Geological disaster treatment anti-slide pile protection wall casting mold device

By introducing damping and vibration mechanisms into the anti-slip pile retaining wall casting device, the problem of air bubbles generated during the casting process was solved, improving defoaming efficiency and finished product quality, and reducing the workload of operators.

CN224325771UActive Publication Date: 2026-06-05HUBEI SOUTHEAST HUBEI FOUNDATION ENG CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
HUBEI SOUTHEAST HUBEI FOUNDATION ENG CO LTD
Filing Date
2025-05-14
Publication Date
2026-06-05

AI Technical Summary

Technical Problem

Existing anti-slide pile retaining wall casting devices are prone to generating a large number of air bubbles during pouring, which affects the quality of the finished product and has low defoaming efficiency, resulting in a heavy workload for operators.

Method used

A casting device for anti-slide pile retaining wall in geological disaster control was designed, comprising a damping mechanism and a vibration mechanism. The vibration mechanism drives the impact rod assembly to knock and defoam inside the mold assembly through the drive component. The damping mechanism reduces vibration through the lifting component to ensure the defoaming effect and the stability of the mold.

Benefits of technology

This effectively improved the quality of the anti-slide piles. By combining vibration defoaming and damping mechanisms, the defoaming efficiency was improved, the workload of operators was reduced, and the stability of the mold and the quality of the finished product were ensured.

✦ Generated by Eureka AI based on patent content.

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Abstract

The utility model discloses a kind of geological disaster control anti-slide pile retaining wall casting mold devices, including base and mould assembly, the outside of base is provided with damping mechanism and vibration mechanism, the vibration mechanism is used to knock and defoam the casting mold poured inside the mould assembly, and the vibration mechanism includes driving assembly and ram component, the driving assembly is used to drive the ram component to move, and the ram component of motion state is used to knock and defoam the casting mold poured inside the mould assembly, the damping mechanism is used to buffer and shock attenuation the mould assembly of vibration state, the vibration mechanism, the tooth fan of swing state drives ram to reciprocate, then ram of inward movement state impacts on the surface of mould assembly, to knock and defoam the casting mold poured inside the mould assembly, effectively improve the finished product quality of anti-slide pile, and by damping mechanism, the mould assembly of impact state plays the effect of buffer and shock attenuation.
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Description

Technical Field

[0001] This utility model relates to the field of geological disaster management technology, specifically to a geological disaster management anti-slide pile retaining wall casting device. Background Technology

[0002] Geological disasters refer to geological processes or phenomena that cause loss of human life and property and damage to the environment under the influence of natural or human factors. The distribution and variation of geological disasters in time and space are subject to both the natural environment and human activities, and are often the result of the interaction between humans and nature. Anti-slide piles are piles that penetrate the landslide body and extend into the sliding bed to support the sliding force of the landslide body and stabilize the slope. They are suitable for shallow and medium-thick landslides and are a major measure for anti-slide treatment. Casting molds refer to cavities that shape fluids or malleable castable materials.

[0003] The existing anti-slide pile retaining wall casting device for geological disaster control involves pouring reinforced concrete into the mold assembly, with the upper and lower molds working together to form the anti-slide pile, and then demolding the formed anti-slide pile. However, during the pouring process, the mold is prone to generating a large number of air bubbles, requiring operators to continuously tap the outer surface of the mold assembly to remove the bubbles. This results in a large workload for operators and low defoaming efficiency, affecting the quality of the finished anti-slide pile. Utility Model Content

[0004] The purpose of this utility model is to provide a casting device for anti-slide pile wall protection in geological disaster control, so as to solve the problem mentioned in the background art that a large number of air bubbles are easily generated during the casting process, which affects the quality of the finished anti-slide pile.

[0005] To achieve the above objectives, this utility model provides the following technical solution: a casting device for anti-slide pile retaining wall in geological disaster control, comprising a base and a mold assembly, wherein a damping mechanism and a vibration mechanism are provided on the outer side of the base;

[0006] The vibration mechanism is used to knock and defoam the mold inside the mold assembly, and the vibration mechanism includes a drive assembly and a striking rod assembly.

[0007] The drive component is used to drive the impact rod component to move, and the impact rod component in the moving state is used to knock and defoam the mold poured inside the mold component;

[0008] The damping mechanism is used to buffer and reduce the vibration of the mold assembly, and the damping mechanism includes a first lifting assembly and a second lifting assembly.

[0009] Both the first lifting component and the second lifting component are used to buffer and dampen the mold component when it is vibrating.

[0010] Preferably, the first lifting assembly includes a telescopic rod, a second spring, and a shock-absorbing plate;

[0011] The telescopic rod includes a sleeve and a sliding rod, and the sliding rod is slidably connected to the inner cavity of the sleeve.

[0012] The sleeve is fixedly connected to the top of the base, the second spring is sleeved on the outside of the telescopic rod, and the two ends of the second spring are fixedly connected to the sleeve and the slide rod respectively, and the shock-absorbing plate is fixedly connected to the top of the slide rod.

[0013] Preferably, the component includes a first bracket, a crossbar, a connecting ring, a first spring, a connecting seat, and a connecting rod;

[0014] The first bracket is fixedly connected to the top of the base, the crossbar is fixedly connected to the inner side of the first bracket, the connecting ring is slidably connected to the outer wall of the crossbar, the first spring is sleeved on the outside of the crossbar, and the two ends of the first spring are respectively fixedly connected to the two connecting rings, the connecting seat is fixedly connected to the bottom of the damping plate, one end of the connecting rod is rotatably connected to the connecting seat, and the other end of the connecting rod is rotatably connected to the connecting ring.

[0015] Preferably, the drive assembly includes a fixed frame, a connecting frame, a turntable, a motor, and an eccentric rod;

[0016] The fixed frame is fixedly connected to one side of the base, the connecting frame is fixedly connected to the top of the fixed frame, the motor is installed on the outside of the connecting frame, the turntable is fixedly connected to the end of the output shaft of the motor, and the eccentric rod is fixedly connected to the eccentric position of the end face of the turntable.

[0017] Preferably, the impact rod assembly includes a swing rod, an impact rod, a connecting shaft, a second bracket, a toothed groove, and a toothed sector;

[0018] The swing rod is movably connected to the outer wall of the eccentric rod, the connecting shaft is fixedly connected to the inner side of the connecting frame, and the end of the swing rod is rotatably connected to the connecting shaft. The toothed sector is assembled at the bottom of the swing rod, the second bracket is fixedly connected to the inner bottom of the connecting frame, the impact rod is slidably connected to the inner wall of the second bracket, and the toothed groove is provided on the outer wall of the impact rod.

[0019] Preferably, in the operating state, the output shaft of the motor is used to drive the turntable to rotate, and in the rotating state, the turntable is used to drive the swing rod to reciprocate around the connecting shaft via the eccentric rod.

[0020] Preferably, the toothed sector meshes with the toothed groove, and the meshing state of the toothed sector and the toothed groove is used to drive the impact rod to reciprocate, and the impact rod in the inward moving state is used to impact the mold assembly.

[0021] Compared with the prior art, the beneficial effects of this utility model are: the vibration mechanism causes the oscillating toothed sector to drive the impact rod to move back and forth, and the impact rod moving inward impacts the surface of the mold assembly, thereby knocking and defoaming the mold inside the mold assembly, effectively improving the finished quality of the anti-slip pile, and through the shock-absorbing mechanism, it plays a buffering and shock-reducing role on the mold assembly under impact. Attached Figure Description

[0022] Figure 1 This is a schematic diagram of the main structure of the present utility model;

[0023] Figure 2 This is a schematic diagram of the shock absorption mechanism of this utility model;

[0024] Figure 3 This is a schematic diagram of the vibration mechanism structure of this utility model;

[0025] Figure 4 This is a schematic diagram of the vibration mechanism of this utility model from another perspective.

[0026] In the diagram: 1. Base; 2. Mold assembly; 3. Shock absorption mechanism; 301. First support; 302. Crossbar; 303. Connecting ring; 304. First spring; 305. Telescopic rod; 306. Second spring; 307. Shock absorption plate; 308. Connecting seat; 309. Connecting rod; 4. Vibration mechanism; 401. Fixed frame; 402. Connecting frame; 403. Turntable; 404. Swing rod; 405. Impact rod; 406. Motor; 407. Eccentric rod; 408. Connecting shaft; 409. Second support; 4010. Tooth groove; 4011. Tooth sector. Detailed Implementation

[0027] 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.

[0028] Please see Figure 1-4 This utility model provides a technical solution for a geological disaster control anti-slide pile retaining wall casting device: a geological disaster control anti-slide pile retaining wall casting device, including a base 1 and a mold assembly 2, with a shock-absorbing mechanism 3 and a vibration mechanism 4 provided on the outer side of the base 1;

[0029] The vibration mechanism 4 is used to knock and defoam the mold inside the mold assembly 2, and the vibration mechanism 4 includes a drive assembly and a striking rod assembly.

[0030] The drive assembly is used to drive the impact rod assembly to move, and the moving impact rod assembly is used to knock and defoam the mold poured inside the mold assembly 2;

[0031] The damping mechanism 3 is used to buffer and reduce the vibration of the mold assembly 2, and the damping mechanism 3 includes a first lifting assembly and a second lifting assembly.

[0032] Both the first and second lifting components are used to buffer and dampen the vibration of the mold component 2.

[0033] Please refer to this carefully. Figure 2 The first lifting assembly includes a telescopic rod 305, a second spring 306, and a shock-absorbing plate 307;

[0034] The telescopic rod 305 includes a sleeve and a sliding rod, with the sliding rod slidably connected to the inner cavity of the sleeve.

[0035] The sleeve is fixedly connected to the top of the base 1, the second spring 306 is sleeved on the outside of the telescopic rod 305, and the two ends of the second spring 306 are fixedly connected to the sleeve and the slide rod respectively, and the damping plate 307 is fixedly connected to the top of the slide rod.

[0036] In this embodiment: the damping plate 307 is pressed downward by the gravity of the mold assembly 2, so that the damping plate 307 squeezes the telescopic rod 305 and the second spring 306. The telescopic rod 305 and the second spring 306 are compressed by force, and the damping plate 307 moves downward until the damping plate 307 remains stationary.

[0037] Please refer to this carefully. Figure 2 The first bracket 301, the crossbar 302, the connecting ring 303, the first spring 304, the connecting seat 308, and the connecting rod 309;

[0038] The first bracket 301 is fixedly connected to the top of the base 1, the crossbar 302 is fixedly connected to the inner side of the first bracket 301, the connecting ring 303 is slidably connected to the outer wall of the crossbar 302, the first spring 304 is sleeved on the outside of the crossbar 302, and the two ends of the first spring 304 are respectively fixedly connected to the two connecting rings 303, the connecting seat 308 is fixedly connected to the bottom of the damping plate 307, one end of the connecting rod 309 is rotatably connected to the connecting seat 308, and the other end of the connecting rod 309 is rotatably connected to the connecting ring 303.

[0039] In this embodiment: the first spring 304 is still in a stretched state. Due to the vibration, the mold assembly 2 applies a downward force to the damping plate 307, causing the damping plate 307 to move downward again. The downward-moving damping plate 307 then presses down on the telescopic rod 305, compressing the second spring 306 again. Simultaneously, under the downward pressure of the damping plate 307, the connecting seat 308 pushes the two connecting rings 303 closer together via the connecting rod 309. The closer connecting rings 303 then compress the first spring 304 in the stretched state, causing the stretched first spring 304 to gradually approach the reset state. When the downward force of the vibration is canceled out, the second spring 306 resets and lifts the damping plate 307 again. At this time, the two connecting rings 303 are moving away from each other. The two connecting rings 303 stretch the first spring 304 again, which slows down the speed at which the two connecting rings 303 move away from each other, thus preventing the damping plate 307 from suddenly resetting upward.

[0040] Please refer to this carefully. Figure 3 The drive assembly includes a fixed frame 401, a connecting frame 402, a turntable 403, a motor 406, and an eccentric rod 407;

[0041] The fixed frame 401 is fixedly connected to one side of the base 1, the connecting frame 402 is fixedly connected to the top of the fixed frame 401, the motor 406 is installed on the outside of the connecting frame 402, the turntable 403 is fixedly connected to the end of the output shaft of the motor 406, and the eccentric rod 407 is fixedly connected to the eccentric position on the end face of the turntable 403.

[0042] In this embodiment: by connecting the motor 406 to power, the output shaft of the running motor 406 drives the turntable 403 to rotate. The rotating turntable 403 drives the eccentric rod 407 to perform circular motion. Since the swing rod 404 is movably connected to the outer wall of the eccentric rod 407, the eccentric rod 407 in circular motion drives the swing rod 404 to reciprocate around the connecting shaft 408.

[0043] Please refer to this carefully. Figure 4 The impact rod assembly includes a swing rod 404, an impact rod 405, a connecting shaft 408, a second bracket 409, a toothed groove 4010, and a toothed sector 4011;

[0044] The swing rod 404 is movably connected to the outer wall of the eccentric rod 407, the connecting shaft 408 is fixedly connected to the inner side of the connecting frame 402, and the end of the swing rod 404 is rotatably connected to the connecting shaft 408. The toothed sector 4011 is assembled at the bottom of the swing rod 404. The second bracket 409 is fixedly connected to the inner bottom of the connecting frame 402. The impact rod 405 is slidably connected to the inner wall of the second bracket 409. The toothed groove 4010 is provided on the outer wall of the impact rod 405.

[0045] In this embodiment: the eccentric rod 407 in a circular motion state drives the swing rod 404 to swing back and forth around the connecting shaft 408. The swing rod 404 in the swing state drives the toothed sector 4011 to swing back and forth. Since the toothed sector 4011 meshes with the toothed groove 4010, the swinging toothed sector 4011 drives the impact rod 405 to move back and forth. The impact rod 405 in the inward movement state impacts the surface of the mold assembly 2, thereby knocking and defoaming the molded material poured inside the mold assembly 2.

[0046] Please refer to this carefully. Figure 3 The output shaft of the motor 406 in operation is used to drive the turntable 403 to rotate. The turntable 403 in rotation is used to drive the swing rod 404 to reciprocate around the connecting shaft 408 via the eccentric rod 407.

[0047] In this embodiment: the output shaft of the running motor 406 drives the turntable 403 to rotate, and the rotating turntable 403 drives the eccentric rod 407 to perform circular motion.

[0048] Please refer to this carefully. Figure 4 The toothed sector 4011 meshes with the toothed groove 4010, and the meshing state of the toothed sector 4011 and the toothed groove 4010 is used to drive the impact rod 405 to reciprocate. The impact rod 405 in the inward movement state is used to impact the mold assembly 2.

[0049] In this embodiment: Since the toothed sector 4011 meshes with the toothed groove 4010, the oscillating toothed sector 4011 drives the impact rod 405 to reciprocate, and the impact rod 405 in the inward moving state impacts the surface of the mold assembly 2.

[0050] Working principle: When it is necessary to knock out bubbles in the mold inside the mold assembly 2, the motor 406 is powered on and started. The output shaft of the running motor 406 drives the turntable 403 to rotate. The rotating turntable 403 drives the eccentric rod 407 to move in a circular motion. Since the swing rod 404 is movably connected to the outer wall of the eccentric rod 407, the eccentric rod 407 in the circular motion state drives the swing rod 404 to swing back and forth around the connecting shaft 408. The swing rod 404 in the swing state drives the toothed sector 4011 to swing back and forth. Since the toothed sector 4011 meshes with the toothed groove 4010, the swinging toothed sector 4011 drives the impact rod 405 to move back and forth. The impact rod 405 in the inward movement state impacts the surface of the mold assembly 2, thereby knocking out bubbles in the mold inside the mold assembly 2.

[0051] When the impact rod 405 strikes the mold assembly 2, the mold assembly 2 vibrates. At this time, the gravity of the mold assembly 2 applies downward pressure to the damping plate 307, causing the damping plate 307 to compress the telescopic rod 305 and the second spring 306. The telescopic rod 305 and the second spring 306 are compressed, and the damping plate 307 moves downward until it remains stationary. At this point, the first spring 304 is still stretched. Due to the vibration, the mold assembly 2 applies a downward force to the damping plate 307, causing the damping plate 307 to move downward again. This downward-moving damping plate 307 then presses down on the telescopic rod 305 again, compressing the second spring 306 once more. Simultaneously, under the downward pressure of the damping plate 307, the connecting seat 308 pushes the two connecting rings 303 closer together through the connecting rod 309. The connecting rings 303 that are close together compress the first spring 304 in the stretched state again, causing the first spring 304 in the stretched state to gradually approach the reset state. When the downward force of the vibration is canceled out, the second spring 306 resets and pushes the damping plate 307 up again. At this time, the two connecting rings 303 are moving away from each other. At this time, the two connecting rings 303 stretch the first spring 304 again, which slows down the speed at which the two connecting rings 303 move away from each other, thus preventing the damping plate 307 from suddenly resetting upward, thereby achieving a shock absorption effect on the impacted mold assembly 2.

[0052] 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 casting device for anti-slide pile retaining wall in geological disaster control, comprising a base (1) and a mold assembly (2), characterized in that: The base (1) is provided with a shock-absorbing mechanism (3) and a vibration mechanism (4) on its outer side. The vibration mechanism (4) is used to knock and defoam the mold poured inside the mold assembly (2), and the vibration mechanism (4) includes a drive assembly and a striker assembly. The driving component is used to drive the impact rod component to move, and the impact rod component in the moving state is used to knock and defoam the mold poured inside the mold component (2); The damping mechanism (3) is used to buffer and reduce the vibration of the mold assembly (2) in a vibrating state, and the damping mechanism (3) includes a first lifting assembly and a second lifting assembly; Both the first lifting component and the second lifting component are used to buffer and dampen the mold component (2) in a vibrating state.

2. The anti-slide pile retaining wall casting device for geological disaster control according to claim 1, characterized in that: The first lifting assembly includes a telescopic rod (305), a second spring (306), and a shock-absorbing plate (307). The telescopic rod (305) includes a sleeve and a sliding rod, and the sliding rod is slidably connected to the inner cavity of the sleeve. The sleeve is fixedly connected to the top of the base (1), the second spring (306) is sleeved on the outside of the telescopic rod (305), and the two ends of the second spring (306) are fixedly connected to the sleeve and the slide rod respectively, and the damping plate (307) is fixedly connected to the top of the slide rod.

3. The anti-slide pile retaining wall casting device for geological disaster control according to claim 2, characterized in that: The second lifting assembly includes a first bracket (301), a crossbar (302), a connecting ring (303), a first spring (304), a connecting seat (308), and a connecting rod (309). The first bracket (301) is fixedly connected to the top of the base (1), the crossbar (302) is fixedly connected to the inner side of the first bracket (301), the connecting ring (303) is slidably connected to the outer wall of the crossbar (302), the first spring (304) is sleeved on the outside of the crossbar (302), and the two ends of the first spring (304) are respectively fixedly connected to the two connecting rings (303), the connecting seat (308) is fixedly connected to the bottom of the damping plate (307), one end of the connecting rod (309) is rotatably connected to the connecting seat (308), and the other end of the connecting rod (309) is rotatably connected to the connecting ring (303).

4. The anti-slide pile retaining wall casting device for geological disaster control according to claim 1, characterized in that: The drive assembly includes a fixed frame (401), a connecting frame (402), a turntable (403), a motor (406), and an eccentric rod (407). The fixed frame (401) is fixedly connected to one side of the base (1), the connecting frame (402) is fixedly connected to the top of the fixed frame (401), the motor (406) is installed on the outside of the connecting frame (402), the turntable (403) is fixedly connected to the end of the output shaft of the motor (406), and the eccentric rod (407) is fixedly connected to the eccentric position of the end face of the turntable (403).

5. The anti-slide pile retaining wall casting device for geological disaster control according to claim 4, characterized in that: The impact rod assembly includes a swing rod (404), an impact rod (405), a connecting shaft (408), a second bracket (409), a toothed groove (4010), and a toothed sector (4011). The swing rod (404) is movably connected to the outer wall of the eccentric rod (407), the connecting shaft (408) is fixedly connected to the inner side of the connecting frame (402), and the end of the swing rod (404) is rotatably connected to the connecting shaft (408). The toothed sector (4011) is assembled at the bottom of the swing rod (404). The second bracket (409) is fixedly connected to the inner bottom of the connecting frame (402). The impact rod (405) is slidably connected to the inner wall of the second bracket (409). The toothed groove (4010) is provided on the outer wall of the impact rod (405).

6. The anti-slide pile retaining wall casting device for geological disaster control according to claim 5, characterized in that: The output shaft of the motor (406) in operation is used to drive the turntable (403) to rotate. The turntable (403) in rotation is used to drive the swing rod (404) to reciprocate around the connecting shaft (408) via the eccentric rod (407).

7. The anti-slide pile retaining wall casting device for geological disaster control according to claim 5, characterized in that: The toothed sector (4011) meshes with the toothed groove (4010), and the toothed sector (4011) and the toothed groove (4010) in the meshing state are used to drive the impact rod (405) to reciprocate. The impact rod (405) in the inward moving state is used to impact the mold assembly (2).