A pouring construction equipment suitable for large area concrete ground

By designing automated pouring and construction equipment, the problem of relying on manual cutting machines for opening large areas of concrete ground has been solved, realizing automated opening and smoothing, improving construction efficiency and quality, and meeting the high efficiency requirements of modern buildings.

CN122148037APending Publication Date: 2026-06-05SHANXI CONSTR ENG CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Applications(China)
Current Assignee / Owner
SHANXI CONSTR ENG CO LTD
Filing Date
2026-04-22
Publication Date
2026-06-05

AI Technical Summary

Technical Problem

In existing technologies, the methods for creating large-area concrete floor joints mainly rely on manual cutting machines, which results in high labor intensity, long construction time, low efficiency, and difficulty in ensuring the quality of the joints.

Method used

A pouring construction device suitable for large-area concrete surfaces was designed. It adopts an automated pushing trolley, clamping mechanism, membrane welding and cutting mechanism and concrete leveling mechanism to realize automatic plate insertion, material collection and concrete leveling, reduce manual intervention and improve construction efficiency and cutting accuracy.

Benefits of technology

It enables automated jointing and leveling of large-area concrete floors, reduces manpower input, improves construction efficiency and joint cutting quality, avoids errors caused by manual operation, and meets the high-quality and high-efficiency requirements of modern construction projects.

✦ Generated by Eureka AI based on patent content.

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Abstract

The application discloses a pouring construction equipment suitable for large-area concrete ground surfaces and relates to the field of concrete ground pouring. The pouring construction equipment suitable for large-area concrete ground surfaces comprises a pushing trolley, the top of the pushing trolley is fixedly connected with a mounting frame, and the mounting frame is provided with a moving mechanism, a first driving mechanism and a pushing plate. The pouring construction equipment is characterized in that the moving mechanism, the first driving mechanism and the pushing plate work cooperatively, the baffle body in the feeding box is automatically pushed out through the pushing plate, the baffle is wrapped with the plastic film on the plastic film roll and then inserted into the concrete ground surface, the plastic film is welded and cut off through the film welding and cutting mechanism, and automatic slotting is completed. After preliminary solidification of the subsequent concrete, the equipment can automatically collect the baffle into the feeding box, so that the equipment is convenient for cleaning and next use. The process does not need subsequent manual slotting, labor input and construction time are reduced, errors and non-standard problems possibly caused by manual slotting are avoided, the precision and quality of slotting are improved, and the overall efficiency of large-area concrete pouring is improved.
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Description

Technical Field

[0001] This invention relates to concrete floor pouring technology, specifically to a pouring construction equipment suitable for large-area concrete floors. Background Technology

[0002] In recent years, with the rapid development of my country's economy, the construction industry has shown a booming trend. Buildings with extra-long and extra-wide floor plans have been increasingly widely used in many fields such as large public buildings, industrial plants, and commercial centers. As an important component of buildings, the ground plays multiple key roles, not only undertaking the basic functions of dividing space and protecting the structure, but also having a significant impact on beautifying the interior environment and meeting usage requirements.

[0003] Concrete cracking has always been a major challenge in the construction of large-area concrete floor structures, hindering project quality. Concrete shrinkage deformation is the primary cause of these cracks. When concrete shrinks, tensile stress is generated internally. Once this stress exceeds the concrete's tensile strength, cracks will form. These cracks not only affect the aesthetics of the floor and reduce the overall quality of the building, but may also pose a potential threat to the building's structural safety and functionality.

[0004] To effectively control crack formation, it is usually necessary to perform expansion joint treatment on large-area concrete floors after pouring. The purpose of expansion joints is to release the stress caused by concrete shrinkage, thereby reducing cracking. Currently, most existing expansion joint methods involve manually pushing a cutting machine to cut the joints in the poured concrete. However, this method has many drawbacks. Manually operating the cutting machine is not only labor-intensive, requiring a large investment of manpower, but also time-consuming and inefficient. Furthermore, manual cutting is prone to errors; the depth, width, and straightness of the cuts are difficult to guarantee according to specifications, thus affecting the quality and effect of the expansion joint treatment. This fails to effectively solve the problem of cracks caused by shrinkage deformation in large-area concrete floors and cannot meet the demands of modern construction projects for high-quality and high-efficiency construction. Therefore, developing a construction device that can automatically, efficiently, and accurately perform expansion joint treatment on large-area concrete floors is of significant practical importance. Summary of the Invention

[0005] The purpose of this invention is to provide a pouring construction device suitable for large-area concrete floors, solving the problem that most existing methods of cutting joints involve manually pushing a cutting machine to cut joints in the poured floor. However, this method has many drawbacks. Manually operating the cutting machine is not only labor-intensive and requires a large investment of manpower, but also time-consuming and inefficient.

[0006] To achieve the above objectives, the present invention provides the following technical solution: a pouring construction equipment suitable for large-area concrete surfaces, comprising a push trolley, a mounting frame fixedly connected to the top of the push trolley, a transmission plate slidably connected inside the mounting frame, a moving mechanism connected to the mounting frame on the transmission plate, the moving mechanism driving the transmission plate to move, a mounting shaft rotatably connected to the transmission plate, a first driving mechanism connected to the transmission plate and driven to the outer surface of the mounting shaft, the first driving mechanism driving the mounting shaft to rotate, a mounting plate fixedly connected to the bottom end of the mounting shaft, a first telescopic drive member fixedly connected to the bottom of the mounting plate, a mounting box fixedly connected to the output end of the first telescopic drive member, a second telescopic drive member fixedly connected inside the mounting box, a clamping box fixedly connected to the output end of the second telescopic drive member, a clamping mechanism provided on the clamping box for clamping and fixing partitions, a plate supply mechanism fixedly connected to one side of the mounting box for supplying material to the partitions, and plastic film rolls rotatably connected to both sides of the mounting box;

[0007] The bottom of the mounting box is provided with a connecting frame, and a film welding and cutting mechanism is provided inside the connecting frame. The film welding and cutting mechanism is used to cut the film. The bottom of the mounting plate is provided with a concrete leveling mechanism, which is used to level the concrete.

[0008] Furthermore, the clamping mechanism includes a third telescopic drive member fixedly connected to the clamping box. The output end of the third telescopic drive member is fixedly connected to a sliding plate slidably connected to the clamping box. A plurality of transmission racks are fixedly connected to one side of the sliding plate. A transmission gear is meshed with one side of the transmission racks. A first transmission shaft rotatably connected to the clamping box is fixedly sleeved in the middle of the transmission gear. A first bevel gear is fixedly sleeved at the bottom end of the first transmission shaft. A second bevel gear is meshed with the outer surface of the first bevel gear. A bidirectional threaded rod is fixedly sleeved in the middle of the second bevel gear. Two clamping plates are threadedly fitted on the outer surface of the bidirectional threaded rod.

[0009] Furthermore, the feeding mechanism includes a feeding box fixedly connected to the clamping box, a fourth telescopic drive member fixedly connected to one side of the feeding box, a push plate slidably connected to the output end of the fourth telescopic drive member, a plurality of partition bodies are provided inside the feeding box, a permanent magnet block is fixedly connected to the partition body, and an iron plate is provided on the partition body.

[0010] Furthermore, the thin film welding and cutting mechanism includes a fifth telescopic drive member fixedly connected within the connecting frame, an electric welding plate fixedly connected to the output end of the fifth telescopic drive member, a first rotation drive member fixedly connected within the connecting frame, a first threaded rod rotatably connected to the output end of the first rotation drive member, a transmission block threadedly fitted on the outer surface of the first threaded rod, a guide rod fixedly connected to the connecting frame slidably connected to the transmission block, a sixth telescopic drive member fixedly connected to one side of the transmission block, and a cutter fixedly connected to the output end of the sixth telescopic drive member.

[0011] Furthermore, the moving mechanism includes a second rotation drive member fixedly connected to the mounting bracket, the output end of the second rotation drive member being fixedly connected to a second threaded rod rotatably connected to the mounting bracket, the outer surface of the second threaded rod being threadedly engaged with a transmission plate, and a guide rod fixedly connected to the mounting bracket being slidably connected to the transmission plate.

[0012] Furthermore, the first driving mechanism includes a third rotational driving component fixedly connected to the transmission plate. The output end of the third rotational driving component is fixedly connected to a drive shaft. A first gear is fixedly sleeved on the outer surface of the drive shaft. A second gear fixedly sleeved on the outer surface of the first gear is meshed with the mounting shaft.

[0013] Furthermore, the concrete leveling mechanism includes a seventh telescopic drive component fixedly connected to the mounting plate. The output end of the seventh telescopic drive component is fixedly connected to a second connecting plate. A transmission frame is slidably connected to the second connecting plate. An eighth telescopic drive component fixedly connected to the second connecting plate is fixedly connected inside the transmission frame. Multiple vibrating rod devices are fixedly connected to the second connecting plate. A telescopic rod is fixedly connected to the bottom of the transmission frame. A leveling plate is fixedly connected to the bottom of the telescopic rod. A spring fixedly sleeved on the outer surface of the telescopic rod and fixedly connected to one side of the leveling plate is fixedly connected to the leveling plate. A vibrating motor is fixedly connected to the leveling plate.

[0014] Furthermore, a flat arc-shaped plate is fixedly connected to the bottom of the second connecting plate.

[0015] Compared with the prior art, the pouring construction equipment for large-area concrete surfaces provided by the present invention has the following beneficial effects:

[0016] This concrete pouring equipment features automatic plate insertion and material collection functions, enabling automatic grouting of large-area concrete surfaces. After the concrete is leveled, the equipment, through the coordinated operation of a moving mechanism and a primary drive mechanism, automatically pushes out the main body of the partition plate from the supply box via a pusher plate. The partition plate is then wrapped with a plastic film roll and inserted into the concrete surface. A film welding and cutting mechanism then welds and cuts the film, completing the automatic grouting. After the concrete has initially solidified, the equipment can automatically retract the partition plate into the supply box for easy cleaning and future use. This process eliminates the need for subsequent manual grouting, reducing labor input and construction time, avoiding potential errors and non-standard practices associated with manual grouting, improving the accuracy and quality of grouting, and thus enhancing the overall efficiency of large-area concrete pouring.

[0017] This equipment excels in concrete leveling, boasting highly efficient automation. The seventh telescopic drive component moves and rotates the leveling arc-shaped plate, quickly performing initial leveling of the poured concrete. The eighth telescopic drive component inserts a vibrating rod into the concrete, effectively improving concrete density, eliminating air bubbles, and enhancing structural performance. Simultaneously, the leveling plate vibrates under the drive of a vibrating motor, further refining the leveling process. This multi-stage, coordinated automated leveling method simulates meticulous manual operation but is more efficient and produces more consistent results, enabling automated, high-quality leveling of concrete surfaces and significantly improving the efficiency and quality of large-area concrete pouring. Attached Figure Description

[0018] To more clearly illustrate the technical solutions in the embodiments of this application or the prior art, the drawings used in the embodiments will be briefly introduced below. Obviously, the drawings described below are only some embodiments recorded in this invention. For those skilled in the art, other drawings can be obtained based on these drawings.

[0019] Figure 1 This is a first perspective view of the external structure of the present invention;

[0020] Figure 2 This is a second perspective view of the external structure of the present invention;

[0021] Figure 3 This is a third perspective view of the external structure of the present invention;

[0022] Figure 4 This is a perspective view of the internal structure of the mounting box, clamping box, and feeding box of the present invention.

[0023] Figure 5 This is a perspective view of the internal structure of the mounting box of the present invention;

[0024] Figure 6 For the present invention Figure 1 Enlarged view of A in the middle;

[0025] Figure 7 For the present invention Figure 2 Enlarged view of B in the middle;

[0026] Figure 8 For the present invention Figure 3 Enlarged view of C;

[0027] Figure 9 For the present invention Figure 4 Enlarged view of D;

[0028] Figure 10 For the present invention Figure 5 A magnified view of E in the middle.

[0029] Explanation of reference numerals in the attached figures:

[0030] 1. Push trolley; 2. Mounting frame; 3. Transmission plate; 4. Mounting shaft; 5. Mounting plate; 6. First telescopic drive component; 7. Mounting box; 8. Second telescopic drive component; 9. Clamping box; 10. Plastic film roll; 11. Connecting frame; 21. Third telescopic drive component; 22. Sliding plate; 23. Transmission rack; 24. Transmission gear; 25. First transmission shaft; 26. First bevel gear; 27. Second bevel gear; 28. Bidirectional threaded rod; 29. ​​Clamping plate; 31. Feeding box; 32. Fourth telescopic drive component; 33. Push plate; 34. Partition body; 35. Permanent magnet block; 41. 42. Electric welding plate; 43. First rotating drive component; 44. First threaded rod; 45. Transmission block; 46. Sixth telescopic drive component; 47. Cutting knife; 51. Second rotating drive component; 52. Second threaded rod; 61. Third rotating drive component; 62. Drive shaft; 63. First gear; 64. Second gear; 71. Seventh telescopic drive component; 72. Second connecting plate; 73. Transmission frame; 74. Eighth telescopic drive component; 75. Vibrating rod device; 76. Telescopic rod; 77. Flat plate; 78. Spring; 79. Vibration motor; 790. Flat arc plate. Detailed Implementation

[0031] To enable those skilled in the art to better understand the technical solution of the present invention, the present invention will be further described in detail below with reference to the accompanying drawings.

[0032] Example 1

[0033] Please see Figures 1 to 10As shown, this invention provides a pouring construction device suitable for large-area concrete surfaces, including a push trolley 1. A mounting frame 2 is fixedly connected to the top of the push trolley 1. A transmission plate 3 is slidably connected inside the mounting frame 2. A moving mechanism connected to the mounting frame 2 is provided on the transmission plate 3, which drives the transmission plate 3 to move. A mounting shaft 4 is rotatably connected to the transmission plate 3. A first driving mechanism connected to the transmission plate 3 is connected to the outer surface of the mounting shaft 4, which drives the mounting shaft 4 to rotate. A mounting plate 5 is fixedly connected to the bottom end of the mounting shaft 4. The bottom of the mounting plate 5 is fixed... A first telescopic drive component 6 is connected, which is an electric telescopic rod and an electric hydraulic rod. The output end of the first telescopic drive component 6 is fixedly connected to a mounting box 7. A second telescopic drive component 8 is fixedly connected inside the mounting box 7. The second telescopic drive component 8 is an electric telescopic rod and an electric hydraulic rod. The output end of the second telescopic drive component 8 is fixedly connected to a clamping box 9. A clamping mechanism is provided on the clamping box 9. The clamping mechanism is used to clamp and fix the partition. A plate feeding mechanism is fixedly connected to one side of the mounting box 7. The plate feeding mechanism is used to feed material to the partition. Plastic film rolls 10 are rotatably connected to both sides of the mounting box 7.

[0034] The bottom of the mounting box 7 is provided with a connecting frame 11, and a film welding and cutting mechanism is provided inside the connecting frame 11. The film welding and cutting mechanism is used to cut the film. The bottom of the mounting plate 5 is provided with a concrete leveling mechanism, which is used to level the concrete.

[0035] The clamping mechanism includes a third telescopic drive component 21 fixedly connected to the clamping box 9. The third telescopic drive component 21 is an electric telescopic rod and an electric hydraulic rod. The output end of the third telescopic drive component 21 is fixedly connected to a sliding plate 22 that is slidably connected to the clamping box 9. A plurality of transmission racks 23 are fixedly connected to one side of the sliding plate 22. A transmission gear 24 is meshed with one side of the transmission rack 23. A first transmission shaft 25 that is rotatably connected to the clamping box 9 is fixedly sleeved in the middle of the transmission gear 24. A first bevel gear 26 is fixedly sleeved at the bottom end of the first transmission shaft 25. A second bevel gear 27 is meshed with the outer surface of the first bevel gear 26. A bidirectional threaded rod 28 is fixedly sleeved in the middle of the second bevel gear 27. Two clamping plates 29 are threadedly fitted on the outer surface of the bidirectional threaded rod 28.

[0036] The feeding mechanism includes a feeding box 31 fixedly connected to the clamping box 9. A fourth telescopic drive member 32 is fixedly connected to one side of the feeding box 31. The fourth telescopic drive member 32 is an electric telescopic rod and an electric hydraulic rod. A push plate 33 slidably connected to the output end of the fourth telescopic drive member 32 is fixedly connected to the feeding box 31. Multiple partition bodies 34 are provided inside the feeding box 31. Permanent magnet blocks 35 are fixedly connected to the partition bodies 34. Iron plates are provided on the partition bodies 34. By placing multiple partition bodies 34 together, the permanent magnet blocks 35 on the multiple partition bodies 34 attract the iron plates on the partition bodies 34, causing the partition bodies 34 to attract together. At the same time, the permanent magnet blocks 35 on the partition bodies 34 connected to the push plate 33 are attracted to the push plate 33.

[0037] The film welding and cutting mechanism includes a fifth telescopic drive member 41 fixedly connected within the connecting frame 11. The fifth telescopic drive member 41 is an electric telescopic rod and an electro-hydraulic rod. An electric welding plate 42 is fixedly connected to the output end of the fifth telescopic drive member 41. A first rotation drive member 43 is fixedly connected within the connecting frame 11. The first rotation drive member 43 is a servo motor. The servo motor is controlled by a PLC programming program, which can control the servo motor to rotate forward and backward and the rotation angle. A first threaded rod 44 rotatably connected to the output end of the first rotation drive member 43 is fixedly connected to the connecting frame 11. A transmission block 45 is threadedly fitted on the outer surface of the first threaded rod 44. A guide rod fixedly connected to the connecting frame 11 is slidably connected to the transmission block 45. A sixth telescopic drive member 46 is fixedly connected to one side of the transmission block 45. The sixth telescopic drive member 46 is an electric telescopic rod and an electro-hydraulic rod. A cutter 47 is fixedly connected to the output end of the sixth telescopic drive member 46.

[0038] The moving mechanism includes a second rotation drive 51 fixedly connected to the mounting bracket 2. The second rotation drive 51 is a servo motor, which is controlled by a PLC programming program. The servo motor can be controlled to rotate forward and backward and rotate at different angles. The output end of the second rotation drive 51 is fixedly connected to a second threaded rod 52 rotatably connected to the mounting bracket 2. The outer surface of the second threaded rod 52 is threadedly engaged with the transmission plate 3. A guide rod fixedly connected to the mounting bracket 2 is slidably connected to the transmission plate 3. The second rotation drive 51 drives the second threaded rod 52 to rotate, and the second threaded rod 52 drives the transmission plate 3 to move.

[0039] The first drive mechanism includes a third rotation drive component 61 fixedly connected to the transmission plate 3. The third rotation drive component 61 is a servo motor, which is controlled by a PLC programming program. The servo motor can be controlled to rotate forward and backward and rotate at different angles. The output end of the third rotation drive component 61 is fixedly connected to a drive shaft 62. A first gear 63 is fixedly sleeved on the outer surface of the drive shaft 62. A second gear 64 is fixedly sleeved on the outer surface of the first gear 63. The third rotation drive component 61 drives the drive shaft 62 to rotate, and the drive shaft 62 drives the mounting shaft 4 to rotate through the first gear 63 and the second gear 64.

[0040] First, concrete is evenly poured onto the surface to be poured using a concrete pouring machine. Then, the trolley 1 is pushed to the side of the surface. A moving mechanism then moves the transmission plate 3, while a first drive mechanism rotates the mounting shaft 4 and mounting plate 5. The mounting plate 5 rotates the concrete leveling mechanism, which in turn moves and rotates the trolley 1, leveling the poured concrete. After leveling, the trolley 1 is moved to a designated position, where the moving mechanism again moves the transmission plate 3, which in turn moves the mounting shaft 4 and mounting plate 5. Simultaneously, a first telescopic drive 6 moves the mounting box 7 downwards, positioning it at... Above the poured ground, the fourth telescopic drive 32 inside the supply box 31 drives the push plate 33 to move, which in turn moves the partition body 34 inside the supply box 31, pushing one partition body 34 into the mounting box 7. Then, the second telescopic drive 8 drives the clamping box 9 downwards, which in turn moves the clamping plate 29 downwards. Next, the third telescopic drive 21 drives the sliding plate 22 to move, which in turn moves the transmission rack 23. The transmission rack 23 then drives the transmission gear 24 and the first transmission shaft 25 to rotate. The first transmission shaft 25, through the first bevel gear 26 and the second bevel gear 27, drives the bidirectional threaded rod 28 to rotate, which in turn moves the clamping plate 29, clamping... Plate 29 clamps and fixes the partition body 34. Then, the second telescopic drive 8 drives the clamping box 9 to move downward. At this time, the clamped partition body 34 is subjected to a downward force, pushing the partition body 34 downward. Then, the partition body 34 is pushed out of the mounting box 7. During the pushing process, the film connected to the two plastic film rolls 10 at the bottom is pushed. At this time, the film wraps the partition body 34, so that the partition body 34 wrapped with film is inserted into the leveled concrete ground, so that it is inserted to one-third of the thickness of the poured concrete. The protection of the film prevents the partition body 34 from solidifying on the concrete ground. Then, the fifth telescopic drive 41 in the connecting frame 11 drives the electric welding plate 42 to move. The four electric welding plates 42 on the upper and lower sides... The films are welded together, and then the first threaded rod 44 is rotated by the first rotating drive 43. The first threaded rod 44 drives the transmission block 45 to move, and at the same time, the sixth telescopic drive 46 on the transmission block 45 drives the cutter 47 to move, so that the cutter 47 cuts the film, which has been welded on both the top and bottom, from the middle. Then the above action is repeated to insert the next partition. After all the partitions are inserted, after the concrete has initially solidified (judged by the staff according to the concrete moisture content), the push trolley 1 is pushed to the designated position, and then the clamping box 9 is moved to the position of the inserted plate. Then the inserted plate is clamped and fixed by the clamping plate 29, and then the inserted plate is moved upward to move into the installation box 7.This then moves the push plate 33, causing the partition body 34 to adhere to it. The next partition body 34 is then adhered to the push plate 33, and this process repeats automatically to collect the partition bodies 34. After collection, the partition body 34 is removed and cleaned by opening the door at the top of the supply box 31 for future use. This achieves automatic joint opening of large-area poured concrete, eliminating the need for subsequent manual jointing and further improving the efficiency of large-area concrete pouring.

[0041] Example 2

[0042] Based on Example 1, please refer to Figure 2 , Figure 3 and Figure 7 As shown, the concrete leveling mechanism includes a seventh telescopic drive component 71 fixedly connected to the mounting plate 5. The seventh telescopic drive component 71 is an electric telescopic rod and an electric hydraulic rod. The output end of the seventh telescopic drive component 71 is fixedly connected to a second connecting plate 72. A transmission frame 73 is slidably connected to the second connecting plate 72. An eighth telescopic drive component 74 fixedly connected to the second connecting plate 72 is fixedly connected inside the transmission frame 73. The eighth telescopic drive component 74 is an electric telescopic rod and an electric hydraulic rod. Multiple vibrating rod devices 75 are fixedly connected to the second connecting plate 72. A telescopic rod 76 is fixedly connected to the bottom of the transmission frame 73. A leveling plate 77 is fixedly connected to the bottom of the telescopic rod 76. A spring 78 fixedly sleeved on the outer surface of the telescopic rod 76 and fixedly connected to one side of the leveling plate 77 is fixedly connected to the leveling plate 77. A vibrating motor 79 is fixedly connected to the leveling plate 77.

[0043] A flat, curved plate 790 is fixedly connected to the bottom of the second connecting plate 72.

[0044] First, concrete is evenly poured onto the surface to be poured using a concrete pouring machine. Then, the trolley 1 is pushed to the side of the surface to be poured. Next, the moving mechanism drives the transmission plate 3 to move, while the first drive mechanism drives the mounting shaft 4 and mounting plate 5 to rotate. The seventh telescopic drive component 71 on the mounting plate 5 drives the second connecting plate 72 to move downwards. The second connecting plate 72 drives the flat arc plate 790 to move, simultaneously moving the transmission plate 3 and, through the first drive mechanism, rotating the mounting shaft 4 and mounting plate 5, thereby causing the flat arc plate 790 to move and rotate. The flat arc plate 790 moves to flatten the poured concrete. Then, the eighth telescopic drive component 74 drives the transmission frame 73 to move downward. The transmission frame 73 drives the vibrator on the vibrator device 75 to insert into the concrete and vibrate it, thereby increasing the concrete density, eliminating air bubbles, improving the concrete structural performance, and enhancing the effect of the poured ground. At the same time, the vibration motor 79 on the flat plate 77 drives the flat plate 77 to vibrate, so that the flat plate 77 flattens the concrete, realizing the automated pouring and flattening of the concrete ground, and further improving the pouring efficiency of the concrete ground.

[0045] The foregoing has only described certain exemplary embodiments of the present invention by way of illustration. Undoubtedly, those skilled in the art can modify the described embodiments in various ways without departing from the spirit and scope of the present invention. Therefore, the foregoing drawings and descriptions are illustrative in nature and should not be construed as limiting the scope of protection of the claims of the present invention.

Claims

1. A pouring and pouring equipment suitable for large-area concrete surfaces, characterized in that, The device includes a pusher trolley (1), a mounting frame (2) fixedly connected to the top of the pusher trolley (1), a transmission plate (3) slidably connected inside the mounting frame (2), a moving mechanism connected to the mounting frame (2) on the transmission plate (3), the moving mechanism being used to drive the transmission plate (3) to move, a mounting shaft (4) rotatably connected to the transmission plate (3), a first drive mechanism connected to the transmission plate (3) being driven to the outer surface of the mounting shaft (4), the first drive mechanism being used to drive the mounting shaft (4) to rotate, and a mounting plate (5) fixedly connected to the bottom end of the mounting shaft (4). The bottom of the mounting plate (5) is fixedly connected to a first telescopic drive member (6), the output end of the first telescopic drive member (6) is fixedly connected to a mounting box (7), the mounting box (7) is fixedly connected to a second telescopic drive member (8), the output end of the second telescopic drive member (8) is fixedly connected to a clamping box (9), the clamping box (9) is provided with a clamping mechanism, the clamping mechanism is used to clamp and fix the partition, one side of the mounting box (7) is fixedly connected to a plate feeding mechanism, the plate feeding mechanism is used to feed the partition, and both sides of the mounting box (7) are rotatably connected to plastic film rolls (10). The bottom of the mounting box (7) is provided with a connecting frame (11), and a film welding and cutting mechanism is provided inside the connecting frame (11). The film welding and cutting mechanism is used to cut the film. The bottom of the mounting plate (5) is provided with a concrete leveling mechanism, which is used to level the concrete.

2. The pouring equipment for large-area concrete pavement as described in claim 1, characterized in that, The clamping mechanism includes a third telescopic drive member (21) fixedly connected to the clamping box (9). The output end of the third telescopic drive member (21) is fixedly connected to a sliding plate (22) slidably connected to the clamping box (9). A plurality of transmission racks (23) are fixedly connected to one side of the sliding plate (22). A transmission gear (24) is meshed with one side of the transmission rack (23). A first transmission shaft (25) rotatably connected to the clamping box (9) is fixedly sleeved in the middle of the transmission gear (24). A first bevel gear (26) is fixedly sleeved at the bottom end of the first transmission shaft (25). A second bevel gear (27) is meshed with the outer surface of the first bevel gear (26). A bidirectional threaded rod (28) is fixedly sleeved in the middle of the second bevel gear (27). Two clamping plates (29) are threadedly fitted on the outer surface of the bidirectional threaded rod (28).

3. The pouring equipment for large-area concrete pavement as described in claim 1, characterized in that, The feeding mechanism includes a feeding box (31) fixedly connected to the clamping box (9). A fourth telescopic drive member (32) is fixedly connected to one side of the feeding box (31). A push plate (33) that is slidably connected to the output end of the fourth telescopic drive member (32) is fixedly connected to the feeding box (31). Multiple partition bodies (34) are provided inside the feeding box (31). Permanent magnet blocks (35) are fixedly connected to the partition bodies (34). Iron plates are provided on the partition bodies (34).

4. The pouring equipment for large-area concrete surfaces according to claim 1, characterized in that, The film welding and cutting mechanism includes a fifth telescopic drive member (41) fixedly connected inside the connecting frame (11). The output end of the fifth telescopic drive member (41) is fixedly connected to an electric welding plate (42). The first rotating drive member (43) is fixedly connected inside the connecting frame (11). The output end of the first rotating drive member (43) is fixedly connected to a first threaded rod (44) rotatably connected to the connecting frame (11). The outer surface of the first threaded rod (44) is threaded with a transmission block (45). The transmission block (45) is slidably connected to a guide rod fixedly connected to the connecting frame (11). A sixth telescopic drive member (46) is fixedly connected to one side of the transmission block (45). The output end of the sixth telescopic drive member (46) is fixedly connected to a cutter (47).

5. The pouring equipment for large-area concrete pavement as described in claim 1, characterized in that, The moving mechanism includes a second rotating drive (51) fixedly connected to the mounting bracket (2). The output end of the second rotating drive (51) is fixedly connected to a second threaded rod (52) rotatably connected to the mounting bracket (2). The outer surface of the second threaded rod (52) is threadedly engaged with the transmission plate (3). A guide rod fixedly connected to the mounting bracket (2) is slidably connected to the transmission plate (3).

6. The pouring equipment for large-area concrete surfaces according to claim 1, characterized in that, The first drive mechanism includes a third rotation drive member (61) fixedly connected to the transmission plate (3). The output end of the third rotation drive member (61) is fixedly connected to a drive shaft (62). A first gear (63) is fixedly sleeved on the outer surface of the drive shaft (62). A second gear (64) is fixedly sleeved on the outer surface of the first gear (63).

7. The pouring equipment for large-area concrete pavement as described in claim 1, characterized in that, The concrete leveling mechanism includes a seventh telescopic drive component (71) fixedly connected to the mounting plate (5). The output end of the seventh telescopic drive component (71) is fixedly connected to a second connecting plate (72). A transmission frame (73) is slidably connected to the second connecting plate (72). An eighth telescopic drive component (74) fixedly connected to the second connecting plate (72) is fixedly connected inside the transmission frame (73). Multiple vibrating rod devices (75) are fixedly connected to the second connecting plate (72). A telescopic rod (76) is fixedly connected to the bottom of the transmission frame (73). A leveling plate (77) is fixedly connected to the bottom of the telescopic rod (76). A spring (78) fixedly connected to one side of the leveling plate (77) is fixedly sleeved on the outer surface of the telescopic rod (76). A vibrating motor (79) is fixedly connected to the leveling plate (77).

8. The pouring equipment for large-area concrete pavement as described in claim 7, characterized in that, The bottom of the second connecting plate (72) is fixedly connected to a flat arc plate (790).