Concrete hexagonal block revetment laying slide device

By designing a concrete hexagonal block slope protection paving track device, and utilizing concave slide plates and push plate components to achieve efficient transportation and precise positioning, the problem of difficult manual handling and high mechanization costs in traditional paving methods has been solved, thereby improving paving efficiency and reducing the risk of damage.

CN224338270UActive Publication Date: 2026-06-09HUBEI SHUIZONG WATER RESOURCES & HYDROPOWER CONSTR CO

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
HUBEI SHUIZONG WATER RESOURCES & HYDROPOWER CONSTR CO
Filing Date
2025-07-22
Publication Date
2026-06-09

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Abstract

This utility model discloses a concrete hexagonal block slope protection paving track device, including a concave slide plate for conveying concrete hexagonal blocks. A deceleration plate is provided on the inner wall of the groove of the concave slide plate. The deceleration plate is connected to the concave slide plate via a rotating shaft. An arc-shaped telescopic rod is hinged to the deceleration plate. Support platforms are provided above and below the concave slide plate. Universal wheels are provided under the support platforms. A laterally movable push plate is provided on the support platforms, and a bidirectional screw is provided under the push plate. This utility model, through the concave slide plate and support plates, facilitates the sliding of hexagonal blocks to the bottom of the slope. The elastic deceleration plate on the inner wall of the concave slide plate facilitates the deceleration of the sliding hexagonal blocks. The push plate facilitates the movement of stationary hexagonal blocks and their removal from the concave slide plate. The paving personnel only need to push the machine and check the hexagonal blocks, increasing the efficiency of laying concrete hexagonal blocks for slope protection.
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Description

Technical Field

[0001] This utility model relates to the field of slope protection technology, specifically to a concrete hexagonal block slope protection paving track device. Background Technology

[0002] Hexagonal slope protection bricks are regular hexagonal slope protection bricks made from ordinary concrete. They are divided into hollow and solid types. The products achieve tight interlocking of blocks through an interlocking structure. The modular design improves construction efficiency. They are mainly used in highway slopes, river embankments and other scenarios. Combined with vegetation planting, they achieve soil and water conservation and ecological protection. They have the characteristics of high compressive strength and excellent erosion resistance.

[0003] Traditional construction methods mainly rely on manual handling and laying or simple chutes for installation. Manual handling requires multiple people to work together, and a single piece usually weighs tens or hundreds of kilograms. Moving on slopes is difficult, and the average daily laying volume is less than 100 square meters, which is difficult to meet the progress requirements of large-scale projects. Mechanized solutions mostly use large hoisting equipment with special clamps, and the equipment investment cost accounts for a high proportion of the total project cost. Therefore, there is an urgent need to develop a special laying device that combines efficient transportation, precise positioning, safety and reliability with controllable cost. Utility Model Content

[0004] The purpose of this invention is to provide a concrete hexagonal block slope protection paving track device to solve the problems mentioned in the background art.

[0005] To achieve the above objectives, this utility model provides the following technical solution: a concrete hexagonal block slope protection paving track device, comprising a concave sliding plate for conveying concrete hexagonal blocks, a speed reduction plate provided on the inner side wall of the groove of the concave sliding plate, the speed reduction plate being connected to the concave sliding plate via a rotating shaft, an arc-shaped telescopic rod hinged to the speed reduction plate, support platforms provided above and below the concave sliding plate, universal wheels provided under the support platforms, a laterally movable push plate provided on the support platforms, a bidirectional screw provided under the push plate, a forward and reverse motor provided at the end of the bidirectional screw, a square hole provided on the side of the concave sliding plate, and a vertically movable baffle provided on the top wall of the square hole, an electric telescopic rod provided on the baffle.

[0006] Based on the above technical solution, the present invention can be further improved as follows.

[0007] Preferably, a strong spring is installed inside the arc-shaped telescopic rod, and a pull cable is installed at the telescopic end of the arc-shaped telescopic rod. The end of the pull cable penetrates the inner wall of the concave sliding plate, and the trajectory of the pull cable inside the concave sliding plate is S-shaped. The end of the pull cable away from the arc-shaped telescopic rod is connected to a winding reel. A drive motor is installed behind the winding reel, and pull cables are installed inside multiple arc-shaped telescopic rods. Multiple pull cables are connected to the winding reel. By setting pull cables, multiple pull cables drive multiple arc-shaped telescopic rods to telescopic. At the same time, the drive motor and the winding reel provide power to the pull cables. When the motor starts and rotates forward, it pulls the pull cables. When the motor stops, the output shaft of the motor rotates and releases the pull cables. When the pull cables can no longer pull the output shaft to rotate, the motor reverses and assists the pull cables to return to the normal state.

[0008] Preferably, seven speed reduction plates are vertically and equidistantly arranged on the inner sidewall of the concave sliding plate, and the speed reduction plates are provided with a rubber layer. By setting multiple speed reduction plates, it is convenient to buffer the concrete hexagonal blocks sliding down from above, reduce the falling speed of the hexagonal blocks, and make the hexagonal blocks slide slowly to the bottom. When the hexagonal blocks stop on the concave sliding plate, the drive motor is started, which starts rapidly and intermittently to hinder and reduce the sliding speed of multiple hexagonal blocks.

[0009] Preferably, the push plate is located below the deceleration plate and is slidably connected to the inner surface of the concave slide plate. Two push plates with the same surface as the support platform are equally spaced on the inner wall of the concave slide plate. The push plate is T-shaped, and both the concave slide plate and the support platform are provided with grooves for lateral movement of the push plate. By setting the laterally moving push plate, it is convenient to start the forward and reverse motor when the hexagonal blocks are tilted and stopped, so that the motor drives the push plate to move through the bidirectional screw, and the push plate drives the hexagonal blocks to move laterally, so that the hexagonal blocks are moved out of the concave slide plate.

[0010] Preferably, both the forward and reverse motors and the drive motor are connected to the concave slide plate through a motor cover, and both the forward and reverse motors and the drive motor are connected to a battery and a controller. By setting the forward and reverse motors and the drive motor, it is convenient to provide power to the components inside the slide device of the hexagonal block.

[0011] Preferably, the inner top wall of the square hole on the side of the concave sliding plate is provided with a storage groove that is compatible with the baffle and the electric telescopic rod, and the top of the electric telescopic rod is fixedly connected to the storage groove. By setting a movable baffle, it is convenient to close the outlet when the hexagonal block slides down and open the outlet when the hexagonal block moves laterally, thereby increasing the efficiency of slope protection paving.

[0012] Preferably, the end of the arc-shaped telescopic rod away from the speed reducer is connected to the inner wall of the concave sliding plate. By setting the arc-shaped telescopic rod, it is convenient to provide support for the speed reducer and also increase the buffer space of the speed reducer.

[0013] Beneficial effects

[0014] Compared with the prior art, the technical solution of this application has the following beneficial technical effects:

[0015] This invention utilizes a concave sliding plate and a supporting plate to facilitate the sliding of concrete hexagonal blocks to the bottom of the slope, making it convenient to use. Simultaneously, an elastic deceleration plate on the inner wall of the concave sliding plate slows down the sliding hexagonal blocks, reducing the probability of collision damage during the fall. A push plate facilitates the movement of stationary hexagonal blocks, removing them from the concave sliding plate. The installation personnel only need to push the machine and check the hexagonal blocks, increasing the efficiency of laying concrete hexagonal blocks for slope protection. Attached Figure Description

[0016] Figure 1 This is a schematic diagram of the orthographic section of the present invention;

[0017] Figure 2 This is a top-section structural diagram of the present invention;

[0018] Figure 3 for Figure 1 Enlarged structural diagram at point A in the middle;

[0019] Figure 4 This is a side view of the structure of this utility model;

[0020] Figure 5 This is a three-dimensional structural diagram of the present invention.

[0021] In the diagram: 1. Concave sliding plate; 2. Speed ​​reducer; 3. Arc telescopic rod; 4. Support platform; 5. Caster wheel; 6. Push plate; 7. Two-way screw; 8. Forward and reverse motor; 9. Square hole; 10. Baffle; 11. Electric telescopic rod; 12. Strong spring; 13. Pull cable; 14. Cable reel; 15. Drive motor; 16. Slide. Detailed Implementation

[0022] The technical solutions of the present utility model will be clearly and completely described below with reference to the accompanying drawings of the embodiments. Obviously, the described embodiments are only some embodiments of the present utility model, and not all embodiments. Based on the embodiments of the present utility model, all other embodiments obtained by those of ordinary skill in the art without creative effort are within the protection scope of the present utility model.

[0023] Please see Figures 1-5This utility model provides a technical solution: a concrete hexagonal block slope protection paving track device, including a concave slide plate 1 for conveying concrete hexagonal blocks. The inner sidewall of the concave slide plate 1 is provided with a deceleration plate 2. Seven deceleration plates 2 are vertically and equally spaced on the inner sidewall of the concave slide plate 1, and a rubber layer is provided on the deceleration plates 2. By setting multiple deceleration plates 2, it is convenient to buffer the concrete hexagonal blocks sliding down from above, reduce the falling speed of the hexagonal blocks, and make the hexagonal blocks slide slowly to the bottom. When the hexagonal blocks stop on the concave slide plate 1, the drive motor 15 is started, which starts rapidly and intermittently to obstruct and reduce the sliding speed of multiple hexagonal blocks.

[0024] The speed reducer 2 is connected to the concave slide plate 1 via a pivot. The speed reducer 2 is hinged to an arc-shaped telescopic rod 3. A strong spring 12 is installed inside the arc-shaped telescopic rod 3, and a pull cable 13 is installed at the telescopic end of the arc-shaped telescopic rod 3. The end of the pull cable 13 penetrates the inner wall of the concave slide plate 1, and the trajectory of the pull cable 13 inside the concave slide plate 1 is S-shaped. A winding reel 14 is connected to the end of the pull cable 13 away from the arc-shaped telescopic rod 3. A drive motor 15 is installed behind the winding reel 14, and multiple... Each of the arc-shaped telescopic rods 3 is equipped with a pull wire 13, and multiple pull wires 13 are connected to a winding reel 14. By setting the pull wires 13, multiple pull wires 13 can drive multiple arc-shaped telescopic rods 3 to extend and retract. At the same time, the drive motor 15 and the winding reel 14 provide power to the pull wires 13. When the motor starts and rotates forward, it pulls the pull wires 13. When the motor stops, the output shaft of the motor rotates and releases the pull wires 13. When the pull wires 13 can no longer pull the output shaft to rotate, the motor reverses and assists the pull wires 13 to return to the normal state.

[0025] The concave slide plate 1 is provided with support platforms 4 at both the top and bottom. Universal wheels 5 are provided under the support platforms 4. A push plate 6 that moves laterally is provided on the support platforms 4. The push plate 6 is located below the deceleration plate 2 and is slidably connected to the inner surface of the concave slide plate 1. Two push plates 6 with the same surface as the support platforms 4 are provided at equal intervals on the inner wall of the concave slide plate 1. The push plate 6 is T-shaped. Both the concave slide plate 1 and the support platforms 4 are provided with sliding grooves 16 that move laterally with the push plate 6. By providing the push plate 6 that moves laterally, it is convenient to start the forward and reverse motor 8 when the hexagonal blocks are tilted and stopped. The motor 8 drives the push plate 6 to move through the bidirectional screw 7, and the push plate 6 drives the hexagonal blocks to move laterally, so that the hexagonal blocks are removed from the concave slide plate 1.

[0026] A bidirectional screw 7 is provided under the push plate 6. A forward and reverse motor 8 is provided at the end of the bidirectional screw 7. The forward and reverse motor 8 and the drive motor 15 are both connected to the concave slide plate 1 through a motor cover. The forward and reverse motor 8 and the drive motor 15 are both connected to a battery and a controller. By setting the forward and reverse motor 8 and the drive motor 15, it is convenient to provide power to the components inside the slide device of the hexagonal block.

[0027] The concave sliding plate 1 has a square hole 9 on its side, and a vertically movable baffle 10 is provided on the top wall of the square hole 9. An electric telescopic rod 11 is provided on the baffle 10. The top wall of the square hole 9 on the side of the concave sliding plate 1 has a storage groove that matches the baffle 10 and the electric telescopic rod 11. The top of the electric telescopic rod 11 is fixedly connected to the storage groove. By setting the movable baffle 10, it is convenient to close the exit when the hexagonal block slides down and open the exit when the hexagonal block moves laterally, thereby increasing the efficiency of slope protection paving. The end of the arc telescopic rod 3 away from the deceleration plate 2 is connected to the inner wall of the concave sliding plate 1. By setting the arc telescopic rod 3, it is convenient to provide support for the deceleration plate 2 and also increase the buffer space of the deceleration plate 2.

[0028] In this embodiment, the concave sliding plate 1 and the supporting plate facilitate the sliding of the concrete hexagonal blocks to the bottom of the slope, making it convenient to use. At the same time, the elastic deceleration plate 2 installed on the inner wall of the concave sliding plate 1 helps to slow down the sliding hexagonal blocks and reduce the probability of collision damage during the sliding. The push plate 6 facilitates the movement of the stationary hexagonal blocks and their removal from the concave sliding plate 1. The laying personnel only need to push the machine and check the hexagonal blocks, which increases the efficiency of laying the concrete hexagonal blocks for the slope.

[0029] The mechanisms, components, and parts in this utility model that are not specifically described are all existing structures that already exist in the prior art and can be purchased directly from the market.

[0030] Although embodiments of the present invention have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made to these embodiments without departing from the principles and spirit of the present invention, the scope of which is defined by the appended claims and their equivalents.

Claims

1. A concrete hexagonal block slope protection paving track device, characterized in that: The concave slide plate (1) is used for conveying hexagonal concrete blocks. A speed reduction plate (2) is provided on the inner wall of the groove of the concave slide plate (1). The speed reduction plate (2) is connected to the concave slide plate (1) by a rotating shaft. An arc telescopic rod (3) is hinged to the speed reduction plate (2). Support platforms (4) are provided on both the top and bottom of the concave slide plate (1). Universal wheels (5) are provided under the support platforms (4). A push plate (6) that moves laterally is provided on the support platforms (4). A bidirectional screw (7) is provided under the push plate (6). A forward and reverse motor (8) is provided at the end of the bidirectional screw (7). A square hole (9) is opened on the side of the concave slide plate (1). A vertically movable baffle (10) is provided on the top wall of the square hole (9). An electric telescopic rod (11) is provided on the baffle (10).

2. The concrete hexagonal block slope protection paving track device according to claim 1, characterized in that: The arc telescopic rod (3) is equipped with a strong spring (12) inside, and the telescopic end of the arc telescopic rod (3) is equipped with a pull line (13). The end of the pull line (13) penetrates the inner wall of the concave slide plate (1), and the trajectory of the pull line (13) inside the concave slide plate (1) is S-shaped.

3. The concrete hexagonal block slope protection paving track device according to claim 2, characterized in that: The end of the pull wire (13) away from the arc telescopic rod (3) is connected to a reel (14), and a drive motor (15) is provided behind the reel (14).

4. The concrete hexagonal block slope protection paving track device according to claim 1, characterized in that: The concave sliding plate (1) has seven speed reduction plates (2) arranged vertically and at equal intervals on its inner sidewall, and the speed reduction plates (2) are provided with a rubber layer.

5. The concrete hexagonal block slope protection paving track device according to claim 1, characterized in that: The push plate (6) is located below the deceleration plate (2), and the push plate (6) is slidably connected to the inner surface of the concave slide plate (1). Two push plates (6) with the same surface as the support platform (4) are arranged at equal intervals on the inner wall of the concave slide plate (1).

6. The concrete hexagonal block slope protection paving track device according to claim 1, characterized in that: The push plate (6) is T-shaped, and both the concave slide plate (1) and the support platform (4) are provided with grooves (16) that move laterally with the push plate (6).

7. The concrete hexagonal block slope protection paving track device according to claim 1, characterized in that: The forward and reverse motor (8) and the drive motor (15) are both connected to the concave slide plate (1) through the motor cover, and both the forward and reverse motor (8) and the drive motor (15) are connected to a battery and a controller.

8. The concrete hexagonal block slope protection paving track device according to claim 1, characterized in that: The inner top wall of the square hole (9) on the side of the concave sliding plate (1) is provided with a storage groove that is compatible with the baffle (10) and the electric telescopic rod (11), and the top end of the electric telescopic rod (11) is fixedly connected to the storage groove.

9. A concrete hexagonal block slope protection paving track device according to claim 1, characterized in that: The end of the arc telescopic rod (3) away from the deceleration plate (2) is connected to the inner wall of the concave slide plate (1), and each of the multiple arc telescopic rods (3) is provided with a pull wire (13), and each of the multiple pull wires (13) is connected to the winding reel (14).