Anti-toppling concrete pouring apparatus

By designing an anti-tipping concrete pouring device and utilizing sliding structures and stabilizing components, the problems of uneven pouring and unstable duct were solved, achieving uniformity of concrete pouring and stability of the duct, and simplifying the construction process.

CN117703082BActive Publication Date: 2026-07-10POWERCHINA RAILWAY CONSTR +1

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Patents(China)
Current Assignee / Owner
POWERCHINA RAILWAY CONSTR
Filing Date
2023-12-15
Publication Date
2026-07-10

AI Technical Summary

Technical Problem

Existing grouting equipment is prone to local stacking during concrete grouting, resulting in uneven grouting, and the grouting conduit is difficult to fix stably.

Method used

An anti-tipping concrete pouring device was designed, including components such as a hopper, longitudinal plate, support plate, pneumatic rod, and electric push rod. Through a sliding structure and stabilizing components, the position of the hopper can be adjusted and the pouring pipe can be stably fixed, avoiding concrete accumulation and facilitating the removal of the pipe.

Benefits of technology

It achieves uniform concrete pouring and stability of the pouring conduit, avoids concrete stacking, simplifies the conduit removal process, and improves construction efficiency.

✦ Generated by Eureka AI based on patent content.

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Abstract

The application discloses an anti-toppling concrete pouring equipment and relates to the technical field of building construction. The anti-toppling concrete pouring equipment comprises a hopper and a longitudinal plate. The left side of the hopper is provided with an adjusting assembly for position stabilization. The adjusting assembly comprises a supporting plate two, a fixing block and an air rod. The outer surface of the supporting plate two is provided with the fixing block. The outer surface of the fixing block is provided in the middle with the air rod. The output end of the air rod is provided with a bottom plate. One side of the bottom plate is connected with a connecting column. The top of the connecting column is provided with a convex column. The left and right surfaces of the hopper are provided with limiting columns. The inside of the limiting columns is provided with limiting holes. The right side of the hopper is provided with a supporting plate one. The anti-toppling concrete pouring equipment is characterized in that the extending plate is slidingly connected to the auxiliary frame. The coincidence degree of the extending plate between the auxiliary frame can be controlled. The length of the auxiliary frame can be adjusted according to the size of the concrete pouring area. The hopper can be conveniently and stably arranged above the concrete pouring area.
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Description

Technical Field

[0001] This invention relates to the field of building construction technology, specifically to a concrete pouring device designed to prevent tipping. Background Technology

[0002] In civil engineering construction, concrete pouring simply refers to pouring prepared concrete into pre-assembled formwork. For taller buildings or deeper piles, pumping is generally used for pouring. Pouring typically requires a hopper and a pouring pipe to deliver the concrete and achieve the purpose of pouring.

[0003] Existing grouting equipment generally requires the grouting conduit to be inserted deep into the concrete grouting area. The position of the grouting conduit is fixed, and the concrete will pile up locally during the pouring process, resulting in uneven grouting of the concrete grouting area.

[0004] Therefore, in view of this, we have studied and improved the existing structure and its shortcomings, and proposed a concrete pouring device that prevents tipping. Summary of the Invention

[0005] To address the shortcomings of existing technologies, this invention provides an anti-tipping concrete pouring device, which solves the problems mentioned in the background section.

[0006] To achieve the above objectives, the present invention provides the following technical solution: a concrete pouring device for preventing tipping, comprising a hopper and a longitudinal plate. An adjustment component for position stabilization is provided on the left side of the hopper. The adjustment component includes a second support plate, a fixing block, and a pneumatic rod. The fixing block is provided on the outer surface of the second support plate, and a pneumatic rod is installed in the middle of the outer surface of the fixing block. A base plate is provided at the output end of the pneumatic rod, and a connecting column is connected to one side of the base plate. A protruding column is installed on the top of the connecting column. Limiting columns are provided on the left and right sides of the hopper, and limiting holes are formed inside the limiting columns. A first support plate is provided on the right side of the hopper. The support plate has a horizontal plate installed at its bottom, a longitudinal plate at its end, a slide rail inside the longitudinal plate, an auxiliary frame at its end, a fixed plate fixedly installed in the middle of the auxiliary frame, an electric push rod on one outer surface of the fixed plate, an extension plate installed inside the auxiliary frame away from the electric push rod, a positioning clamp inside the hopper, a threaded rod installed on one side of the positioning clamp, a tube disc between the two sets of positioning clamps, a corrugated pipe on the outer surface of the tube disc, an injection conduit at the bottom of one set of the tube disc, and a guide plate at the bottom of the support plate.

[0007] Furthermore, the tubing coil is provided in two sets, one set of which is threadedly connected to the infusion conduit.

[0008] Furthermore, the first support plate forms a sliding structure with the horizontal plate via a slider, and the first support plate has the same structure as the second support plate.

[0009] Furthermore, the hopper forms a sliding structure with the longitudinal plate and the slide rail via a slider, and the longitudinal plate is provided in two sets.

[0010] Furthermore, the longitudinal plates and transverse plates are vertically distributed, and the longitudinal plates and auxiliary frames are an integrated structure.

[0011] Furthermore, one end of the auxiliary frame is slidably connected to the extension plate, and the auxiliary frame has a hollow structure.

[0012] Furthermore, a mounting plate is provided on one side of the bottom of the hopper, and a servo motor is mounted on the outer surface of the mounting plate, with a lead screw connected to the output end of the servo motor.

[0013] Furthermore, a stabilizing component for secondary adjustment of the position of the infusion conduit is installed on the outside of the lead screw, and the stabilizing component includes a limiting sleeve, a connecting rod and a connecting plate. The bottom thread of the limiting sleeve is threaded with the connecting rod, and the bottom thread of the connecting rod is threaded with the connecting plate.

[0014] Furthermore, the stabilizing component also includes a threaded cap, a first connecting rod, and a second connecting rod. The first connecting rod is installed on the internal thread of the connecting disc, the top of the first connecting rod is provided with a threaded cap, and the second connecting rod is installed on the internal thread of the first connecting rod.

[0015] Furthermore, arc-shaped plates are installed at the four corners of the hopper, and the hopper and the arc-shaped plates are integrated into one structure.

[0016] This invention provides an anti-tipping concrete pouring device, which has the following beneficial effects:

[0017] 1. This anti-tipping concrete pouring equipment allows the hopper to move longitudinally via a slider and a slide rail in the longitudinal plate. After the hopper is placed in the concrete pouring area, its position can be adjusted again, preventing concrete leaking from the pouring pipe from continuously pouring into the same position and causing concrete pile-up that needs to be manually pushed away.

[0018] 2. This anti-tipping concrete pouring equipment features a sliding connection design between the extension plate and the auxiliary frame. By controlling the overlap between the extension plate and the auxiliary frame, the length of the auxiliary frame can be adjusted according to the size of the concrete pouring area, ensuring that the hopper is stably positioned above the concrete pouring area.

[0019] 3. This anti-tipping concrete pouring equipment, through the design of support plate one and support plate two on both sides of the hopper and the design of the adjustment component, can lift the position of the hopper. The horizontal plate is fixed to the hopper with screws, and the hopper can be removed independently. Thus, when the hopper is lifted and moved to one side, the bottom plate of the pouring pipe can be used to limit and lift it from both sides by the adjustment component and the design of support plate one, support plate two and horizontal plate, so that the pouring pipe can be removed after the concrete pouring is completed.

[0020] This anti-tipping concrete pouring equipment, through the design of stabilizing components and the connecting disc sleeved on the outside of the pouring conduit, allows the position of the pouring conduit to be changed by the positional movement of the limiting sleeve and connecting rod, utilizing the corrugated pipe design. This facilitates secondary adjustment of the concrete pouring area of ​​the pouring conduit. Furthermore, the first and second connecting rods are threadedly connected, making it easy for the user to assemble the first and second connecting rods. The first and second connecting rods are arranged in a ring around the outside of the pouring conduit, resulting in greater stability when adjusting the position of the pouring conduit. Attached Figure Description

[0021] Figure 1 This is a schematic diagram of the overall structure of an anti-tipping concrete pouring device according to the present invention;

[0022] Figure 2 This is a schematic diagram of the connection structure of the pouring conduit for an anti-tipping concrete pouring device according to the present invention;

[0023] Figure 3 This is a schematic diagram of the connection structure between the auxiliary frame and the extension plate of an anti-tipping concrete pouring equipment according to the present invention;

[0024] Figure 4 This is a top view of the hopper structure of an anti-tipping concrete pouring device according to the present invention;

[0025] Figure 5 This is a schematic diagram of the internal structure of the auxiliary frame of an anti-tipping concrete pouring device according to the present invention;

[0026] Figure 6 This invention relates to an anti-tipping concrete pouring device. Figure 1 Enlarged structural diagram at point A in the middle.

[0027] In the diagram: 1. Support plate one; 2. Adjustment component; 201. Support plate two; 202. Fixing block; 203. Air rod; 3. Hopper; 4. Base plate; 5. Connecting column; 6. Protruding column; 7. Guide plate; 8. Longitudinal plate; 9. Slide rail; 10. Auxiliary frame; 11. Limiting column; 12. Limiting hole; 13. Threaded rod; 14. Arc plate; 15. Mounting plate; 16. Servo motor; 17. Lead screw; 18. Stabilizing component; 1801. Limiting sleeve; 1802. Connecting rod; 1803. Connecting disc; 1804. Threaded cap; 1805. First connecting rod; 1806. Second connecting rod; 19. Extension plate; 20. Positioning clamp; 21. Electric push rod; 22. Fixing plate; 23. Tube coil; 24. Corrugated pipe; 25. Horizontal plate; 26. Injection conduit. Detailed Implementation

[0028] The embodiments of the present invention will be described in further detail below with reference to the accompanying drawings and examples. The following examples are for illustrative purposes only and should not be construed as limiting the scope of the invention.

[0029] like Figure 1 , Figure 5 and Figure 6As shown, the present invention provides a technical solution: a concrete pouring device for preventing tipping, comprising a support plate 1, an adjusting component 2, a support plate 201, a fixing block 202, a pneumatic rod 203, a hopper 3, a base plate 4, a connecting column 5, a protruding column 6, a guide plate 7, a longitudinal plate 8, a slide rail 9, an auxiliary frame 10, a limiting column 11, a limiting hole 12, a threaded rod 13, an arc-shaped plate 14, a mounting plate 15, a servo motor 16, a lead screw 17, a stabilizing component 18, a limiting sleeve 1801, a connecting rod 1802, a connecting disc 1803, a threaded cap 1804, a first connecting rod 1805, a second connecting rod 1806, an extension plate 19, a positioning clamp 20, an electric push rod 21, and a fixing plate. 22. Pipe coil 23. Corrugated pipe 24. Horizontal plate 25. Injection conduit 26. A position stabilization adjustment component 2 is provided on the left side of the hopper 3. The adjustment component 2 includes a support plate 201, a fixing block 202, and a pneumatic rod 203. Arc-shaped plates 14 are installed at the four corners of the hopper 3, and the hopper 3 and the arc-shaped plates 14 are integrated. The hollow structure between the arc-shaped plates 14 and the hopper 3 facilitates the user's use by tying ropes to lift the hopper 3 as needed. The hopper 3 forms a sliding structure with the longitudinal plate 8 and the slide rail 9 via a slider. Two sets of longitudinal plates 8 are provided. A fixing block 202 is provided on the outer surface of the support plate 201, and a fixing block 202 is installed in the middle of the outer surface of the fixing block 202. The hopper 3 has a pneumatic rod 203, with a base plate 4 at its output end. A connecting post 5 is connected to one side of the base plate 4, and a protruding post 6 is installed on the top of the connecting post 5. Limiting posts 11 are provided on the left and right sides of the hopper 3, and limiting holes 12 are opened inside the limiting posts 11. The design of the support plate 1 and the support plate 201 on both sides of the hopper 3, along with the design of the fixing block 202 and the pneumatic rod 203, allows the base plate 4 to move up and down. The up and down movement of the base plate 4 allows the connecting post 5 to move synchronously. Both the support plate 1 and the support plate 201 can slide along the horizontal plate 25, so that the connecting post 5 can be inserted into the limiting post 11 after moving to the appropriate position. Inside the support plate 1, the protruding post 6 at the top of the connecting post 5 can be inserted into the limiting hole 12. The design of the protruding post 6 being inserted into the limiting hole 12 ensures that the hopper 3 connected to the limiting post 11 is connected in place while being lifted, avoiding slippage during the lifting process. With the same connection structure and opposite positions in the support plate 1 and support plate 201, after the protruding post 6 at the top of one set of connecting posts 5 can be inserted into the limiting hole 12 to lift the hopper 3 to a certain height, the protruding post 6 at the top of the other set of connecting posts 5 can be inserted into the limiting hole 12 to stabilize the lifting height of the hopper 3. A guide plate 7 is provided at the bottom of support plate 201.

[0030] like Figure 2 , Figure 4 and Figure 5As shown, a support plate 1 is provided on the right side of the hopper 3, and a horizontal plate 25 is installed at the bottom of the support plate 1. The support plate 1 and the horizontal plate 25 form a sliding structure through a slider. The support plate 1 and the support plate 201 have the same structure. A longitudinal plate 8 is provided at the end of the horizontal plate 25. The longitudinal plate 8 and the horizontal plate 25 are vertically distributed, and the longitudinal plate 8 and the auxiliary frame 10 are an integrated structure. Through the longitudinal and transverse design of the longitudinal plate 8 and the horizontal plate 25, it is possible to prevent the concrete pouring area from tipping over when pouring concrete into the hopper 3. It has good stability. A slide 9 is provided inside the longitudinal plate 8. An auxiliary frame 10 is provided at the end of the longitudinal plate 8, and a fixing plate 22 is fixedly installed in the middle of the auxiliary frame 10. The hopper 3 passes through... The slide block and the slide rail 9 in the longitudinal plate 8 allow for longitudinal positional movement, enabling the hopper 3 to be repositioned after being placed in the concrete pouring area. This prevents concrete leaking from the pouring pipe 26 from continuously pouring into the same position, avoiding the problem of concrete accumulation requiring manual pushing. One end of the auxiliary frame 10 is slidably connected to the extension plate 19, and the auxiliary frame 10 has a hollow structure. The output end of the electric push rod 21 is connected to the bottom slide block of the hopper 3, thus the electric push rod 21 can drive the hopper 3 to move in the slide rail 9 in the longitudinal plate 8, facilitating the adjustment of the pouring area of ​​the pouring pipe 26. The electric push rod 21 is provided on one outer surface of the fixed plate 22, and the extension plate 19 is installed on the side of the auxiliary frame 10 away from the electric push rod 21. The concrete pouring area of ​​the same size is slidably connected to the auxiliary frame 10 via an extension plate 19. By controlling the overlap between the extension plate 19 and the auxiliary frame 10, the length of the auxiliary frame 10 can be adjusted according to the size of the concrete pouring area, facilitating the stable positioning of the hopper 3 above the concrete pouring area. The hopper 3 is equipped with a positioning clamp 20 inside, and a threaded rod 13 is installed on one side of the positioning clamp 20. A tube disc 23 is positioned between the two sets of positioning clamps 20, and a corrugated pipe 24 is provided on the outer surface of the tube disc 23. The two sets of positioning clamps 20 can be moved closer or further apart by rotating the threaded rod 13 counterclockwise or clockwise. The movement of the two sets of positioning clamps 20 allows for adjustment of the hollow circular tube disc 23 at the top of the corrugated pipe 24. The pipe disc 23 is fixed in place, and when the corrugated pipe 24 connected to it breaks after repeated use, the two sets of positioning clamps 20 can be moved apart by rotating the threaded rod 13, facilitating the replacement of the corrugated pipe 24 without requiring the entire hopper 3 to be replaced. A grouting conduit 26 is installed at the bottom of one set of pipe disc 23. When concrete enters the corrugated pipe 24 through the hopper 3, the mobility of the corrugated pipe 24 provides a buffer, reducing the impact when the concrete is transferred to the grouting conduit 26 and preventing excessive shaking of the grouting conduit 26 due to the continuous influx of new concrete during pouring. Two sets of pipe disc 23 are provided; one set is threadedly connected to the grouting conduit 26, allowing for easy separation of the pipe disc 23 from the grouting conduit 26 after the hopper 3 is raised.After the pipe disc 23 is separated from the infusion conduit 26, the horizontal plate 25 is fixed to the hopper 3 with screws. The hopper 3 can be removed independently. When the hopper 3 finishes lifting and moves to one side, the horizontal plate 25 is fixed to the placement surface by striking the positioning rod. The design of the fixing block 202 and the air rod 203 allows the base plate 4 to move up and down. This movement of the base plate 4 causes the connecting column 5 to move synchronously. Both support plate 1 and support plate 201 can slide along the horizontal plate 25, allowing the two sets of base plates 4 to move closer together and limit the infusion conduit 26. The air rod 203 assists in pulling the infusion conduit 26 upwards from the pouring area.

[0031] like Figure 1 and Figure 2 As shown, a mounting plate 15 is provided on one side of the bottom of the hopper 3, and a servo motor 16 is mounted on the outer surface of the mounting plate 15. The output end of the servo motor 16 is connected to a lead screw 17. A stabilizing component 18 for secondary adjustment of the position of the infusion conduit 26 is mounted on the outside of the lead screw 17. The stabilizing component 18 includes a limiting sleeve 1801, a connecting rod 1802, and a connecting plate 1803. The connecting rod 1802 is threaded at the bottom of the limiting sleeve 1801, and the connecting plate 1803 is threaded at the bottom of the connecting rod 1802. The stabilizing component 18 also includes a threaded cover 1804, a first connecting rod 1805, and a second connecting rod 1806. The first connecting rod 1805 is threaded on the inside of the connecting plate 1803, and the threaded cover 1804 is provided on the top of the first connecting rod 1805. The second connecting rod 1806 is threaded on the inside of the first connecting rod 1805. The servo motor 16 is designed to drive the lead screw 17 to rotate, thereby adjusting the position of the limiting sleeve 1801 on the outside of the lead screw 17. 1801 will rotate synchronously, and the top of the limiting sleeve 1801 will slide against the limiting hopper 3, so that the limiting sleeve 1801 can move horizontally outside the screw 17. The limiting sleeve 1801 is connected to the connecting rod 1802, and the connecting plate 1803 is sleeved on the outside of the grouting conduit 26. Thus, by moving the position of the limiting sleeve 1801 and the connecting rod 1802, the design of the corrugated pipe 24 can be used to change the position of the grouting conduit 26, which is convenient for the concrete pouring area of ​​the grouting conduit 26 to be adjusted a second time. According to the length of the grouting conduit 26, the first connecting rod 1805 can be rotated to make it threadedly connected to the connecting plate 1803. The first connecting rod 1805 and the second connecting rod 1806 are threadedly connected, which is convenient for the user to assemble the first connecting rod 1805 and the second connecting rod 1806 in a ring. The first connecting rod 1805 and the second connecting rod 1806 are distributed in a ring outside the grouting conduit 26, which can make the grouting conduit 26 more stable when adjusting its position.

[0032] In summary, as Figures 1-6As shown, in use, the anti-tipping concrete pouring equipment has a pouring conduit 26 positioned on both sides of the hopper 3 via support plates 1 and 201. The design of the fixing block 202 and the air rod 203 allows the base plate 4 to move up and down. This up-and-down movement of the base plate 4 causes the connecting column 5 to move synchronously. Both support plates 1 and 201 can slide along the horizontal plate 25, allowing the connecting column 5 to be inserted into the limiting column 11 after reaching the appropriate position. Simultaneously, the protruding post 6 at the top of the connecting column 5 can be inserted into the limiting hole 12. This design ensures that the connection is in place while the hopper 3 connected to the limiting column 11 is being lifted, preventing slippage during the lifting process. To address the issue of detachment, the support plates 1 and 201 are designed with identical but opposite connecting structures. After the protruding post 6 at the top of one set of connecting posts 5 is inserted into the limiting hole 12 to raise the hopper 3 to a certain height, the protruding post 6 at the top of the other set of connecting posts 5 can be inserted into the limiting hole 12 to stabilize the height of the hopper 3. After the hopper 3 is raised, the tube coil 23 and the filling conduit 26 can be easily separated. After separation, the horizontal plate 25 is fixed to the hopper 3 with screws, allowing the hopper 3 to be removed independently. When the hopper 3 is moved to one side after lifting, the horizontal plate 25 is fixed to the placement surface by striking the positioning rod. This is achieved through the design of the fixing block 202 and the air rod 203. The design allows the base plate 4 to move up and down, which in turn moves the connecting column 5 synchronously. Both support plate 1 and support plate 201 can slide along the horizontal plate 25, allowing the two sets of base plates 4 to move closer together and limit the position of the grouting conduit 26. The design of the air rod 203 assists in pulling the grouting conduit 26 upwards from the pouring area, facilitating the user's segmented disassembly of the assembled grouting conduit 26. Furthermore, the hopper 3 can move longitudinally via the slider and the slide rail 9 in the longitudinal plate 8, allowing for repositioning after the hopper 3 is placed in the concrete pouring area. This prevents concrete leaking from the grouting conduit 26 from continuously pouring into the same position, avoiding the problem of concrete accumulation requiring manual pushing. Secondly, the design of the threaded rod 13... Rotating counterclockwise or clockwise controls the two sets of positioning clamps 20 to move closer and further apart. This movement of the clamps fixes the hollow circular tube disc 23 at the top of the bellows 24. Furthermore, if the bellows 24, connected to the tube disc 23, breaks after repeated use, rotating the threaded rod 13 moves the two sets of positioning clamps 20 away, facilitating replacement of the bellows 24 without requiring a complete replacement of the hopper 3. Finally, the servo motor 16 drives the lead screw 17 to rotate, causing the limiting sleeve 1801 outside the lead screw 17 to rotate synchronously. The top of the limiting sleeve 1801 slides against the hopper 3, allowing it to move horizontally outside the lead screw 17. The limiting sleeve 1801 is connected to the connecting rod 1802.The connecting plate 1803 is fitted onto the outside of the grouting conduit 26. The position of the grouting conduit 26 can be changed by the positional movement of the limiting sleeve 1801 and the connecting rod 1802, utilizing the design of the bellows 24. This facilitates secondary adjustments to the concrete pouring area of ​​the grouting conduit 26. Furthermore, the first connecting rod 1805 can be rotated to threadedly connect with the connecting plate 1803 according to the length of the grouting conduit 26. The first connecting rod 1805 and the second connecting rod 1806 are also threadedly connected, facilitating user assembly. The first connecting rod 1805 and the second connecting rod 1806 are arranged in a ring around the outside of the grouting conduit 26, providing greater stability during position adjustments.

[0033] The embodiments of the present invention are given for illustrative and descriptive purposes only, and are not intended to be exhaustive or to limit the invention to the forms disclosed. Many modifications and variations will be apparent to those skilled in the art. The embodiments were chosen and described in order to better illustrate the principles and practical application of the invention, and to enable those skilled in the art to understand the invention and to design various embodiments with various modifications suitable for a particular purpose.

Claims

1. A concrete pouring device for preventing tipping, comprising a hopper (3) and a longitudinal plate (8), characterized in that: The left side of the hopper (3) is provided with an adjustment component (2) for stabilizing the position. The adjustment component (2) includes a second support plate (201), a fixing block (202), and a pneumatic rod (203). The outer surface of the second support plate (201) is provided with the fixing block (202), and the middle of the outer surface of the fixing block (202) is provided with the pneumatic rod (203). The output end of the pneumatic rod (203) is provided with a base plate (4), and a connecting column (5) is connected to one side of the base plate (4). A protruding column (6) is installed on the top of the connecting column (5). Limiting columns (11) are provided on the left and right sides of the hopper (3), and limiting holes (12) are opened inside the limiting columns (11). A support plate (1) is provided on the right side of the hopper (3), and a horizontal plate (25) is installed at the bottom of the support plate (1). A longitudinal plate (8) is provided at the end of the horizontal plate (25). A slide rail (9) is provided inside the longitudinal plate (8). An auxiliary frame (10) is provided at the end of the longitudinal plate (8), and a fixing plate (22) is fixedly installed in the middle of the auxiliary frame (10). An electric push rod (21) is provided on one side of the outer surface of the fixing plate (22). An extension plate (19) is installed on the side of the auxiliary frame (10) away from the electric push rod (21). A positioning clamp (20) is provided inside the hopper (3), and one side of the positioning clamp (20) is... A threaded rod (13) is installed, a tube disc (23) is provided between the two sets of positioning clamps (20), and a corrugated pipe (24) is provided on the outer surface of the tube disc (23). A filling conduit (26) is provided at the bottom of one set of the tube discs (23). A guide plate (7) is provided at the bottom of the second support plate (201). A mounting plate (15) is provided on one side of the bottom of the hopper (3), and a servo motor (16) is installed on the outer surface of the mounting plate (15). The output end of the servo motor (16) is connected to a lead screw (17). A stabilizing component (18) for second-degree adjustment of the position of the filling conduit (26) is installed on the outside of the lead screw (17), and the stabilizing component (18) includes... The stabilizing assembly (18) includes a limiting sleeve (1801), a connecting rod (1802), and a connecting plate (1803). The bottom thread of the limiting sleeve (1801) is threaded with the connecting rod (1802), and the bottom thread of the connecting rod (1802) is threaded with the connecting plate (1803). The stabilizing assembly (18) also includes a threaded cap (1804), a first connecting rod (1805), and a second connecting rod (1806). The internal thread of the connecting plate (1803) is threaded with the first connecting rod (1805), the top of the first connecting rod (1805) is threaded with the cap (1804), and the internal thread of the first connecting rod (1805) is threaded with the second connecting rod (1806).

2. The anti-tipping concrete pouring equipment according to claim 1, characterized in that: The tubing coil (23) is provided in two sets, one set of which is threadedly connected to the infusion conduit (26).

3. The anti-tipping concrete pouring equipment according to claim 1, characterized in that: The first support plate (1) forms a sliding structure with the horizontal plate (25) through the slider, and the first support plate (1) has the same structure as the second support plate (201).

4. The anti-tipping concrete pouring equipment according to claim 1, characterized in that: The hopper (3) forms a sliding structure with the longitudinal plate (8) and the slide rail (9) through the slider, and the longitudinal plate (8) is provided with two sets.

5. The anti-tipping concrete pouring equipment according to claim 1, characterized in that: The longitudinal plate (8) and the transverse plate (25) are vertically distributed, and the longitudinal plate (8) and the auxiliary frame (10) are an integrated structure.

6. The anti-tipping concrete pouring equipment according to claim 1, characterized in that: One end of the auxiliary frame (10) is slidably connected to the extension plate (19), and the auxiliary frame (10) has a hollow structure.

7. The anti-tipping concrete pouring equipment according to claim 1, characterized in that: The hopper (3) is equipped with arc-shaped plates (14) at the four corners of its exterior, and the hopper (3) and the arc-shaped plates (14) are integrated into one structure.