A debris flow blocking protection device

By designing the cleaning and flushing components of the debris flow barrier and protection device, the problem of high maintenance workload for nozzles when multiple nozzles are used in combination has been solved, resulting in a reduction in the number of nozzles and an improvement in cleaning efficiency.

CN224412602UActive Publication Date: 2026-06-26CHONGQING NANDI TECH DEV CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
CHONGQING NANDI TECH DEV CO LTD
Filing Date
2025-05-30
Publication Date
2026-06-26

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Abstract

The utility model relates to the technical field of debris flow protection, specifically relates to a kind of debris flow blocking protection device, including protective retaining wall main part and cleaning component, cleaning component includes metal frame, positioning frame, moving frame, sliding frame, standing plate, pushing component and flushing component, when the slope of protective retaining wall main part and the flow guide groove need to be cleaned, open external water pump to clean water extraction, sliding frame is moved by pushing component, so that flushing component can be moved to clean the slope of protective retaining wall main part, further, when water flow in flow guide groove gathers to a certain extent, mixed sludge therein will be removed, to realize cleaning, flushing component is provided in the application A group can be realized when multiple retaining wall combination is used to clean, subsequent work spray head maintenance quantity will also be significantly reduced, and then work spray head setting structure can be optimized and the number of settings is reduced, when multiple quantity combination is used in retaining wall, the workload of work spray head maintenance can be effectively reduced.
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Description

Technical Field

[0001] This utility model relates to the field of debris flow protection technology, and in particular to a debris flow blocking and protection device. Background Technology

[0002] Existing retaining walls have simple structures, mainly considering the wall's strength and impact resistance, but rarely considering the cleanup of intercepted soil after a debris flow, making it inconvenient to clean up the accumulated silt after a debris flow.

[0003] Existing technology CN221193426U describes a debris flow protection wall that is easy to clean. It includes a main body of the protection wall, a concrete diversion channel, metal baffles, and a high-pressure water pipe. A concrete diversion channel is installed on the lower right side of the main body, and a metal diversion channel is installed at the upper end of the concrete diversion channel. Multiple baffle slots are formed from front to back on the upper right side of the main body, and multiple metal baffles are provided. These metal baffles are movably engaged with the multiple baffle slots via hinges. Multiple storage cavities are formed from front to back on the upper left side of the main body. This design solves the problem that existing protection walls have simple structures and are inconvenient for cleaning up accumulated silt after a debris flow. This utility model is highly practical, employing a combination of high-pressure nozzle impact and diversion channel guidance, which can quickly remove the accumulated silt after a debris flow, thereby reducing the cleaning burden on personnel and facilitating its widespread use.

[0004] However, the applicant found that when using the above-mentioned retaining walls, the retaining walls often need to be used in combination in large quantities. As the number increases, the number of sprinkler heads will increase accordingly, resulting in a huge workload for subsequent sprinkler head maintenance and inconvenience in use. Utility Model Content

[0005] The purpose of this utility model is to provide a debris flow blocking and protection device, which aims to optimize the structure of the working nozzles and reduce the number of nozzles required. When multiple working nozzles are used in combination on retaining walls, the maintenance workload of the working nozzles can be effectively reduced.

[0006] To achieve the above objectives, this utility model provides a debris flow blocking and protection device, including a protective retaining wall body, wherein several casting sections are arranged in a straight line at the bottom of the protective retaining wall body, and a flow guide channel is cast on the front side, and a cleaning component is also included.

[0007] The cleaning assembly includes a metal frame, a positioning frame, a movable frame, a sliding frame, a standing plate, a pushing component, and a rinsing component. The metal frame is cast into the top of the main body of the protective retaining wall. The positioning frame is detachably connected to the metal frame and is located on top of the metal frame. The movable frame is welded to the front side of the positioning frame and is provided with a guide groove. The sliding frame can slide linearly within the guide groove. The standing plate is cast into the rear side of the main body of the protective retaining wall. The pushing component is located behind the sliding frame, and the rinsing component is located in front of the sliding frame.

[0008] A reinforcing plate is cast and installed on the rear side of the main body of the protective retaining wall, and the reinforcing plate is cast and installed on the rear side of the main body of the protective retaining wall and located below the standing plate.

[0009] The pushing component includes a connecting rod and a gripping rod. The connecting rod is threadedly connected to the sliding frame and is located on the rear side of the sliding frame. The gripping rod has anti-slip texture on its surface and is integrally formed with the connecting rod.

[0010] The flushing component includes a water guide pipe and flushing nozzles. The water guide pipe is fixedly connected to the sliding frame and connected to the outlet pipe of an external water supply pump through a movable water pipe. Several flushing nozzles are threadedly connected to the water guide pipe and are disposed at the bottom of the water guide pipe.

[0011] The cleaning component also includes a support plate, which is cast onto the reinforcing plate and is set at an angle, with its highest point abutting below the standing plate.

[0012] This utility model discloses a debris flow blocking and protection device. In use, the main body of the retaining wall is fixed to the ground by a casting section. When cleaning the slope and guide channel of the retaining wall body is required, the flushing component is connected to an external water pump. The sliding part of the sliding frame is then slidably placed in the guide groove of the moving frame, and a pushing component is installed on the sliding frame. The external water pump is then turned on to extract cleaning water, and the pushing component moves the sliding frame, thereby moving the flushing component to clean the slope of the retaining wall body. Furthermore, when the water flow in the guide channel reaches a certain level, it will carry away the mixed silt, thus achieving cleaning. In this application, a single flushing component can be used to clean multiple retaining walls in combination, significantly reducing the number of subsequent working nozzles to be maintained. This optimizes the working nozzle setup structure and reduces the number of nozzles required, effectively reducing the workload of working nozzle maintenance when multiple retaining walls are used in combination. Attached Figure Description

[0013] To more clearly illustrate the technical solutions in the embodiments of this application or the prior art, the accompanying drawings used in the description of the embodiments or the prior art will be briefly introduced below.

[0014] Figure 1 This is a schematic diagram of the overall structure of the debris flow blocking and protection device according to the first embodiment of this utility model.

[0015] Figure 2 This is a left view of the debris flow blocking and protection device according to the first embodiment of this utility model.

[0016] Figure 3 This is a schematic diagram of the overall structure of the debris flow blocking and protection device according to the second embodiment of this utility model.

[0017] In the diagram: 101-Main body of protective retaining wall, 102-Pouring section, 103-Drainage channel, 104-Metal frame, 105-Positioning frame, 106-Moving frame, 107-Sliding frame, 108-Standing plate, 109-Reinforcing plate, 110-Connecting rod, 111-Holding rod, 112-Water pipe, 113-Flushing nozzle, 201-Support plate. Detailed Implementation

[0018] The embodiments of the present invention are described in detail below. Examples of the embodiments are shown in the accompanying drawings. The embodiments described below with reference to the accompanying drawings are exemplary and intended to explain the present invention, but should not be construed as limiting the present invention.

[0019] Example 1:

[0020] like Figure 1 and Figure 2 As shown, where Figure 1 This is a schematic diagram of the overall structure of the debris flow prevention and protection device. Figure 2 This is a left view of a debris flow prevention and protection device. The present invention provides a debris flow prevention and protection device comprising a protective retaining wall body 101 and a cleaning component. The cleaning component includes a metal frame 104, a positioning frame 105, a moving frame 106, a sliding frame 107, a standing plate 108, a pushing component, and a flushing component. The pushing component includes a connecting rod 110 and a holding rod 111. The flushing component includes a water guide pipe 112 and a flushing nozzle 113. The aforementioned solution optimizes the nozzle setup structure and reduces the number of nozzles required. When multiple retaining walls are used in combination, it effectively reduces the workload of nozzle maintenance. It is understood that the aforementioned solution can effectively reduce the workload of nozzle maintenance when multiple retaining walls are used in combination.

[0021] In this embodiment, several casting sections 102 are arranged in a straight line at the bottom of the protective retaining wall body 101, and a guide channel 103 is cast on the front side. The casting sections 102 are used for casting and fixing the protective retaining wall body 101, and steel reinforcement frames are installed through the multiple casting sections 102 and the protective retaining wall body 101.

[0022] The metal frame 104 is cast on the top of the protective retaining wall body 101. The positioning frame 105 is detachably connected to the metal frame 104 and is located on the top of the metal frame 104. The movable frame 106 is welded to the front side of the positioning frame 105. The movable frame 106 is provided with a guide groove. The sliding frame 107 can slide linearly in the guide groove. The standing plate 108 is cast on the rear side of the protective retaining wall body 101. The pushing component is located on the rear side of the sliding frame 107. The flushing component is located on the front side of the sliding frame 107. The metal frame 104 is cast onto the top of the protective retaining wall body 101 during installation, and multiple frames can be installed according to the length of the protective retaining wall body 101. This application describes the working principle of the device using a symmetrical arrangement. The metal frame 104 is provided with a T-shaped sliding groove to facilitate the sliding installation of the positioning frame 105. The top of the T-shaped part of the positioning frame 105 is provided with a vertically downward through hole, and the bottom of the T-shaped sliding groove of the metal frame 104 is provided with a threaded hole to facilitate the positioning frame 105 to be fixed by a T-shaped screw. The movable frame 106 with a guide sliding groove is welded to the front side of the positioning frame 105. When multiple protective retaining wall bodies 101 are used in combination, the movable frame 106 needs to be aligned at the splicing ends to facilitate the stable linear sliding of the sliding part of the sliding frame 107. After the standing plate 108 is cast and installed, it facilitates the walking of cleaning personnel. The pushing component is installed on the rear side of the sliding frame 107, and the flushing component is provided on the front side.

[0023] Secondly, a reinforcing plate 109 is cast and installed on the rear side of the main body 101 of the protective retaining wall. The reinforcing plate 109 is cast and installed on the rear side of the main body 101 of the protective retaining wall and is located below the standing plate 108. Multiple reinforcing plates 109 are arranged in a line at intervals on the rear side of the main body 101 of the protective retaining wall, which helps to improve the stability of the main body 101 of the protective retaining wall.

[0024] Then, the connecting rod 110 is threadedly connected to the sliding frame 107 and is located on the rear side of the sliding frame 107; the gripping rod 111 has anti-slip texture on its surface and is integrally formed with the connecting rod 110. The front external threaded end of the connecting rod 110 is directly connected to the threaded hole on the sliding frame 107 for installation, and the gripping rod 111 is integrally formed on the rear side for pushing the sliding frame 107 to move.

[0025] Finally, the water guide pipe 112 is fixedly connected to the sliding frame 107 and connected to the outlet pipe of the external water supply pump through a movable water pipe; several flushing nozzles 113 are threadedly connected to the water guide pipe 112 and are located at the bottom of the water guide pipe 112. The mounting plate of the water guide pipe 112 is fixed to the mounting rectangular plate of the sliding frame 107 by bolts, and multiple threaded holes are provided at intervals on its bottom to facilitate the installation of multiple flushing nozzles 113. The water inlet pipe on the rear side of the water guide pipe 112 is connected to the outlet pipe of the external water supply pump through a movable water pipe to achieve water supply.

[0026] When using this utility model to optimize the structure of the working nozzles and reduce their number, effectively reducing the maintenance workload of the working nozzles when multiple protective walls are used in combination, the main body 101 of the protective retaining wall is cast and fixed to the ground by the casting part 102. Then, the main body 101 of the protective retaining wall can directly protect against debris flows. At the same time, when multiple main bodies 101 of the protective retaining wall are assembled, the movable frame 106 needs to be aligned. When it is necessary to clean the inclined surface of the main body 101 of the protective retaining wall and the guide channel 103, the water inlet pipe at the tail of the water guide pipe 112 is connected to an external water pump through clamps and movable water pipes. Then, the sliding part of the sliding frame 107 is slidably set on the outermost movable frame 106. The guide slide is placed in the guide slide groove, and the pushing component is installed on the sliding frame 107. Then, the external water pump is turned on to extract cleaning water, and the sliding frame 107 is moved by the pushing component, which in turn moves the flushing component, thus cleaning the inclined surface of the protective retaining wall body 101. Furthermore, when the water flow in the guide groove 103 reaches a certain level, it will drive the mixed silt in it to be discharged, thereby achieving cleaning. In this application, the flushing component is set in one set to achieve cleaning when multiple retaining walls are used in combination. The number of subsequent working nozzles will also be significantly reduced, thereby optimizing the working nozzle setting structure and reducing the number of settings. When multiple retaining walls are used in combination, the workload of working nozzle maintenance can be effectively reduced.

[0027] Example 2:

[0028] like Figure 3 As shown, where Figure 3 This is a schematic diagram of the overall structure of the debris flow blocking and protection device. Based on the first embodiment, this utility model provides a debris flow blocking and protection device. The cleaning component also includes a support plate 201. The support plate 201 is cast on the reinforcing plate 109 and is set at an angle, with the high end abutting below the standing plate 108.

[0029] In this embodiment, arranging several support plates 201 in a straight line can improve the stability of the standing board 108 and enhance the safety of workers when walking.

[0030] The above-disclosed embodiments are merely one or more preferred embodiments of this application and should not be construed as limiting the scope of this application. Those skilled in the art can understand that all or part of the processes for implementing the above embodiments and equivalent changes made in accordance with the claims of this application still fall within the scope of this application.

Claims

1. A debris flow prevention and protection device, comprising a retaining wall body, wherein several casting sections are arranged in a straight line at intervals at the bottom of the retaining wall body, and a flow guide channel is cast and provided on the front side, characterized in that: It also includes cleaning components; The cleaning assembly includes a metal frame, a positioning frame, a movable frame, a sliding frame, a standing plate, a pushing component, and a rinsing component. The metal frame is cast into the top of the main body of the protective retaining wall. The positioning frame is detachably connected to the metal frame and is located on top of the metal frame. The movable frame is welded to the front side of the positioning frame and is provided with a guide groove. The sliding frame can slide linearly within the guide groove. The standing plate is cast into the rear side of the main body of the protective retaining wall. The pushing component is located behind the sliding frame, and the rinsing component is located in front of the sliding frame.

2. The debris flow blocking and protection device as described in claim 1, characterized in that: A reinforcing plate is also cast and installed on the rear side of the main body of the protective retaining wall. The reinforcing plate is cast and installed on the rear side of the main body of the protective retaining wall and is located below the standing plate.

3. The debris flow blocking and protection device as described in claim 1, characterized in that: The pushing component includes a connecting rod and a gripping rod. The connecting rod is threadedly connected to the sliding frame and is located on the rear side of the sliding frame. The gripping rod has anti-slip texture on its surface and is integrally formed with the connecting rod.

4. The debris flow blocking and protection device as described in claim 1, characterized in that: The flushing component includes a water guide pipe and flushing nozzles. The water guide pipe is fixedly connected to the sliding frame and connected to the outlet pipe of an external water supply pump through a movable water pipe. Several flushing nozzles are threadedly connected to the water guide pipe and are disposed at the bottom of the water guide pipe.

5. The debris flow blocking and protection device as described in claim 2, characterized in that... : The cleaning assembly also includes a support plate cast onto the reinforcing plate and angled, with its highest point abutting below the standing plate.