sticking agent on the dead corners inside the material box 13.
[0052] like Figures 1 to 7As shown, the moving assembly includes a lifting shell 23 fixed to the top of the hydraulic telescopic rod 2, a guide bar 214 fixed to the bottom of the middle part of the lifting frame 21, the lifting shell 23 slidably connected to the outside of the guide bar 214, two sliding plates 223 fixed to the middle of the bottom of the moving tube 22 by a connecting rod, the sliding plates 223 slidably connected to the inside of the guide bar 214, a sliding column 224 fixed to one side of the sliding plate 223, guide holes 232 opened on both sides of the lifting shell 23, the sliding column 224 slidably connected to the inside of the guide holes 232, and a second spring 233 fixed to both sides of the bottom of the lifting shell 23, the top of the second spring 233 fixedly connected to the guide bar 214;
[0053] When the hydraulic telescopic rod 2 pushes the lifting frame 21 upward, it also pushes the lifting shell 23 upward. At this time, the lifting shell 23, supported by the elasticity of the second spring 233, pushes the guide bar 214, causing the lifting frame 21 to rise. During this process, the first brush 212 coats the inner wall of the material box 13 with an anti-sticking agent. When the liquid distribution pipe 211 contacts the pusher plate 132, the hydraulic telescopic rod 2 continues to push the lifting shell 23 upward. At this time, the top of the liquid distribution pipe 211 is limited by the pusher plate 132, and the second spring 233 is compressed, thus raising the lifting frame 21. The shell 23 drives the guide hole 232 to rise. When the guide hole 232 rises, it guides the sliding column 224, which can drive the moving tube 22 to move horizontally through the sliding plate 223. When the moving tube 22 moves horizontally, it can drive the second brush cotton 221 to coat the surface of the push plate 132 with anti-sticking agent. After the coating is completed, the hydraulic telescopic rod 2 drives the lifting frame 21 and multiple structures to return to the ground. The elastic force of the second spring 233 drives the sliding column 224 to return to the ground, thereby achieving a more comprehensive coating of anti-sticking agent on the surfaces of the material box 13 and the push plate 132.
[0054] like Figures 1 to 8 As shown, the feeding assembly includes a liquid extraction shell 24 fixed inside both sides of the lifting frame 21. The top of the liquid extraction shell 24 is provided with two liquid outlet pipes 244, which are respectively connected to the first liquid inlet pipe 213 and the second liquid inlet pipe 222 on the same side. A one-way valve is provided at the connection between the liquid outlet pipe 244 and the liquid extraction shell 24. A liquid inlet pipe 243 is provided on one side of the liquid extraction shell 24, which is connected to the inside of the liquid storage tank 25. A one-way valve is provided at the connection between the liquid inlet pipe 243 and the liquid extraction shell 24. A piston 242 is provided inside the liquid extraction shell 24. A third spring 241 is fixed at the top of the piston 242. A second telescopic column 245 passes through the bottom of the liquid extraction shell 24, and the top of the second telescopic column 245 is fixedly connected to the bottom of the piston 242.
[0055] When it is necessary to deliver anti-sticking agent into the dispensing tube 211 and the moving tube 22, the second telescopic column 245 is pushed into the suction shell 24. At this time, the second telescopic column 245 pushes the piston 242, and the suction shell 24 is filled with anti-sticking agent. The piston 242 squeezes the anti-sticking agent inside the suction shell 24. At this time, the one-way valve of the outlet tube 244 opens, and the anti-sticking agent is delivered to the first delivery tube 213 and the second delivery tube 222 through the outlet tube 244. Then, the second telescopic column 245 is released, and the elastic force of the third spring 241 pushes the piston 242 to return to its original position. At this time, the one-way valve of the outlet tube 244 closes, and the inlet tube 243 opens to draw anti-sticking agent from inside the storage tank 25, completing one delivery of anti-sticking agent, thus making it easier to deliver the anti-sticking agent.
[0056] like Figures 1 to 8 As shown, top blocks 231 are fixed on both sides of the lifting shell 23, and the two top blocks 231 are located directly below the two second telescopic columns 245.
[0057] During coating, both the first brush cotton 212 and the second brush cotton 221 remain wet. When the liquid distribution pipe 211 touches the top, it is limited by the push plate 132. At this time, the lifting shell 23 continues to rise, and the lifting shell 23 drives the top block 231 to rise. Then, after the top block 231 moves a certain distance, it will push the second telescopic column 245 to rise, thereby driving the feeding component to deliver the anti-sticking agent. When the hydraulic telescopic rod 2 drives the lifting shell 23 to reset downward, the top block 231 moves downward, thereby automatically resetting the second telescopic column 245, which makes it easier for the subsequent liquid extraction shell 24 to deliver the anti-sticking agent.
[0058] The foregoing has shown and described the basic principles, main features, and advantages of the present invention. Those skilled in the art should understand that the present invention is not limited to the above embodiments. The embodiments and descriptions in the specification are merely illustrative of the principles of the invention. Various changes and modifications can be made to the invention without departing from its spirit and scope, and all such changes and modifications fall within the scope of the present invention as claimed. The scope of protection of the present invention is defined by the appended claims and their equivalents.
Claims
1. A silica mud material transport device, characterized in that: The device includes a conveyor frame, the top of which is rotatably connected to multiple sprockets via a connecting plate. A rotating assembly is installed on one side of the connecting plate, and the output shaft of the rotating assembly is fixedly connected to the shaft of one of the sprockets. Two sets of chains are sleeved on the outside of the multiple sprockets. Multiple material boxes are evenly spaced on the outside of the chains. Two connecting blocks are fixed to the bottom of each material box, and the bottom ends of the two connecting blocks are rotatably connected to the inside of the chains. The material handling box is slidably connected to a pusher plate. A first telescopic column is fixed to the bottom end of the pusher plate. The first telescopic column passes through the inside of the material handling box. A first spring is sleeved on the outside of the first telescopic column. The bottom end of the first spring is fixedly connected to the first telescopic column. The top end of the first spring is fixedly connected to the material handling box. A second support frame is fixed to the top of the conveying frame on the side away from the rotating component. A support plate is fixed to one side of the second support frame. A first arc surface is provided on one side of the top end of the support plate. When the material handling box rotates to the top of the first arc surface, the arc surface of the first arc surface pushes the first telescopic column to extend into the material handling box, so that the pusher plate unloads material into the material handling box. The top of the conveyor frame is rotatably connected to a cleaning roller located below the second support frame, and the top of the cleaning roller can contact the material box and the pusher plate. Both ends of the sprocket shaft near the second support frame are fixed with first pulleys, and both ends of the cleaning roller are fixed with second pulleys. The first pulley and the second pulley on the same side are connected by a belt. A second arc surface is provided on the side of the bottom end of the support plate near the first arc surface, and the distance between the bottom end point of the second arc surface and the center hole is greater than the distance between the top end point of the first arc surface and the center hole. The first telescopic column maintains its state when it slides on the second arc surface.
2. The silica mud material transport equipment according to claim 1, characterized in that: A first support frame is fixed inside the conveyor frame near the second support frame. A hydraulic telescopic rod is installed at the bottom inside the first support frame. Liquid storage tanks are provided on both sides of the hydraulic telescopic rod inside the first support frame. A lifting frame is provided at the top of the hydraulic telescopic rod. A first brush is provided above the lifting frame.
3. The silica mud material transport equipment according to claim 2, characterized in that: The top of the lifting frame is fixed with a liquid distribution tube, the first brush cotton is wrapped around the top of the liquid distribution tube, and the bottom of the liquid distribution tube is connected to the two sides of the bottom of the liquid distribution tube with a first infusion tube, and the bottom of the two first infusion tubes is connected to a feeding component.
4. The silica mud material transport equipment according to claim 3, characterized in that: The liquid distribution tube is equipped with a movable tube inside. The top end of the movable tube is fitted with a second brush cotton. The two sides of the bottom end of the second brush cotton are connected to a second infusion tube. The bottom end of the second infusion tube is also connected to the feeding component. The top end of the hydraulic telescopic rod is equipped with a movable component. The moving component drives the moving tube to move horizontally inside the dispensing tube.
5. A silica mud material transport device according to claim 4, characterized in that: The moving assembly includes a lifting shell fixed to the top of the hydraulic telescopic rod. A guide bar is fixed to the bottom of the middle part of the lifting frame. The lifting shell is slidably connected to the outside of the guide bar. Two sliding plates are fixed to the middle of the bottom end of the moving tube by a connecting rod. The sliding plates are slidably connected to the inside of the guide bar. A sliding column is fixed to one side of the sliding plate. Guide holes are opened on both sides of the lifting shell. The sliding column is slidably connected to the inside of the guide holes. Second springs are fixed to both sides of the bottom end inside the lifting shell. The top of the second spring is fixedly connected to the guide bar.
6. The silica mud material transport equipment according to claim 3, characterized in that: The feeding assembly includes a liquid extraction shell fixed inside both sides of the lifting frame. The top of the liquid extraction shell is provided with two liquid outlet pipes, which are respectively connected to a first liquid inlet pipe and a second liquid inlet pipe on the same side. A one-way valve is provided at the connection between the liquid outlet pipe and the liquid extraction shell. A liquid inlet pipe is provided on one side of the liquid extraction shell, which is connected to the inside of the liquid storage tank. A one-way valve is provided at the connection between the liquid inlet pipe and the liquid extraction shell. A piston is provided inside the liquid extraction shell. A third spring is fixed to the top of the piston. A second telescopic column passes through the bottom of the liquid extraction shell, and the top of the second telescopic column is fixedly connected to the bottom of the piston.
7. A silica mud material transport device according to claim 5, characterized in that: Top blocks are fixed on both sides of the lifting shell, and the two top blocks are located directly below the two second telescopic columns.