CN112900191A - Garden road laying structure that water permeability is high - Google Patents

Abstract

A gardens road paving structure that water permeability is high includes: liquid collection layer, steel net layer and fragment of brick layer, liquid collection layer, steel net layer and fragment of brick layer connect gradually, and the collecting tank has been seted up on liquid collection layer, and the collecting tank is provided with liquid collection mouth, and liquid collection mouth is towards the steel net layer, and the steel net layer has a plurality of steel meshes, and the fragment of brick layer includes a plurality of bricks of stepping on, and each is stepped on the brick and fixes on the steel net layer, and each steps on the brick interval and sets up, and the adjacent brick seam that forms between stepping on the brick. After moisture falls on the brick layer of stepping on, around the brick is stepped on to the flow direction, finally flow to the brickwork joint, flow into the collecting tank after passing the steel mesh hole to with moisture drainage to the road below on the road surface, avoid gathering too much moisture on the road surface and influence the pedestrian current.

Description

Garden road laying structure that water permeability is high

Technical Field

The invention relates to the technical field of road construction, in particular to a garden road paving structure with high water permeability.

Background

At present, roads in gardens are generally paved by plate bricks for pedestrians to pass through gardens, but on some roads with low-lying bottom ends, moisture on the surfaces of the roads is not easy to be discharged to a sewer, and the passing of the pedestrians is influenced when the moisture on the surfaces of the roads is too much accumulated.

Disclosure of Invention

Based on this, it is necessary to provide a garden road paving structure having high water permeability.

The technical scheme for solving the technical problems is as follows: a gardens road paving structure that water permeability is high includes: the brick layer comprises a liquid collecting layer, a steel net layer and a brick layer, wherein the liquid collecting layer, the steel net layer and the brick layer are sequentially connected, a liquid collecting groove is formed in the liquid collecting layer and provided with a liquid collecting port, the liquid collecting port faces the steel net layer, the steel net layer is provided with a plurality of steel net holes, the brick layer comprises a plurality of pedal bricks, each pedal brick is fixed on the steel net layer, and each pedal brick is arranged at intervals, and a brick joint is formed between the adjacent pedal bricks.

In one embodiment, the step brick comprises an upper brick, an elastic block and a lower brick, the upper brick, the elastic block and the lower brick are sequentially connected, the lower brick is connected with the steel mesh layer, a lower groove is formed in one surface, facing the upper brick, of the lower brick, the lower groove is provided with a lower opening, a lower cover is rotatably connected to the side wall of the lower groove, a sealing elastic piece is fixedly connected to the side wall of the lower groove, the sealing elastic piece is connected with one surface, facing away from the upper brick, of the lower cover, a movable cover of the lower cover is arranged at the lower opening, an insertion strip is arranged on the protrusion, facing the one surface of the lower brick, of the upper brick, and penetrates through the lower opening in a movable mode, is movably inserted into the lower groove and abuts against the lower cover in a movable mode.

In one embodiment, the cover spring is a cover spring.

In one embodiment, still include the circular arc hook, the lower cover is opened and is equipped with the perforation, the one end of circular arc hook with the lateral wall of lower groove is connected, and the other end passes the perforation, the centre of a circle of circular arc hook and the center of rotation coincidence of lower cover, the circular arc hook passes the closing cap spring, the closing cap spring slide set up in the circular arc hook.

In one embodiment, an end of the cover spring close to the lower cover is provided with an elastic plate, and the elastic plate abuts against the lower cover.

In one embodiment, the number of the insert bars is at least two, and each insert bar is staggered with the cover elastic piece.

In one embodiment, the number of the inserting strips is two, one inserting strip is positioned on one side of the covering elastic piece, and the other inserting strip is positioned on the other side of the covering elastic piece.

In one embodiment, the elastic block comprises a supporting elastic member, one end of which is connected with the upper brick and the other end of which is connected with the lower brick.

In one embodiment, the elastic block further comprises a sponge block, a sponge perforation is formed in the sponge block, and the supporting elastic piece is arranged in the sponge perforation.

In one embodiment, the elastic block further includes a plurality of supporting partition plates, each supporting partition plate is provided with a partition plate through hole, the partition plate through holes are aligned, the number of the sponge blocks is at least two, the partition plates and the sponge blocks are arranged alternately, and the supporting spring is arranged through each sponge through hole and each partition plate through hole.

The invention has the beneficial effects that: according to the garden road paving structure with high water permeability, when water falls on the step bricks on the brick layer, the water flows to the periphery of the step bricks, finally flows to the brick joints, passes through the steel mesh holes and then flows into the liquid collecting tank, so that the water on the road surface is guided to the lower part of the road, and the influence of excessive water accumulated on the road surface on pedestrian passage is avoided.

Drawings

FIG. 1 is a schematic structural view of a garden road paving structure with high water permeability according to an embodiment;

FIG. 2 is a schematic view of a partial cross-sectional structure of a brick layer of a garden road paving structure with high water permeability according to an embodiment;

FIG. 3 is a schematic view of a partial cross-sectional structure of a brick layer of a landscape road pavement structure having high water permeability according to another embodiment;

fig. 4 is a partial sectional view illustrating a steel mesh layer of a garden road pavement structure having high water permeability according to an embodiment.

In the attached drawings, 10, a garden road paving structure with high water permeability; 100. a liquid collecting layer; 110. a liquid collecting tank; 200. a steel mesh layer; 210. a transverse steel rod; 220. a longitudinal steel bar; 221. fixing grooves; 230. steel mesh holes; 300. a brick layer; 310. putting bricks; 311. cutting; 312. a drainage channel; 313. a drainage inlet; 314. an outflow guide port; 315. hooking; 316. a vertical rod; 317. a cross bar; 318. a convex tip; 320. an elastic block; 321. a support elastic member; 322. a sponge block; 323. perforating the sponge; 324. supporting the partition plate; 325. perforating the partition plate; 326. a weep hole; 330. placing bricks; 331. a lower groove; 332. a lower cover; 333. a cover elastic member; 334. a circular arc hook; 335. a spring plate; 336. a spacer; 337. a drain port; 338. pushing the plate; 339. a water-pushing elastic member; 340. a steel rod cavity; 350. brickwork joint; 400. and (4) a wave block.

Detailed Description

It should be noted that the embodiments and features of the embodiments may be combined with each other without conflict. The technical solutions of the present invention will be further described below with reference to the accompanying drawings of the embodiments of the present invention, and the present invention is not limited to the following specific embodiments.

It should be understood that the same or similar reference numerals in the drawings of the embodiments correspond to the same or similar parts. In the description of the present invention, it should be understood that if there are terms such as "upper", "lower", "front", "rear", "left", "right", "top", "bottom", etc., indicating orientations or positional relationships based on the orientations or positional relationships shown in the drawings, it is only for convenience of description and simplicity of description, but does not indicate or imply that the equipment or elements referred to must have a specific orientation, be constructed in a specific orientation, and be operated, and therefore, the terms describing the positional relationships in the drawings are only used for illustrative purposes and are not to be construed as limiting the patent, and the specific meanings of the terms will be understood by those skilled in the art according to specific situations.

As shown in fig. 1, in one embodiment, a landscape road pavement structure having high water permeability includes: liquid collection layer 100, steel mesh layer 200 and brick layer 300, liquid collection layer 100, steel mesh layer 200 and brick layer 300 connect gradually, liquid collection tank 110 has been seted up to liquid collection layer 100, liquid collection tank 110 is provided with the liquid collection mouth, the liquid collection mouth is towards steel mesh layer 200, steel mesh layer 200 has a plurality of steel mesh 230, brick layer 300 includes a plurality of step bricks, each step brick is fixed on steel mesh layer 200, and each step brick interval sets up, forms brick seam 350 between the adjacent step brick. In this embodiment, collection liquid layer 100 includes album liquid layer body and connects in the barricade portion in the album liquid layer outside, and barricade portion is protruding in collection liquid layer body setting, and the inboard of barricade portion forms collecting tank 110, the top of collecting tank 110 have a catchment mouth, and steel mesh layer 200 is laid on the barricade portion for set up step on steel mesh layer 200 brick and collecting tank 110 keep apart, steel mesh layer 110 supports to stepping on the brick.

Specifically, after moisture falls on the brick of the brick layer 300, the periphery of the brick is stepped to the flow direction, and finally the brick flows to the brick joint 350, and flows into the liquid collecting tank 110 after passing through the steel mesh holes 230, so that moisture on the road surface is drained to the road below, and the phenomenon that pedestrians are influenced by excessive moisture accumulated on the road surface is avoided.

In order to better clear the standing water near the step bricks, in one embodiment, as shown in fig. 2, each of the step bricks comprises an upper brick 310, an elastic block 320 and a lower brick 330, the upper brick 310, the elastic block 320 and the lower brick 330 are sequentially connected, the lower brick 330 is connected with the steel mesh layer 200, the lower brick 330 has a lower groove 331 formed on a surface thereof facing the upper brick 310, the lower groove 331 has a lower opening, the side wall of the lower groove 331 is rotatably connected with a lower cover 332, the side wall of the lower groove 331 is fixedly connected with a cover sealing elastic piece 333, the cover elastic member 333 is connected to a side of the lower cover 332 facing away from the upper brick 310, the lower cover 332 is movably covered on the lower opening, the protruding surface of the upper brick 310 facing the lower brick 330 is provided with an inserting strip 311, the inserting bar 311 movably penetrates through the lower opening, is movably inserted into the lower groove 331, and movably abuts against the lower cover 332. When a pedestrian steps on the upper brick 310, the upper brick 310 is pressed downwards, the elastic block 320 is compressed, the inserting strip 311 penetrates through the lower opening and is inserted into the lower groove 331, and the lower cover 332 is opened, so that accumulated water near the upper brick 310 can flow into the lower groove 331, excessive accumulated water below the upper brick 310 is avoided, and the accumulated water below the upper brick 310 is prevented from splashing to the pedestrian after the pedestrian steps on the upper brick 310. In one embodiment, one end of the cover elastic member 333 is fixedly connected to a side of the lower cover 332 facing away from the upper brick 310, and the other end is fixedly connected to a sidewall of the lower groove 331. In one embodiment, the width of the lower opening is smaller than the width of the lower groove 331, and the lower cover 332 is rotatably disposed on a side wall of the lower groove 331 near the lower opening. It should be understood that the width of the lower opening is set to be smaller than the width of the lower groove 331 so that the groove top of the lower groove 331 can support the elastic block 320 while the cover elastic member 333 is coupled below the groove top and the lower cover 332 is rotatably coupled to the groove top of the lower groove 331. Wherein the middle step brick in fig. 1 conceals two adjacent resilient blocks 320.

Since the spring has good elasticity and a large degree of bending deformation, in one embodiment, the cover elastic member 333 is a cover spring.

In order to enable the cover elastic member 333 to better support the lower cover 332 at one side of the lower opening, in an embodiment, as shown in fig. 2, the cover elastic member further includes an arc hook 334, the lower cover 332 is provided with a through hole, one end of the arc hook 334 is connected with the sidewall of the lower groove 331, the other end of the arc hook 334 passes through the through hole, a circle center of the arc hook 334 coincides with a rotation center of the lower cover 332, the arc hook 334 passes through the cover spring, and the cover spring is slidably disposed on the arc hook 334. Since the lower cap 332 rotates near the lower port, by fixing the circular-arc hook 334 in the coil of the cover spring, wherein the line of the circular-arc hook 334 coincides with the line of rotation of the lower cap 332, the cover spring can expand and contract along the curve of the circular-arc hook 334, thereby better accommodating the movement of the lower cap 332.

In order to make the lower cover 332 better cover the lower opening, in one embodiment, an end of the cover spring near the lower cover 332 is provided with a spring plate 335, and the spring plate 335 abuts against the lower cover 332. The elastic plate 335 is disposed on the cover spring, so that the contact area between the cover elastic member 333 and the lower cover 332 is increased, and the lower cover 332 is pressed by the elastic plate 335, so that the lower cover 332 more stably covers the lower opening. Because the arc hook 334 has a large bending amplitude, the bending deformation amplitude of the cover spring is limited, in one embodiment, the number of the cover springs is at least two, the cover springs are abutted end to end, and the elastic plate 335 is arranged on one cover spring close to the lower cover 332. By sleeving a plurality of sections of the cover springs on the circular arc hooks 334, each cover spring is made to stretch out and draw back on a small arc, and the requirement for bending deformation of the cover springs is lowered. In one embodiment, a spacer 336 is disposed at one end of each of the cover springs, each of the spacers 336 has a spacer hole, the circular hook 334 passes through each of the spacer holes, and the adjacent cover spring abuts against the spacer 336. Since the end of the cover spring is not flat, the adjacent cover springs are easily wound, and the adjacent cover springs are pressed against each other by the spacer 336 by providing the spacer 336 at one end of each cover spring, separating the adjacent cover springs by the spacer 336. In one embodiment. Spacers 336 are provided at both ends of each of the cover springs, and the spacers 336 of the adjacent cover springs abut against each other.

In order to make the accumulated water flow into the lower groove 331 better, in one embodiment, the number of the insert strips 311 is at least two, and each insert strip 311 is staggered with respect to the cover elastic member 333. Through setting up many cuttings 311 for when going up brick 310 and pushing down, many cuttings 311 can push up lower cover 332 better, thereby make ponding flow into lower groove 331 better.

In order to make the inserting bar 311 push the lower cover 332 better, in one embodiment, the number of the inserting bar 311 is two, one of the inserting bars 311 is located on one side of the cover elastic member 333, and the other inserting bar 311 is located on the other side of the cover elastic member 333. Since the lower cover 332 is hindered by the cover elastic member 333 when rotating, the lower cover 332 is better pressed against the cover elastic member 333 by providing the insert 311 at both sides of the cover elastic member 333.

In order to adapt the elastic block 320 to the movement change of the upper brick 310, in one embodiment, the elastic block 320 includes a supporting elastic member 321, and one end of the supporting elastic member 321 is connected to the upper brick 310 and the other end is connected to the lower brick 330. When the upper brick 310 is pressed down, the supporting elastic member 321 is compressed, and after a pedestrian passes through the supporting elastic member 321 is restored to be deformed, so that the upper brick 310 is supported. In one embodiment, the supporting elastic member 321 is a supporting spring. In one embodiment, one end of the supporting elastic member 321 is fixedly connected to a surface of the upper brick 310 facing the lower brick 330, and the other end is fixedly connected to a surface of the lower brick 330 facing the upper brick 310.

In order to better clear accumulated water in the road, as shown in fig. 1 to 3, in one embodiment, the elastic block 320 further includes a sponge block 322, the sponge block 322 is provided with a sponge perforation 323, and the supporting elastic member 321 is disposed in the sponge perforation 323. Moisture near the stepping bricks is absorbed by the sponge blocks 322, when pedestrians step on the stepping bricks, the upper bricks 310 squeeze the sponge blocks 322, and after the moisture of the sponge blocks 322 is squeezed out, the moisture can flow into the lower grooves 331 and can also flow into the brick joints 350 to enter the liquid collecting grooves 110.

In order to better clean the moisture in the sponge block 322, as shown in fig. 2, in an embodiment, the elastic block 320 further includes a plurality of supporting partitions 324, each supporting partition 324 is provided with a partition perforation 325, and the partition perforations 325 are aligned, the number of the sponge blocks 322 is at least two, the partitions and the sponge blocks 322 are arranged alternately, and the supporting springs are inserted through the sponge perforations 323 and the partition perforations 325. Through setting up alternate support baffle 324 and sponge piece 322, extrude sponge piece 322 through two great support baffles 324 of hardness from top to bottom for each sponge piece 322 can all be fully extruded, thereby better with the moisture discharge in the sponge hole, with the moisture of absorbing better next time. In order to make the water penetrate into the lower sponge block 322 more quickly, in one embodiment, each supporting partition 324 is further provided with a plurality of liquid penetrating holes 326, the partition perforation 325 is located in the middle of the supporting partition 324, and the liquid penetrating holes 326 are uniformly distributed on the periphery of the partition perforation 325. The speed of water permeation from the upper part to the lower part of the supporting partition plate 324 is increased by forming the liquid permeation holes 326.

In order to better clear accumulated water on the upper brick 310, as shown in fig. 2, in one embodiment, the upper brick 310 is provided with a plurality of drainage channels 312, one end of each drainage channel 312 is provided with a drainage inlet 313, the other end of each drainage channel 312 is provided with a drainage outlet 314, the drainage inlet 313 is located on the side of the upper brick 310 facing away from the elastic block 320, and the drainage outlet 314 is located on the side of the upper brick 310 facing towards the elastic block 320. Accumulated water on the surface of the upper brick 310 is drained to the lower part of the upper brick 310 in time through the drainage channel 312, and the accumulated water is prevented from staying on the surface of the upper brick 310 to influence the passing of pedestrians. In one embodiment, each of the drainage channels 312 is gradually spaced away from the center of the upper brick 310 from an end near the drainage inlet 313 to an end near the drainage outlet 314. When no pedestrian passes through, the lower cover 332 is pressed against the lower opening, and accumulated water cannot flow into the lower groove 331, so that the accumulated water on the surface of the upper brick 310 is guided to the periphery of the step brick, and flows through the brick joint 350 and into the liquid collecting tank 110. In one embodiment, the lower opening is located in the middle of the lower tile 330, and the insert 311 is located near the side of the lower cover 332 where the rotation is connected. The lower opening is arranged in the middle of the lower brick 330, so that water flow in the drainage channel 312 is prevented from flowing to the lower opening and being accumulated above the lower cover 332. The reason for disposing the slip 311 near the side where the lower cover 332 is rotatably connected is to make the slip 311 open the lower cover 332 better, and the closer the slip 311 is to the position where the lower cover 332 is rotatably connected, the greater the extent to which the lower cover 332 is opened.

Because the volume of the lower groove 331 is limited, in order to timely clear up the moisture accumulated in the lower groove 331 so that the lower groove 331 can continuously collect and contain accumulated water when a pedestrian passes through, as shown in fig. 3, in an embodiment, the water drain device further comprises a hook 315, a water drain opening 337 is formed in the groove bottom of the lower groove 331, the water drain opening 337 penetrates through the groove bottom of the lower groove 331, one end of the hook 315 is fixedly connected with the upper brick 310, the other end of the hook is provided with a convex tip 318, the width of the convex tip 318 is gradually increased from one end close to the lower opening to one end close to the groove bottom of the lower groove 331, and the convex tip 318 is movably inserted into the water drain opening 337 and movably abutted against the side wall of the water drain opening 337. When a pedestrian steps on the upper brick 310, the upper brick 310 descends, the hook 315 descends, the convex tip 318 descends, the gap between the convex tip 318 and the side wall of the water drainage opening 337 gradually increases, accumulated water in the lower groove 331 can flow to the steel mesh layer 200 from the gap between the convex tip 318 and the side wall of the water drainage opening 337, meanwhile, the lower brick 330 moves downwards, the lower cover 332 is opened, and accumulated water flowing in from the lower opening can also flow out of the lower groove 331 through the water drainage opening 337 more directly. Since the hooks 315 are inserted into the hydrophobic holes from the lower side of the lower brick 330, that is, the hooks 315 partially pass through the steel mesh 200, in order to prevent the steel mesh 200 from obstructing the movement of the hooks 315, in one embodiment, the hooks 315 are inserted through the steel mesh 230. It should be understood that the steel mesh holes 230 of the steel mesh layer 200 can be arranged according to the structure of the step brick. Through the lower groove 331 of activity switching, in time collect and hold the pedestrian and step on when stepping on the brick, step on near flowing ponding of brick, open the lower cover 332 of groove 331 down with the help of pedestrian's gravity to and the hydrophobic hole mediation of groove 331 down, in time collect and discharge ponding. In one embodiment, the cross section of the hook 315 is L-shaped, the hook 315 includes a vertical rod 316, a cross rod 317 and the convex tip 318, one end of the vertical rod 316 is fixedly connected to the upper brick 310, the other end of the vertical rod is fixedly connected to one end of the cross rod 317, the other end of the cross rod 317 is fixedly connected to the convex tip 318, the vertical rod 316 penetrates through the steel mesh 230, the cross rod 317 is disposed in the liquid collecting tank 110, and the convex tip 318 penetrates through the steel mesh 230. For faster disposal of accumulated water, in one embodiment, the number of hooks 315 is at least two, the number of hydrophobic holes is at least two, and the tip 318 of one of the hooks 315 is inserted into one of the hydrophobic holes. In one embodiment, the width of the hydrophobic opening 337 increases from the end near the lower opening to the end near the bottom of the lower slot 331. As the nib 318 moves downward, the clearance between the nib 318 and the sidewall of the hydrophobic aperture increases, allowing more water to flow out of the lower trough 331.

In order to accelerate the accumulated water in the lower trough 331 to flow to the sump 110, as shown in fig. 2, in one embodiment, the collecting device further includes a push plate 338 and a water-pushing elastic member 339, one end of the water-pushing elastic member 339 is fixedly connected with the push plate 338, the other end of the water-pushing elastic member 339 is fixedly connected with the bottom of the lower trough 331, and the protruding tip 318 is fixedly connected with the push plate 338. When the upper brick 310 moves downwards, the convex tip 318 moves downwards, the push plate 338 is pulled to move downwards, and the push plate 338 pushes accumulated water to flow to the hydrophobic hole at the bottom of the groove, so that the accumulated water is discharged out of the lower groove 331 more quickly. In order to allow the push plate 338 to push more water, in one embodiment, the end of the nib 318 distal from the base of the lower channel 331 is fixedly attached to the push plate 338. By holding the push plate 338 higher on the nib 318, the push plate 338 has more fluid under it and the push plate 338 can push more fluid. To avoid excessive weight on the push plate 338, the nibs 318 are pressed out of the lower channel 331. in one embodiment, the push plate 338 is made of plastic. The plastic material is lighter, which reduces the pressure of the push plate 338 on the nib 318. In one embodiment, the push plate 338 defines a weight-reducing cavity therein.

In order to fix the step bricks on the steel mesh layer 200, as shown in fig. 1, in one embodiment, the steel mesh layer 200 includes a plurality of transverse steel rods 210 and a plurality of longitudinal steel rods 220, each transverse steel rod 210 and each longitudinal steel rod 220 are staggered to form a steel mesh 230, each transverse steel rod 210 abuts against a surface of each longitudinal steel rod 220 facing away from the sump 110, two steel rod cavities 340 are formed in each lower brick 330, each steel rod cavity 340 is penetrated by one transverse steel rod 210, and each step brick is disposed between two adjacent longitudinal steel rods 220. The two transverse steel rods 210 penetrate through each step brick, the step bricks are stabilized on a plane, then the transverse steel rods 210 are lapped on the longitudinal steel rods 220, and meanwhile, the two ends of each transverse steel rod 210 and each longitudinal steel rod 220 are fixed, so that the step bricks are prevented from moving. In order to enable the transverse steel rods 210 to be stably placed on the longitudinal steel rods 220, as shown in fig. 4, in one embodiment, a plurality of fixing grooves 221 are formed on each longitudinal steel rod 220, the fixing grooves 221 on two adjacent longitudinal steel rods 220 are correspondingly aligned, and each transverse steel rod 210 is disposed in the corresponding fixing groove 221 of each longitudinal steel rod 220. Each transverse steel rod 210 is placed in the fixing groove 221 of each longitudinal steel rod 220, and the movement of the transverse steel rods 210 is limited by the side walls of the fixing grooves 221, so that the transverse steel rods 210 are prevented from moving to drive the pedal bricks to move. In order to make the layout of the step bricks more orderly, as shown in fig. 1, in one embodiment, each of the transverse steel rods 210 is parallel, and the distance between two adjacent transverse steel rods 210 is equal, each of the longitudinal steel rods 220 is parallel, and two adjacent longitudinal steel rods 220 are parallel. The steel meshes 230 with the same size and shape are formed by the staggered arrangement of the horizontal steel rods 210 and the vertical steel rods 220 which have the same distance and are parallel to each other, so that the specification of each steel mesh 230 is unified, and the large-scale production and use of the step bricks are better adapted. In one embodiment, the step bricks are rectangular, and the horizontal steel rods 210 and the vertical steel rods 220 are perpendicular. When the horizontal steel rod 210 and the vertical steel rod 220 are perpendicular, the steel mesh holes 230 are rectangular, so that the shape of the steel mesh holes 230 is better adapted to the step bricks.

As shown in fig. 1, in one embodiment, the foldable bicycle further comprises a wave block 400, and one side of the wave block 400, between adjacent four of the step bricks, is fixedly connected to the upper bricks 310 of two adjacent step bricks, and the other side of the wave block is fixedly connected to the upper bricks 310 of the other two adjacent step bricks. When a pedestrian steps on one of the four stepping bricks, the upper brick 310 of the stepping brick is pressed downwards, the fluctuation block 400 is pressed downwards to drive the upper bricks 310 of the other three adjacent stepping bricks to be pressed downwards, so that the three upper bricks 310 are pressed downwards and together introduce accumulated water into the liquid collecting tank 110, and the road surface around the foot of the pedestrian is dredged. In one embodiment, the quantity of crotch is two, one the crotch is located step on one side of brick, another the crotch is located step on the opposite side of brick, one the crotch is close to the indulging steel pole 220 of one side, another the crotch is close to adjacent another indulge steel pole 220, the fast quantity of elasticity is four, is two liang of relative distribution in the end opening periphery, and one the elasticity is fast with one the crotch is located same one side, relative setting another the elasticity is fast with another the crotch is located same one side.

It should be understood that the above-described embodiments of the present invention are merely examples for clearly illustrating the present invention, and are not intended to limit the embodiments of the present invention. Other variations and modifications will be apparent to persons skilled in the art in light of the above description. And are neither required nor exhaustive of all embodiments. Any modification, equivalent replacement, and improvement made within the spirit and principle of the present invention should be included in the protection scope of the claims of the present invention.

Claims (10)

1. The utility model provides a structure is laid to gardens road that water permeability is high which characterized in that includes: the brick layer comprises a liquid collecting layer, a steel net layer and a brick layer, wherein the liquid collecting layer, the steel net layer and the brick layer are sequentially connected, a liquid collecting groove is formed in the liquid collecting layer and provided with a liquid collecting port, the liquid collecting port faces the steel net layer, the steel net layer is provided with a plurality of steel net holes, the brick layer comprises a plurality of pedal bricks, each pedal brick is fixed on the steel net layer, and each pedal brick is arranged at intervals, and a brick joint is formed between the adjacent pedal bricks.

2. A garden road paving structure with high water permeability as claimed in claim 1, wherein the step brick comprises an upper brick, an elastic block and a lower brick, the upper brick, the elastic block and the lower brick are sequentially connected, the lower brick is connected with the steel mesh layer, a lower groove is formed in one surface of the lower brick facing the upper brick, the lower groove is provided with a lower opening, a lower cover is rotatably connected to a side wall of the lower groove, a cover elastic member is fixedly connected to a side wall of the lower groove, the cover elastic member is connected with one surface of the lower cover facing away from the upper brick, a movable cover of the lower cover is arranged on the lower opening, an insertion strip is arranged on one surface of the upper brick facing the lower brick, and the insertion strip movably penetrates through the lower opening, is movably inserted into the lower groove and is movably abutted against the lower cover.

3. A high water permeability garden-road laying structure as claimed in claim 2, wherein said cover elastic member is a cover spring.

4. A garden road paving structure with high water permeability as claimed in claim 3, further comprising a circular arc hook, wherein the lower cover is provided with a through hole, one end of the circular arc hook is connected with the side wall of the lower groove, the other end of the circular arc hook passes through the through hole, the circle center of the circular arc hook coincides with the rotation center of the lower cover, the circular arc hook passes through the cover spring, and the cover spring is slidably arranged on the circular arc hook.

5. A high water permeability garden road laying structure as claimed in claim 3, wherein one end of the cover spring near the lower cover is provided with a spring plate abutting against the lower cover.

6. A water permeable garden road laying structure as claimed in claim 2, wherein said number of said cutting is at least two, and each said cutting is offset from said cover elastic member.

7. A water permeable garden road paving structure as claimed in claim 2, wherein said number of said cutting is two, one said cutting being located at one side of said cover elastic member, the other said cutting being located at the other side of said cover elastic member.

8. A garden-road laying structure with high water permeability as claimed in claim 2, wherein said elastic block comprises a supporting elastic member having one end connected to said upper brick and the other end connected to said lower brick.

9. The structure of claim 8, wherein the elastic block further comprises a sponge block, the sponge block is provided with a sponge through hole, and the supporting elastic member is disposed in the sponge through hole.

10. A high water permeability garden road laying structure as claimed in claim 9, wherein said elastic block further comprises a plurality of supporting partition plates, each supporting partition plate is provided with a partition plate through hole, and each partition plate through hole is aligned, the number of said sponge blocks is at least two, said partition plates and said sponge blocks are arranged alternately, and said supporting spring is inserted through each sponge through hole and each partition plate through hole.

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