CN213173778U - Mountain slope repairing system - Google Patents

Abstract

The application relates to the field of mountain restoration, in particular to a mountain slope restoration system, which comprises a building block body laid on a mountain slope, wherein a first anchor rod is connected to the building block body and penetrates through the building block body to be connected with the mountain slope; the first anchor rod is connected with a positioning block capable of extending into the mountain slope in a sliding mode, and a sliding assembly capable of driving the positioning block to extend into the mountain slope is arranged on the first anchor rod. This application is through first stock and locating piece reinforcing building block body and the domatic joint strength of massif between, further reduces the possibility that building block body dropped from the domatic face of massif.

Description

Mountain slope repairing system

Technical Field

The application relates to the field of mountain restoration, in particular to a mountain slope restoration system.

Background

Along with economic development, resource development construction such as mine resource development, mountain opening and road building, mountain road construction, municipal engineering construction and the like causes exposed side slopes, ecological environment protection and landscape harmony are not facilitated, and meanwhile, due to the exposed side slopes, water and soil loss and landslide collapse accidents are easily caused by long-term rain water washing and the like, the side slopes need to be repaired and subjected to three-dimensional greening.

The utility model discloses a chinese utility model patent that the bulletin number is CN205116186U discloses a domatic hollow block of planting living and the mine is domatic with planting in mine, plant living hollow block includes block body, and block body is regular hexagonal prism shape, is formed with the through-hole between block body's the relative plane, plant living substrate and/or seedling set up in the through-hole, the through-hole is circular, and the through-hole includes central through-hole and side through-hole, forms to central through-hole between two hexagonal relative planes of block body, and the seedling is arranged in central through-hole, forms to the side through-hole between two arbitrary relative sides of block body, plants living substrate and is arranged in the side through-hole.

Because the slope surfaces of the mine are all provided with certain slope feet, the slope feet of some slope surfaces can reach 70 degrees or even larger, and in order to prevent the building block body from sliding down from the slope surfaces of the mine, the slope feet of the slope surfaces of the mine are provided with the inclined retaining walls. The building block body is exposed to the sun and rain for a long time on the inclined slope surface, so that the building block is easy to slip off from the mine slope surface; when the block body can slide down from the slope surface of the mine through the inclined retaining wall, the block body is blocked, and the block body is prevented from dropping on the road surface below the mine.

With respect to the related art in the above, the inventors consider that there are the following drawbacks: the building block body still has great possibility to slide down from the slope surface of the mine, and the building block body can take this internal seedling of this building block and plant the living substrate and drop when sliding down, and the side through-hole intercommunication of a plurality of building block bodies forms vertically and horizontally staggered's through-channel on domatic, and the rhizome intertwine is in the same place when making the vegetation in the planting substrate, and when one of them building block body dropped, seedling and plant the living substrate and fall with the plant area on the other building block body easily wherein.

SUMMERY OF THE UTILITY MODEL

In order to solve the problem that building block body and the domatic joint strength of massif are not enough, this application provides a domatic repair system of massif.

The application provides a hillside surface repair system adopts following technical scheme:

a mountain slope surface repairing system comprises a building block body laid on a mountain slope surface, wherein a first anchor rod is connected to the building block body and penetrates through the building block body to be connected with the mountain slope surface; the first anchor rod is connected with a positioning block capable of extending into a mountain slope in a sliding mode, a sliding assembly for driving the positioning block to extend into the mountain slope is arranged on the first anchor rod and comprises a sliding rod and a conical block, a vertical groove is formed in the first anchor rod, the sliding rod is connected into the vertical groove in a sliding mode, the conical block is connected with the lower end of the sliding rod, and the vertex of the conical block is located below the bottom face of the conical block; the one end that lies in first stock on the locating piece sets to the slope, on the supreme direction of follow down, the one end terminal surface that the locating piece is located first stock to the distance of stock axis crescent gradually, be connected with the baffle on the locating piece, set up on the first stock with the locating piece complex spout that slides, the baffle slides and connects in the spout.

By adopting the technical scheme, when the building block body is installed, after the building block body is laid on the mountain slope surface, the first anchor rod penetrates through the building block body to be connected with the mountain slope surface, and the positioning block is driven by the sliding assembly to extend into the mountain slope surface, so that the connection strength between the building block body and the mountain slope surface is enhanced to a certain extent, and the possibility that the building block body falls off from the mountain slope surface is further reduced; when the positioning block penetrates through the first anchor rod and extends into a mountain slope, an operator slides the sliding rod downwards into the vertical groove along the vertical direction, the conical block on the sliding rod is abutted against one end, located in the first anchor rod, of the positioning rod block, so that the positioning rod is subjected to component force towards the direction far away from the inner part of the first anchor rod, and the positioning rod extends out of the first anchor rod and extends into the mountain slope; the baffle on the locating piece slides and is connected in the spout, can prevent effectively that the locating piece from deviating from first stock when first stock is not connected with this body of building block.

Preferably, one end of the positioning block extending into the mountain slope is provided with a sharp corner.

Through adopting above-mentioned technical scheme, the setting of closed angle on the locating piece, the closed angle has the effect of punching, makes the locating lever stretch into the domatic convenient simple more of massif.

Preferably, the positioning block is connected with a reset block, the first anchor rod is provided with a connecting groove, and the reset block is connected in the connecting groove in a sliding manner along the radial direction of the first anchor rod.

Through adopting above-mentioned technical scheme, when being connected first stock with this body of building block, need to move the reset block to being close to first stock axis direction, make the reset block drive the locating piece and retract to first stock in, when first stock passed building block body back and stretched into the massif slope face, prevent that the locating piece from causing great damage to building block body and massif slope face. And after the first anchor rod is installed and the positioning block extends out of the first anchor rod, an operator adds glue into the connecting groove, the glue flows onto the positioning block, and the positioning block is fixed.

Preferably, be connected with the joint piece on the first stock, when the reset block retracted the locating piece in to first stock, the reset block upwards stretched out first stock and the cooperation of joint piece joint, be connected with the connecting block on the joint piece, connecting block and spread groove joint cooperation.

Through adopting above-mentioned technical scheme, drive the locating piece at the reset block and retract back to first stock in, through joint piece and reset block joint, connecting block and spread groove joint cooperation, make operating personnel convenient simple more when the first stock of installation, need not operating personnel and hold the reset block all the time in order to prevent the first stock of locating block roll-off.

Preferably, the building block body is provided with a plurality of, and a plurality of building block body is last to be connected with the connecting rod, building block body one side is seted up flutedly, building block body opposite side is connected with the arch of pegging graft complex with the recess.

Through adopting above-mentioned technical scheme, through lug and recess grafting cooperation between a plurality of building block bodies, the joint strength between a plurality of building block bodies is strengthened, reduces the possibility that building block body dropped to a certain extent.

Preferably, the bottom end of the mountain slope is fixedly connected with a soil wall.

Through adopting above-mentioned technical scheme, it is light at the domatic bottom fixed connection picture of massif, further reduces the possibility that the building block body dropped.

In summary, the present application includes at least one of the following beneficial technical effects:

1. the connection strength between the building block body and the mountain slope is enhanced through the first anchor rod and the positioning block, and the possibility that the building block body falls off from the mountain slope is further reduced;

2. when the first anchor rod is connected with the building block body, the reset block needs to be moved towards the direction close to the axis of the first anchor rod, so that the reset block drives the positioning block to retract into the first anchor rod, and when the first anchor rod penetrates through the building block body and then extends into the slope of the mountain, the positioning block is prevented from causing great damage to the building block body and the slope of the mountain;

3. and after the first anchor rod is installed and the positioning block extends out of the first anchor rod, an operator adds glue into the connecting groove, the glue flows onto the positioning block, and the positioning block is fixed.

Drawings

FIG. 1 is a schematic diagram of the overall structure of an embodiment of the present application;

FIG. 2 is a schematic structural view of the block body of FIG. 1;

FIG. 3 is a cross-sectional view taken along line A-A of FIG. 1, showing a first anchor and glide assembly;

FIG. 4 is an enlarged view of portion B of FIG. 3 showing the stop, locating block and sharp corner;

fig. 5 is a cross-sectional view of the first anchor rod with the locating block positioned within the first anchor rod, showing the snap-in block and the connecting block.

Description of reference numerals: 1. a mountain slope; 11. a soil wall; 2. a block body; 21. a protrusion; 22. a groove; 23. a connecting rod; 3. a first anchor rod; 31. a vertical slot; 32. a chute; 33. connecting grooves; 34. a clamping block; 35. connecting blocks; 4. positioning blocks; 41. sharp corners; 42. a baffle plate; 43. a reset block; 5. a slipping component; 51. a slide bar; 52. a conical block.

Detailed Description

The present application is described in further detail below with reference to figures 1-5.

The embodiment of the application discloses mountain slope surface repairing system. Referring to fig. 1, a hillside surface repairing system includes polylith building block body 2, and building block body 2 lays on hillside surface 1, 1 bottom fixedly connected with cob wall 11 of hillside surface, cob wall 11 and 2 butts of the building block body of bottommost.

Referring to fig. 1 and 2, the block body 2 is shaped like a cuboid, a groove 22 is formed in one side of the block body 2, a protrusion 21 is fixedly connected to the other side of the block body 2, and the protrusion 21 is in insertion fit with the groove 22.

The upper parts of the building block bodies 2 are connected with connecting rods 23, and the length direction of the connecting rods 23 is parallel to the inclination direction of the slope surface 1 of the mountain.

Referring to fig. 1 and 3, the connecting rod 23 is connected with a first anchor rod 3, and the first anchor rod 3 penetrates through the connecting rod 23 and the block body 2 and then extends into the slope 1 of the mountain.

Referring to fig. 3 and 4, the first anchor rod 3 is slidably connected with a positioning block 4, and the positioning block 4 is slidably connected to the first anchor rod 3 along the radial direction of the first anchor rod 3. The first anchor rod 3 is provided with a sliding component 5 which drives the positioning block 4 to extend into the slope surface 1 of the mountain.

The first anchor rod 3 is provided with a vertical groove 31 axially arranged along the first anchor rod 3, the sliding assembly 5 comprises a sliding rod 51 and a conical block 52, the sliding rod 51 is connected in the vertical groove 31 in a sliding manner along the vertical direction, the bottom surface of the conical block 52 is fixedly connected with the lower end of the sliding rod 51, and the vertex of the conical block 52 is positioned below the bottom surface of the conical block 52.

The one end terminal surface that locating piece 4 is located first stock 3 sets to the slope, and from supreme direction down, the distance of locating piece 4 one end terminal surface that is located first stock 3 to the stock axis increases gradually.

One end of the positioning block 4 extending into the mountain slope 1 is provided with a sharp corner 41.

Fixedly connected with baffle 42 on locating piece 4 has seted up spout 32 on the first stock 3, and the length direction of spout 32 is parallel with the radial of first stock 3, and baffle 42 slides along the radial of first stock 3 and connects in spout 32.

The positioning block 4 is fixedly connected with a reset block 43, and the reset block 43 is arranged along the length direction of the first anchor rod 3. The first anchor rod 3 is provided with a connecting groove 33 arranged along the length direction of the first anchor rod 3. The thickness of the connecting groove 33 is larger than that of the restoring block 43, and the restoring block 43 is connected in the connecting groove 33 in a sliding manner along the radial direction of the first anchor rod 3.

Referring to fig. 5, be provided with joint piece 34 on the first stock 3, when reset block 43 retracted joint piece 34 to first stock 3 in, reset block 43 upwards stretched out first stock 3 and the cooperation of joint piece 34 joint, fixedly connected with connecting block 35 on the joint piece 34, connecting block 35 and the cooperation of spread groove 33 joint.

The implementation principle of a mountain slope restoration system in the embodiment of the application is as follows:

when installing building block body 2, lay building block body 2 on the domatic 1 of massif back, operating personnel passes connecting rod 23, building block body 2 and is connected with the domatic 1 of massif with first stock 3. At this moment, the positioning block 4 is located in the first anchor rod 3, the clamping block 34 is in clamping fit with the reset block 43, and the connecting block 35 is in clamping fit with the connecting groove 33.

Treat first stock 3 and the domatic 1 back of mountain, operating personnel extracts reset block 43 with joint piece 34, connecting block 35 deviates from spread groove 33, slide bar 51 to the vertical direction lapse to erecting the inslot 31 in, the one end butt that conical block 52 and the locating lever piece on the slide bar 51 are located first stock 3, and then make the locating lever receive the component force of keeping away from the inside direction of first stock 3 of orientation, make the locating lever stretch out first stock 3, stretch into the domatic 1 of mountain.

Then, the operator adds glue into the connecting groove 33, and the glue flows onto the positioning block 4 to position the positioning block 4.

The above embodiments are preferred embodiments of the present application, and the protection scope of the present application is not limited by the above embodiments, so: all equivalent changes made according to the structure, shape and principle of the present application shall be covered by the protection scope of the present application.

Claims (6)

1. The utility model provides a domatic repair system of mountain, includes building block body (2) of laying on the domatic (1) of mountain, its characterized in that: the building block body (2) is connected with a first anchor rod (3), and the first anchor rod (3) penetrates through the building block body (2) to be connected with the mountain slope (1); the first anchor rod (3) is connected with a positioning block (4) capable of extending into a mountain slope surface (1) in a sliding mode, a sliding assembly (5) for driving the positioning block (4) to extend into the mountain slope surface (1) is arranged on the first anchor rod (3), the sliding assembly (5) comprises a sliding rod (51) and a conical block (52), a vertical groove (31) is formed in the first anchor rod (3), the sliding rod (51) is connected into the vertical groove (31) in a sliding mode, the conical block (52) is connected with the lower end of the sliding rod (51), and the vertex of the conical block (52) is located below the bottom surface of the conical block (52); the one end that lies in first stock (3) on locating piece (4) sets to the slope, on the orientation of following supreme down, one end terminal surface to the distance of stock axis that locating piece (4) lie in first stock (3) increase gradually, be connected with baffle (42) on locating piece (4), set up on first stock (3) and slide complex spout (32) with locating piece (4), baffle (42) slide connect in spout (32).

2. The landslide restoration system according to claim 1, wherein: and a sharp corner (41) is arranged at one end of the positioning block (4) extending into the mountain slope (1).

3. The landslide restoration system according to claim 1, wherein: be connected with reset block (43) on locating piece (4), spread groove (33) have been seted up on first stock (3), reset block (43) are connected in spread groove (33) along first stock (3) radial sliding.

4. The landslide restoration system according to claim 3 wherein: be connected with joint piece (34) on first stock (3), when reset block (43) retracted locating piece (4) to first stock (3) in, reset block (43) upwards stretches out first stock (3) and joint piece (34) joint cooperation, be connected with connecting block (35) on joint piece (34), connecting block (35) and spread groove (33) joint cooperation.

5. The landslide restoration system according to claim 1, wherein: the building block body (2) is provided with a plurality of, and is a plurality of be connected with connecting rod (23) on building block body (2), recess (22) have been seted up to building block body (2) one side, building block body (2) opposite side is connected with and pegs graft complex arch (21) with recess (22).

6. The landslide restoration system according to claim 1, wherein: the bottom end of the mountain slope (1) is fixedly connected with a soil wall (11).

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