CN113308961B - Road paving structure in sponge city - Google Patents

Abstract

The application relates to a road paving structure in sponge city belongs to the technical field in sponge city. The water-permeable brick comprises a foundation, a support column and a water-permeable brick, wherein the foundation is sequentially arranged from bottom to top, the support column is arranged on the foundation, the water-permeable brick is arranged on the support column, the foundation is provided with a water receiving pipe used for receiving rainwater, a drain pipe connected with the water receiving pipe is pre-buried in the foundation, and a water outlet of the drain pipe is connected with a water source. When raining, rainwater falling onto the water permeable bricks permeates into the water receiving pipe from the water permeable bricks, then enters the water drainage pipe from the water receiving pipe, and is drained into a water source through the water drainage pipe, so that water on a road is drained, and soil below the water permeable bricks is not easy to collapse; and the water is discharged into the water source through the water discharge pipe, and the water is collected, so that the water resource is saved.

Description

Road paving structure in sponge city

Technical Field

The application relates to the field of sponge cities, in particular to a road paving structure of a sponge city.

Background

The sponge city is a new generation of city rainfall flood management concept, and means that the city can be like a sponge, and has good elasticity in the aspects of adapting to environmental changes, coping with natural disasters caused by rainwater and the like. Wherein, the principle of sponge city is also adopted to some roads, permeates the soil of road below with the water on the road through infiltration technique.

In the related art, water permeable bricks are laid on the surface of a road, and water permeable holes are formed in the water permeable bricks. When raining, rainwater falling on the water permeable bricks permeates into soil through the water permeable holes, so that water is not easy to accumulate on the surface of the road.

With respect to the related art in the above, the inventors have considered that when more water permeates into the soil under the water permeable bricks, the soil of the foundation under the water permeable bricks is made softer, and thus the road may collapse.

Disclosure of Invention

In order to make the road difficult for collapsing, this application provides the road pavement structure in sponge city.

The application provides a road pavement structure in sponge city adopts following technical scheme:

the utility model provides a road paving structure in sponge city, includes the ground that sets gradually from supreme down, locate the support column on the ground and locate the brick that permeates water on the support column, the ground is equipped with the water receiving pipe that is used for accepting the rainwater, the ground is pre-buried to have the drain pipe of being connected with the water receiving pipe, the delivery port and the water source of drain pipe are connected.

By adopting the technical scheme, when raining, rainwater falling onto the water permeable bricks permeates into the water receiving pipe from the water permeable bricks, then enters the water drainage pipe from the water receiving pipe, and is drained into a water source through the water drainage pipe, so that water on a road is drained, and the road is not easy to collapse; and the water is discharged into the water source through the water discharge pipe, and the water is collected, so that the water resource is saved.

Optionally, the support column is provided with a clamping groove for embedding the water permeable bricks, and the water receiving pipe is located below the space between two adjacent water permeable bricks.

By adopting the technical scheme, the water permeable bricks are embedded into the clamping grooves of the supporting columns, so that the water permeable bricks are connected with the supporting columns; through the support of support column, make the brick that permeates water be higher than the ground, the water receiving pipe is established on the ground and is located the below of two adjacent bricks that permeate water, makes the rainwater drop to the water receiving pipe from the clearance between two adjacent bricks that permeate water to collect the rainwater.

Optionally, the top surface of the brick that permeates water has seted up the mounting groove, the brick that permeates water in be provided with the pad that permeates water that has the hole of permeating water in the mounting groove, the brick that permeates water has seted up a plurality of water conservancy diversion passageways, the one end and the mounting groove of water conservancy diversion passageway are linked together, and the other end link up with one of them circumference side of the brick that permeates water mutually.

Through adopting above-mentioned technical scheme, when the rainwater falls on the brick that permeates water, the rainwater drips on permeating water pad, water gets into the mounting groove behind the hole of permeating water pad, flow from the circumference side of the brick that permeates water after passing through the water conservancy diversion passageway again, the rainwater is located between two adjacent bricks that permeate water this moment, thereby make the rainwater drop to in the water receiving pipe, set up mounting groove and water conservancy diversion passageway through permeating water the brick, make the water that drips on the brick surface that permeates water also can drop to in the water receiving pipe, and then make more water collected.

Optionally, the water permeable brick is provided with two water guide blocks on all circumferential sides, a water guide cavity, a water inlet communicated with the water guide cavity and a water outlet communicated with the water guide cavity are formed between the two water guide blocks on the same circumferential side, the water receiving pipe is located below the water outlet, and the water guide channel is communicated with the water guide cavity.

By adopting the technical scheme, when rainwater on the day falls between two adjacent water permeable bricks, the rainwater enters the water guide cavity from the water inlet and then falls into the water receiving pipe from the water outlet; on the other hand, water entering the flow guide channel also flows out of the water guide cavity and enters the water receiving pipe through the water outlet, and water falling on a road enters the water receiving pipe as far as possible through the flow guide effect of the water guide block.

Optionally, each water guide block includes an abutting portion abutting against the support column and a water guide portion connected to the abutting portion, and the water guide portion is inclined toward the water outlet.

By adopting the technical scheme, the water guide block is abutted with the support column, and the water permeable brick and the support column are relatively stable under the abutting action of the abutting part; the water guide part is arranged towards the water outlet in an inclined mode, so that the water outlet is smaller than the water inlet, the water receiving pipe is located below the water outlet, and water flowing out of the water outlet can be received without being too large when the water receiving pipe is designed.

Optionally, be provided with between brick and the water receiving pipe that permeates water and keep off the stone spare, keep off the stone spare including support in the loader of ground and locate the piece that absorbs water in the loader, the loader have with the delivery port corresponding end of intaking and with the water outlet end that the water receiving pipe corresponds, the up end evagination of the piece that absorbs water sets up.

Through adopting above-mentioned technical scheme, when the stone falls down from the clearance between two adjacent brick that permeate water, the stone falls into earlier on the piece that absorbs water to being kept off outside the piece that absorbs water, making the difficult entering water receiving of stone in the water receiving pipe, and when water fell into on keeping off the stone piece, water can be absorbed by the piece that absorbs water, until the piece that absorbs water is sucked and is filled up, the water in the piece that absorbs water flows out and falls into in the water receiving pipe from the play water end of carrier because of the action of gravity, thereby make hydroenergy get into in the water receiving pipe and the stone is difficult for getting into in the water receiving pipe.

Optionally, the structure of mating formation is still including top water retaining member, rainwater sensor and the control terminal who locates the water receiving pipe, water retaining member is including covering the baffle and the drive of water receiving pipe baffle pivoted driving motor, driving motor with the lateral wall fixed connection of water receiving pipe, rainwater sensor is connected with the control terminal electricity, control terminal is connected with driving motor electricity.

By adopting the technical scheme, the baffle blocks the water receiving pipe in a conventional state, when people splash water or overturn beverages on a road, water falls down from between two adjacent water permeable bricks and drops on the baffle, and the water is blocked by the baffle, so that water with more impurities is not easy to enter the water receiving pipe; when raining, the rainwater sensor transmits a signal to the control terminal, the control terminal controls the driving motor to act, the driving motor drives the baffle to rotate, and the baffle does not cover the water receiving pipe any more, so that rainwater falling between two adjacent water permeable bricks enters the water receiving pipe; when the rain is not raining, the rain sensor transmits signals to the control terminal again, the control terminal controls the driving motor to act, and the baffle covers the water receiving pipe again.

Optionally, a diversion trench is formed in the side face, far away from the water receiving pipe, of the baffle, and diversion openings communicated with the diversion trench are formed in the circumferential side face of the baffle.

Through adopting above-mentioned technical scheme, when the water droplet falls on the baffle, generally can get into the guiding gutter to flow out from the water conservancy diversion mouth, make the water on the baffle change the discharge.

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

1. when raining, rainwater falling onto the water permeable bricks permeates into the water receiving pipe from the water permeable bricks, then enters the water drainage pipe from the water receiving pipe, and is drained into a water source through the water drainage pipe, so that water on a road is drained, and soil below the water permeable bricks is not easy to collapse;

2. the water collecting pipe is provided with a water collecting pipe, and the water collecting pipe is provided with a water collecting channel;

3. when stones fall down from the gap between two adjacent water permeable bricks, the stones firstly fall into the water absorbing part and are blocked outside the water absorbing part, so that the stones are not easy to enter the water receiving pipe.

Drawings

Fig. 1 is a schematic overall structure diagram of a pavement structure on a road according to an embodiment of the present application.

Fig. 2 is a schematic distribution diagram of a paving structure according to an embodiment of the present application from bottom to top.

Fig. 3 is a schematic connection diagram of a support column and a water permeable brick according to an embodiment of the present application.

Fig. 4 is a schematic connection diagram of a water receiving pipe and a water discharging pipe according to an embodiment of the present application.

FIG. 5 is an exploded view of the water permeable mat and the water permeable brick according to the embodiment of the present application.

Fig. 6 is a schematic structural view of a water permeable brick according to an embodiment of the present application.

Fig. 7 is a schematic structural view of a stone blocking member between a water receiving pipe and a water permeable brick according to an embodiment of the present application.

Fig. 8 is a schematic overall structure diagram of a stone blocking member according to an embodiment of the present application.

Figure 9 is an exploded view of the absorbent member and carrier of the present application.

Fig. 10 is a schematic view illustrating a state in which the water receiving pipe is blocked by the water blocking member according to the embodiment of the present application.

Fig. 11 is a schematic view of the water receiving pipe not being blocked by the water blocking member according to the embodiment of the present application.

Description of reference numerals: 1. a foundation; 2. a support pillar; 21. a card slot; 3. water permeable bricks; 31. mounting grooves; 32. a water permeable cushion; 33. a flow guide channel; 34. a water guide block; 341. an abutting portion; 342. a water guide part; 35. a water guide cavity; 36. a water inlet; 37. a water outlet; 4. a water receiving pipe; 41. a filter element; 5. a drain pipe; 6. a stone blocking member; 61. a carrier; 611. a water inlet end; 612. a water outlet end; 613. supporting legs; 62. a water absorbing member; 7. a water blocking member; 71. a drive motor; 72. a baffle plate; 73. a diversion trench; 74. a flow guide port; 8. and (6) paving the groove.

Detailed Description

The present application is described in further detail below with reference to figures 1-11.

The embodiment of the application discloses road pavement structure in sponge city.

Referring to fig. 1 and 2, the road has an inwardly concave pavement groove 8, and the pavement structure is located in the pavement groove 8. The structure of mating formation includes ground 1, support column 2 and the brick 3 that permeates water that sets gradually from supreme down, and ground 1 is laid at 8 tank bottoms in the pavement groove, and support column 2 sets up on ground 1, and the brick 3 that permeates water is connected with support column 2, provides the support for the brick 3 that permeates water through support column 2, makes 3 covers the pavement groove and forms the road of permeating water.

Referring to fig. 2 and 3, the foundation 1 is formed by laying stones or silt, and the lower ends of the support columns 2 are embedded in the foundation 1 and connected with the foundation 1 through concrete. The support column 2 is kept away from the one end terminal surface of ground 1 and is seted up draw-in groove 21, and the brick 3 that permeates water imbeds in the draw-in groove 21. In the embodiment, one support column 2 provides support for four permeable bricks 3, the support column 2 is provided with four clamping grooves 21, and the four clamping grooves 21 are circumferentially arranged on the support column 2 at intervals; the brick 3 that permeates water is the cuboid, and the four corners embedding draw-in groove 21 of brick 3 that permeates water.

Referring to fig. 4, foundation 1 is provided with water receiving pipe 4 and drain pipe 5, and drain pipe 5 buries underground in foundation 1 in advance, and the one end of drain pipe 5 is sealed, and the other end is connected with the water source. The water receiving pipe 4 is vertically arranged on the foundation 1, the lower end of the water receiving pipe 4 is connected with the water drainage pipe 5, the water receiving pipe 4 is positioned below the space between two adjacent water permeable bricks 3, the water receiving pipe 4 is enabled to receive water falling from the two adjacent water permeable bricks 3, the water receiving pipe 4 flows into the water drainage pipe 5 after receiving rainwater, and the water flows into a water source through the water drainage pipe 5. The number of the water receiving pipes 4 is set according to the actual situation, in the embodiment, the water receiving pipes 4 are arranged below every two adjacent water permeable bricks 3; the number of the water discharge pipes 5 can be one, or two or more than two, and any water discharge pipe can discharge water in the water receiving pipes 4, and one water discharge pipe 5 can be connected with a plurality of water receiving pipes 4. Wherein, the water source is the water storage places such as cistern, collects the water in the drain pipe 5 through the water source.

Referring to fig. 5 and 6, the mounting groove 31 has been seted up to the top surface of brick 3 that permeates water, and brick 3 that permeates water is provided with the pad 32 that permeates water in mounting groove 31, and the pad 32 that permeates water is provided with a plurality of holes of permeating water, and hydroenergy can pass through the hole of permeating water to make water can pass through the pad 32 that permeates water. When the brick 3 that permeates water uses, permeate water and fill up 32 embedding mounting groove 31 in, the brick 3 that permeates water has the side that permeates water and fills up 32 up, and the rainwater drips to permeating water and fills up 32 when making rainy to the rainwater permeates water and fills up 32 and get into in the mounting groove 31.

The brick 3 that permeates water is seted up water conservancy diversion passageway 33, and the one end of water conservancy diversion passageway 33 is linked together with mounting groove 31, and the other end link up with one of them circumference side of brick 3 that permeates water mutually, and when the brick 3 that permeates water uses, the port that water conservancy diversion passageway 33 is located the circumference side is less than the port that water conservancy diversion passageway 33 is located the mounting groove 31, makes the rainwater in the mounting groove 31 flow out through water conservancy diversion passageway 33. Wherein, the water conservancy diversion passageway 33 can be provided with a plurality ofly, specifically, the water conservancy diversion passageway 33 is provided with eight, and the brick 3 that permeates water has four circumference sides, and each circumference side all has two ports of water conservancy diversion passageway 33, makes the water in the mounting groove 31 discharge from four circumference sides.

Four circumferential side surfaces of the water permeable brick 3 are provided with two water guide blocks 34, the two water guide blocks 34 on the same circumferential side surface form a water guide cavity 35, the port of the water guide channel 33 is positioned in the water guide cavity 35, so that the water guide channel 33 is communicated with the water guide cavity 35, and water flowing out of the water guide channel 33 enters the water guide cavity 35. Moreover, the two water guide blocks 34 on the same circumferential side surface are not mutually abutted, the two water guide blocks 34 also form a water inlet 36 and a water outlet 37, and the water inlet 36 and the water outlet 37 are both communicated with the water guide cavity 35. In addition, when the permeable bricks 3 are laid, the water guide blocks 34 of two adjacent permeable bricks 3 are mutually abutted, and the two water guide cavities 35 are also communicated, so that a larger cavity is formed between the two permeable bricks 3.

When the permeable bricks 3 are used, the water inlet 36 is positioned above the water outlet 37, water entering the mounting groove 31 flows into the water guide cavity 35 from the flow guide channel 33, part of rainwater falls into the water guide cavity 35 between two adjacent permeable bricks 3 from the water inlet 36, and the water in the water guide cavity 35 flows out from the water outlet 37. In addition, the water receiving pipe 4 is positioned below the water outlet 37, and water flowing out of the water outlet 37 enters the water receiving pipe 4, so that the water receiving pipe 4 receives rainwater falling from the water permeable brick 3.

Each water guide block 34 comprises an abutting part 341 and a water guide part 342 which are integrally arranged, a water inlet 36 is formed between the two abutting parts 341, the two abutting parts 341 are respectively abutted against the two support columns 2, and the positioning function is realized during installation, so that the water permeable bricks 3 can be conveniently connected with the support columns 2; the two water guiding parts 342 form the water outlet 37, and the water guiding parts 342 incline towards the water outlet 37, so that the two water guiding blocks 34 contract towards the water outlet 37, and the width of the water outlet 37 is smaller than that of the water inlet 36. Meanwhile, the water guide part 342 inclines towards the water outlet 37, so that the water guide part 342 has a guiding function, and water in the water guide cavity 35 can flow out from the water outlet 37 more easily.

Referring to fig. 7 and 8, in order to prevent stones from falling into the water receiving pipe 4 from the gap between two adjacent water permeable bricks 3, a stone blocking member 6 is arranged between the water permeable bricks 3 and the water receiving pipe 4. The stone blocking member 6 includes a carrier 61 and a water absorbing member 62, the carrier 61 is supported on the foundation 1 by the supporting legs 613, and the number of the supporting columns 2 may be one, or two or more, and all that can be used for supporting the carrier 61 on the foundation 1.

Referring to fig. 8 and 9, the carrier 61 has a water inlet end 611 and a water outlet end 612, the water inlet end 611 corresponds to the water outlet 37 of the water permeable brick 3, so that water falling from the water outlet 37 enters the carrier 61 from the water outlet end 612; the water outlet end 612 corresponds to the water receiving pipe 4, and the area of the end surface of the water outlet end 612 is smaller than the area of the opening of the water receiving pipe 4, so that water coming out of the water outlet end 612 enters the water receiving pipe 4.

The water absorbing member 62 is made of water absorbing material, and in this embodiment, the water absorbing member 62 is sponge. The absorbent member 62 is positioned within the carrier 61, and the absorbent member 62 abuts against the inner side wall of the carrier 61. When stones fall from the gap between two adjacent water permeable bricks 3, the stones are abutted against the water absorbing piece 62, and because the water absorbing piece 62 of the embodiment is a sponge, the sponge has certain elasticity and can bounce the stones open, the stones are not positioned on the stone blocking piece 6, and if the stones cannot be bounced open, the stones are also positioned on the stone blocking piece 6, and the stones cannot enter the water receiving pipe 4; when water falls from the gap between two adjacent water permeable bricks 3, the water can be absorbed by the water absorbing piece 62, and after the water absorbing piece 62 absorbs water, due to gravity, the excess water flows out from the lower part of the water absorbing piece 62, namely from the water outlet 37 of the bearing device 61, so that the water flows into the water receiving pipe 4.

In order to prevent stones of the stone blocking member 6 from easily staying on the stone blocking member 6, the upper end of the water absorbing member 62 protrudes from the carrier 61, and the upper end surface of the water absorbing member 62 protrudes outward. When the stones fall on the water absorbing member 62, the stones abut against the upper end surface of the water absorbing member 62, so that the water absorbing member 62 ejects the stones, and the upper end surface of the water absorbing member 62 protrudes outward, so that the stones are not likely to stay on the water absorbing member 62.

Referring to fig. 10 and 11, a filter element 41 is disposed in the water receiving pipe 4, and the filter element 41 is connected to the water receiving pipe 4 in a sliding manner, so that the filter element 41 can be detached from the water receiving pipe 4. The filter element 41 is internally provided with a purifying material which can be one or more of zeolite, activated carbon, calcium sulfite, PAV non-woven fabric and the like, and the water passing through the water receiving pipe 4 is primarily filtered through the purifying material to remove part of impurities.

The paving structure further comprises a water retaining piece 7, the water retaining piece 7 comprises a driving motor 71 and a baffle 72, the driving motor 71 is fixedly connected with the outer side wall of the water receiving pipe 4, the output shaft of the driving motor 71 is fixedly connected with the baffle 72, the baffle 72 is located between the water receiving pipe 4 and the carrier 61, and water of the carrier 61 is not prone to dropping into the water receiving pipe 4 due to blocking of the baffle 72. Wherein, the output shaft of the driving motor 71 is eccentrically connected with the baffle 72, so that after the driving motor 71 drives the baffle 72 to rotate by taking the output shaft of the driving motor 71 as a central shaft, the baffle 72 does not block the water receiving pipe 4 any more, and the water of the carrier 61 falls into the water receiving pipe 4.

The side of the baffle 72 far from the water receiving pipe 4 is provided with a diversion trench 73, and the circumferential side of the baffle 72 is provided with a diversion port 74 communicated with the diversion trench 73, so that water in the diversion trench 73 flows out from the diversion port 74. When water falls from the stone blocking piece 6, the water falls into the diversion groove 73 of the baffle plate 72 and then flows out from the diversion port 74, so that the water cannot directly enter the water receiving pipe 4.

The pavement structure further comprises a rainwater sensor and a control terminal, the rainwater sensor and the control terminal can be arranged on trees beside the road, on telegraph poles and the like, the rainwater sensor is electrically connected with the control terminal, and the control terminal is electrically connected with the driving motor 71. When the rain sensor detects rain, the rain sensor transmits a signal to the control terminal, and the control terminal controls the driving motor 71 to act, so that the baffle plate 72 rotates 180 degrees above the water receiving pipe 4, and the baffle plate 72 does not cover the water receiving pipe 4; when the rain sensor cannot detect rain, the rain sensor transmits a signal to the control terminal, the control terminal controls the driving motor 71 to act, the baffle plate 72 rotates 180 degrees again, and the baffle plate 72 covers the water receiving pipe 4 again.

The implementation principle of the road pavement structure in the sponge city in the embodiment of the application is as follows: when raining, the driving motor 71 drives the baffle plate 72 to rotate, so that the baffle plate 72 does not block the water receiving pipe 4, then rainwater drips onto the stone blocking piece 6 from a gap between two adjacent water permeable bricks 3, when the water absorbing piece 62 absorbs water, the water drips from the bearing device 61 and enters the water receiving pipe 4, and the water is filtered by the filter element 41 and then enters the drain pipe 5 to be discharged into a water source.

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 (7)

1. The utility model provides a road pavement structure in sponge city which characterized in that: the rainwater drainage system comprises a foundation (1), a support column (2) and a water permeable brick (3), wherein the foundation (1), the support column (2) and the water permeable brick (3) are sequentially arranged from bottom to top, the foundation (1) is provided with a water receiving pipe (4) for receiving rainwater, a drainage pipe (5) connected with the water receiving pipe (4) is pre-buried in the foundation (1), and a water outlet (37) of the drainage pipe (5) is connected with a water source; be provided with between brick (3) and the water receiving pipe (4) and keep off stone spare (6) permeate water, keep off stone spare (6) including support in loader (61) of ground (1) and locate water absorption spare (62) in loader (61), loader (61) have with delivery port (37) corresponding intake end (611) and with water receiving pipe (4) corresponding play water end (612), the protruding device in upper end face of water absorption spare (62).

2. The road paving structure of the sponge city according to claim 1, characterized in that: the support column (2) is provided with a clamping groove (21) for the water permeable bricks (3) to be embedded, and the water receiving pipe (4) is located below the space between the two adjacent water permeable bricks (3).

3. The road paving structure of the sponge city according to claim 1, characterized in that: mounting groove (31) have been seted up to the top surface of brick (3) of permeating water, permeate water brick (3) in be provided with the permeable pad (32) that has the hole of permeating water in mounting groove (31), a plurality of water conservancy diversion passageways (33) have been seted up in brick (3) of permeating water, the one end and the mounting groove (31) of water conservancy diversion passageway (33) are linked together, and the other end link up mutually with one of them circumference side of brick (3) of permeating water.

4. The road paving structure of the sponge city according to claim 3, characterized in that: all circumferential sides of the water permeable bricks (3) are provided with two water guide blocks (34), a water guide cavity (35), a water inlet (36) communicated with the water guide cavity (35) and a water outlet (37) communicated with the water guide cavity (35) are formed between the two water guide blocks (34) on the same circumferential side, the water receiving pipe (4) is located below the water outlet (37), and the water guide channel (33) is communicated with the water guide cavity (35).

5. The road paving structure of the sponge city according to claim 4, characterized in that: each water guide block (34) comprises a contact part (341) which is in contact with the support column (2) and a water guide part (342) which is connected with the contact part (341), and the water guide part (342) is obliquely arranged towards the water outlet (37).

6. The road paving structure of the sponge city according to claim 1, characterized in that: the structure of mating formation is still including top water retaining member (7), rainwater sensor and the control terminal of locating water receiving pipe (4), water retaining member (7) is including covering baffle (72) and the drive of water receiving pipe (4) baffle (72) pivoted driving motor (71), driving motor (71) with the lateral wall fixed connection of water receiving pipe (4), the rainwater sensor is connected with the control terminal electricity, the control terminal is connected with driving motor (71) electricity.

7. The road paving structure of the sponge city according to claim 6, characterized in that: the side surface of the baffle plate (72) far away from the water receiving pipe (4) is provided with a diversion trench (73), and the circumferential side surface of the baffle plate (72) is provided with a diversion port (74) communicated with the diversion trench (73).

Images