CN111535619A

CN111535619A - Ecological landscape corridor for intelligent three-dimensional rainwater recycling

Info

Publication number: CN111535619A
Application number: CN202010392888.3A
Authority: CN
Inventors: 时小兵; 王洋; 李善华
Original assignee: China MCC17 Group Co Ltd
Current assignee: China MCC17 Group Co Ltd
Priority date: 2020-05-11
Filing date: 2020-05-11
Publication date: 2020-08-14
Anticipated expiration: 2040-05-11
Also published as: CN111535619B

Abstract

The invention relates to the technical field of galleries, and discloses an intelligent three-dimensional rainwater recycling ecological landscape gallery which comprises a gallery body, wherein a collection box with an opening at the upper end is installed at the top of the gallery body, a plurality of support plates are evenly and equidistantly installed on the vertical inner side wall of the gallery body along a straight line, flowerpots are arranged at the tops of the support plates, a transfer box and a water supply box are fixedly connected to the outer side wall of the gallery body, which is opposite to the outer side wall, of the gallery body in a vertical direction from top to bottom in sequence, a first water pipe is fixedly communicated with the outer wall of the top of the transfer box, the other end of the first water pipe is communicated with the collection box, a water outlet pipe and a water inlet pipe are fixedly communicated with the outer wall of the transfer box, which is far away from the gallery body, in the vertical direction from top to bottom in sequence, the other end of the water outlet. The invention uses rainwater to irrigate when rainwater exists, and uses external water source to irrigate automatically when rainwater does not exist.

Description

Ecological landscape corridor for intelligent three-dimensional rainwater recycling

Technical Field

The invention relates to the technical field of galleries, in particular to an intelligent three-dimensional ecological landscape gallery for rainwater recycling.

Background

The landscape corridor is a strip hill or land which is different from the background and has a characteristic, the landscape corridor emphasizes the landscape function, the corridor (corridor) in landscape ecology is a linear or strip landscape element different from the surrounding landscape substrate, and the ecological corridor (ecological corridor) is a corridor type with the ecological service functions of protecting biodiversity, filtering pollutants, preventing water and soil loss, preventing wind and fixing sand, regulating and controlling flood and the like. The ecological corridor is mainly composed of ecological structural elements such as vegetation, water bodies and the like, and is the same concept as a green corridor (green corridor). The american society for protection and Management (USA) defines the ecological corridor as "narrow-banded vegetation for wild animals, which generally promotes movement of biological factors between two regions" from the point of view of biological protection.

In order to improve utilization efficiency, rainwater needs to be collected in rainy days, the rainwater collected in rainy days is often insufficient, and therefore manual water feeding is needed, and further operation is inconvenient.

Disclosure of Invention

The invention aims to solve the problem of the use of the traditional landscape corridor in the prior art, and provides an intelligent three-dimensional rainwater recycling ecological landscape corridor.

In order to achieve the purpose, the invention adopts the following technical scheme:

an ecological landscape corridor for intelligent three-dimensional rainwater recycling comprises a corridor body, wherein a collecting box with an opening at the upper end is installed at the top of the corridor body, a plurality of supporting plates are installed on the vertical inner side wall of the corridor body along a straight line at uniform intervals, flowerpots are arranged at the tops of the supporting plates, a transfer box and a water supply box are fixedly connected on the back outer side walls of the corridor body from top to bottom in sequence along the vertical direction, a first water pipe is fixedly communicated with the outer wall of the top of the transfer box, the other end of the first water pipe is communicated with the collecting box, a water outlet pipe and a water inlet pipe are fixedly communicated with the outer wall of the transfer box far away from the corridor body from the top to bottom in sequence along the vertical direction, the other end of the water outlet pipe is communicated with the water supply box, the other end of the water inlet pipe is externally connected with a water source, sponges are fixedly connected in the, a second water pipe is fixedly communicated with the wall of the water supply tank close to the gallery body, and the other end of the second water pipe extends into the sponge; an adjusting mechanism and a valve plate mechanism are installed in the transfer box, and a floating mechanism is installed in the water supply box.

Preferably, the adjusting mechanism comprises two first springs and a sealing plate, the two first springs are symmetrically and fixedly connected to the inner box bottom of the transfer box, the upper ends of the two first springs are fixedly connected with the sealing plate, and the sealing plate is in sealing sliding connection with the inner box wall of the transfer box through a sealing mechanism.

Preferably, the valve plate mechanism comprises a first T-shaped sliding groove, a first T-shaped sliding block, a first valve plate and a second spring, the first T-shaped sliding groove is formed in the inner box wall of the transfer box between the water outlet pipe and the water inlet pipe, the first T-shaped sliding groove is located under the sealing plate, the first T-shaped sliding block is connected in the first T-shaped sliding groove in a sliding mode, one end, far away from the bottom of the first T-shaped sliding groove, of the first T-shaped sliding block penetrates through the notch of the first T-shaped sliding groove and extends outwards, and is fixedly connected with the first valve plate, the second spring is fixedly connected to the bottom groove wall of the first T-shaped sliding groove, and the upper end of the second spring is fixedly connected with the first T-shaped sliding block.

Preferably, the floating mechanism comprises a second T-shaped sliding groove, a second T-shaped sliding block, a floating rod, a second valve plate and a floating ball, liquid water is filled in the water supply tank, the second T-shaped sliding groove is formed in the inner tank wall, far away from the corridor body, of the water supply tank, the second T-shaped sliding block is connected in the second T-shaped sliding groove in a sliding mode, one end, far away from the bottom of the second T-shaped sliding groove, of the second T-shaped sliding block penetrates through a notch of the second T-shaped sliding groove and extends outwards, and is fixedly connected with the floating rod, the second valve plate is fixedly connected to the upper end of the floating rod, the floating ball is fixedly connected to the lower end of the floating rod, and the floating ball and the water surface.

Preferably, a ball groove is formed in one end, close to the bottom of the first T-shaped sliding groove, of the first T-shaped sliding block, a ball is connected in the ball groove in a rolling mode, and one end, far away from the bottom of the ball groove, of the ball penetrates through a notch of the ball groove and extends outwards and is connected with the bottom of the first T-shaped sliding groove in a rolling mode.

Preferably, sealing mechanism includes seal groove and sealed the pad, the section of seal groove and sealed pad all is the annular setting, the seal groove is seted up on the annular lateral wall of closing plate, sealed pad fixed connection is in the seal groove, the notch and the outside extension of seal groove are passed to the one end that sealed pad kept away from the seal groove tank bottom, and with the sealed sliding connection of inner box wall of transfer case.

Preferably, the box opening of the collecting box is fixedly connected with a filter screen.

Preferably, a valve is arranged on the water inlet pipe.

Preferably, the collection box, the transfer box and the water delivery box are coated with antirust paint.

Compared with the prior art, the invention provides an intelligent three-dimensional rainwater recycling ecological landscape corridor, which has the following beneficial effects:

according to the intelligent three-dimensional rainwater recycling ecological landscape corridor, by arranging the water supply tank, the transfer tank, the first water pipe, the water outlet pipe, the adjusting mechanism, the first spring, the sealing plate, the valve plate mechanism, the first T-shaped chute, the first T-shaped slide block, the first valve plate, the second spring, the floating mechanism, the second T-shaped chute and the second T-shaped slide block, rainwater is collected by the collecting box in rainy days, then the rainwater flows into the transfer tank through the first water pipe, further the rainwater applies pressure to the sealing plate, further the first spring is compressed, the sealing plate applies thrust to the first valve plate along with the increase of the rainwater, further the first valve plate seals the water inlet pipe, and further the rainwater flows into the water supply tank through the water outlet pipe; when the water level in the water supply tank descends, the second valve plate descends under the action of the floating ball, and the water outlet pipe supplies water to the water supply tank; after the water of rainy day used up, first spring reset closing plate upwards moved, and then the second spring makes first valve plate reset, and then the inlet tube is in the transfer case with outside water source conveying, and along with the rising water in the inlet tube of closing plate flows to sending the water tank in through the outlet pipe, and then utilizes the rainwater to water when having the rainwater, does not have the rainwater to utilize external water source automatic watering.

The parts not involved in the device are the same as or can be realized by the prior art, the device utilizes rainwater to irrigate when rainwater exists, and no rainwater is automatically irrigated by utilizing an external water source.

Drawings

FIG. 1 is a schematic structural view of an ecological landscape corridor for intelligent three-dimensional rainwater reuse according to the present invention;

FIG. 2 is a schematic view of a connection structure of a transfer box, a water supply box and a gallery body of the ecological landscape gallery for intelligent three-dimensional rainwater reuse, which is provided by the invention;

FIG. 3 is an enlarged view of portion A of FIG. 2;

fig. 4 is an enlarged view of a portion B in fig. 2.

In the figure: the device comprises a gallery body 1, a collecting box 2, a water feeding box 3, a transfer box 4, a first water pipe 5, a water outlet pipe 6, an adjusting mechanism 7, a first spring 71, a sealing plate 72, a valve plate mechanism 8, a first T-shaped sliding groove 81, a first T-shaped sliding block 82, a first valve plate 83, a second spring 84, a floating mechanism 9, a second T-shaped sliding groove 91, a second T-shaped sliding block 92, a floating rod 93, a second valve plate 94, a floating ball 95, a water inlet pipe 10, a second water pipe 11, a ball groove 12, balls 13, a sealing groove 14 and a sealing groove 15.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments.

Referring to fig. 1-4, an ecological landscape corridor for intelligent three-dimensional rainwater recycling comprises a corridor body 1, a collection box 2 with an opening at the upper end is installed at the top of the corridor body 1, a plurality of support plates are evenly and equidistantly installed on the vertical inner side wall of the corridor body 1 along a straight line, flowerpots are arranged at the tops of the support plates, a transfer box 4 and a water supply box 3 are fixedly connected to the opposite outer side walls of the corridor body 1 from top to bottom in sequence along the vertical direction, a first water pipe 5 is fixedly communicated with the outer wall at the top of the transfer box 4, the other end of the first water pipe 5 is communicated with the collection box 2, a water outlet pipe 6 and a water inlet pipe 10 are fixedly communicated with the outer wall of the transfer box 4 far away from the corridor body 1 from top to bottom in sequence along the vertical direction, the other end of the water outlet pipe 6 is communicated with the water supply box 3, the other end of the, soil is filled in the flowerpot, a second water pipe 11 is fixedly communicated with the wall of the water delivery tank 3 close to the gallery body 1, and the other end of the second water pipe 11 extends into the sponge; the transfer case 4 is internally provided with an adjusting mechanism 7 and a valve plate mechanism 8, the water supply case 3 is internally provided with a floating mechanism 9, the adjusting mechanism 7 comprises two first springs 71 and a sealing plate 72, the two first springs 71 are symmetrically and fixedly connected with the inner bottom of the transfer case 4, the upper ends of the two first springs 71 are fixedly connected with the sealing plate 72, the sealing plate 72 is in sealing sliding connection with the inner case wall of the transfer case 4 through the sealing mechanism, the valve plate mechanism 8 comprises a first T-shaped sliding groove 81, a first T-shaped sliding block 82, a first valve plate 83 and a second spring 84, the first T-shaped sliding groove 81 is arranged on the inner case wall of the transfer case 4 between the water outlet pipe 6 and the water inlet pipe 10, the first T-shaped sliding groove 81 is positioned under the sealing plate 72, the first T-shaped sliding block 82 is in the first T-shaped sliding groove 81, one end of the first T-shaped sliding block 82, far away from the bottom of the first T-shaped sliding groove 81, penetrates through the notch of the first T-shaped, and is fixedly connected with the first valve plate 83, the second spring 84 is fixedly connected on the bottom groove wall of the first T-shaped chute 81, and the upper end of the second spring 84 is fixedly connected with the first T-shaped sliding block 82, the floating mechanism 9 comprises a second T-shaped chute 91, a second T-shaped sliding block 92, a floating rod 93, a second valve plate 94 and a floating ball 95, the water supply tank 3 is filled with liquid water, the second T-shaped chute 91 is arranged on the inner tank wall of the water supply tank 3 far away from the gallery body 1, the second T-shaped sliding block 92 is slidably connected in the second T-shaped chute 91, one end of the second T-shaped sliding block 92 far away from the bottom of the second T-shaped chute 91 passes through the notch of the second T-shaped chute 91 and extends outwards and is fixedly connected with the floating rod 93, the second valve plate 94 is fixedly connected on the upper end of the floating rod 93, the floating ball 95 is fixedly connected on the lower end of the floating rod 93, and the floating ball 95 floats on the water, then rainwater flows into the transit box 4 through the first water pipe 5, further rainwater applies pressure to the sealing plate 72, further the first spring 71 is compressed, the sealing plate 72 applies thrust to the first valve plate 83 along with the increase of the rainwater, further the first valve plate 83 seals the water inlet pipe 10, and further the rainwater flows into the water supply box 3 through the water outlet pipe 6; liquid water in the water supply tank 3 moves into the sponge of the flowerpot through the second water pipe 11, the sponge locks water for utilization of soil, when the water level in the water supply tank 3 descends, the second valve plate 94 descends under the action of the floating ball 95, and then the water outlet pipe 6 supplies water into the water supply tank 3; after the water in the rainy day is used up, the first spring 71 resets the sealing plate 72 to move upwards, and then the second spring 84 enables the first valve plate 83 to reset, and then the water inlet pipe 10 conveys an external water source into the transit box 4, the water in the water inlet pipe 10 flows into the water conveying box 3 through the water outlet pipe 6 along with the rising of the sealing plate 72, and then the rainwater is used for irrigating when rainwater exists, and no rainwater is used for automatically irrigating by using an external water source.

The ball groove 12 is opened to the one end that first T type slider 82 is close to first T type spout 81 tank bottom, and ball 13 is connected to the roll in the ball groove 12, and the one end that ball 13 kept away from the ball groove 12 tank bottom passes ball groove 12 notch and outwards extends, and with the tank bottom roll connection of first T type spout 81, makes the more swift of first T type slider 82 motion.

Sealing mechanism includes seal groove 14 and sealed the pad 15, and the section of seal groove 14 and sealed pad 15 all is the annular setting, and seal groove 14 is seted up on the annular lateral wall of closing plate 72, and sealed pad 15 fixed connection is in seal groove 14, and sealed pad 15 is kept away from the one end of seal groove 14 tank bottom and is passed the notch of seal groove 14 and outwards extend, and with the sealed sliding connection of interior tank wall of transfer case 4, improves the sealed effect of closing plate 72.

The case mouth fixedly connected with filter screen of collecting box 2 prevents that impurity from getting into in collecting box 2.

A valve is arranged on the water inlet pipe 10, so that the water inlet pipe 10 can be conveniently closed.

The collection box 2, the transfer box 4 and the water supply tank 3 are all coated with antirust paint, so that the situation that the collection box 2, the transfer box 4 and the water supply tank 3 are rusted is prevented.

In the invention, in rainy days, rainwater is collected by the collection box 2, then the rainwater flows into the transfer box 4 through the first water pipe 5, then the rainwater applies pressure to the sealing plate 72, so that the first spring 71 is compressed, the sealing plate 72 applies thrust to the first valve plate 83 along with the increase of the rainwater, then the first valve plate 83 seals the water inlet pipe 10, and then the rainwater flows into the water supply box 3 through the water outlet pipe 6; liquid water in the water supply tank 3 moves into the sponge of the flowerpot through the second water pipe 11, the sponge locks water for utilization of soil, when the water level in the water supply tank 3 descends, the second valve plate 94 descends under the action of the floating ball 95, and then the water outlet pipe 6 supplies water into the water supply tank 3; after the water in the rainy day is used up, the first spring 71 resets the sealing plate 72 to move upwards, and then the second spring 84 enables the first valve plate 83 to reset, and then the water inlet pipe 10 conveys an external water source into the transit box 4, the water in the water inlet pipe 10 flows into the water conveying box 3 through the water outlet pipe 6 along with the rising of the sealing plate 72, and then the rainwater is used for irrigating when rainwater exists, and no rainwater is used for automatically irrigating by using an external water source.

The above description is only for the preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art should be able to cover the technical scope of the present invention and the equivalent alternatives or modifications according to the technical solution and the inventive concept of the present invention within the technical scope of the present invention.

Claims

1. The ecological landscape corridor for intelligent three-dimensional rainwater recycling comprises a corridor body (1) and is characterized in that a collecting box (2) with an opening at the upper end is installed at the top of the corridor body (1), a plurality of supporting plates are installed on the vertical inner side wall of the corridor body (1) along a straight line at uniform intervals, flowerpots are arranged at the tops of the supporting plates, a transfer box (4) and a water delivery box (3) are fixedly connected on the back outer side wall of the corridor body (1) in sequence from top to bottom along the vertical direction, a first water pipe (5) is fixedly communicated on the outer wall of the top of the transfer box (4), the other end of the first water pipe (5) is communicated with the collecting box (2), a water outlet pipe (6) and a water inlet pipe (10) are fixedly communicated on the outer wall of the corridor body (1) far away from the transfer box (4) in sequence from the top to bottom along the vertical direction, the other end of the water outlet pipe (6) is communicated with the water delivery tank (3), the other end of the water inlet pipe (10) is externally connected with a water source, sponge is fixedly connected in the flowerpot, soil is filled in the flowerpot, a second water pipe (11) is fixedly communicated on the wall, close to the corridor body (1), of the water delivery tank (3), and the other end of the second water pipe (11) extends into the sponge; an adjusting mechanism (7) and a valve plate mechanism (8) are installed in the transfer case (4), and a floating mechanism (9) is installed in the water supply tank (3).

2. The ecological landscape corridor for intelligent three-dimensional rainwater recycling according to claim 1, wherein the adjusting mechanism (7) comprises two first springs (71) and a sealing plate (72), the two first springs (71) are symmetrically and fixedly connected to the inner bottom of the transfer box (4), the upper ends of the two first springs (71) are fixedly connected to the sealing plate (72), and the sealing plate (72) is in sealing sliding connection with the inner box wall of the transfer box (4) through a sealing mechanism.

3. The ecological landscape corridor for intelligent three-dimensional rainwater recycling according to claim 1, wherein the valve plate mechanism (8) comprises a first T-shaped sliding groove (81), a first T-shaped sliding block (82), a first valve plate (83) and a second spring (84), the first T-shaped sliding groove (81) is formed in the inner wall of the transit box (4) between the water outlet pipe (6) and the water inlet pipe (10), the first T-shaped sliding groove (81) is located right below the sealing plate (72), the first T-shaped sliding block (82) is slidably connected in the first T-shaped sliding groove (81), one end, far away from the bottom of the first T-shaped sliding groove (81), of the first T-shaped sliding block (82) penetrates through the notch of the first T-shaped sliding groove (81) and extends outwards and is fixedly connected with the first valve plate (83), and the second spring (84) is fixedly connected to the bottom of the first T-shaped sliding groove (81), and the upper end of the second spring (84) is fixedly connected with the first T-shaped sliding block (82).

4. The ecological landscape corridor for intelligent three-dimensional rainwater recycling according to claim 1, wherein the floating mechanism (9) comprises a second T-shaped chute (91), a second T-shaped slide block (92), a floating rod (93), a second valve plate (94) and a floating ball (95), the water supply tank (3) is filled with liquid water, the second T-shaped chute (91) is arranged on the inner tank wall of the water supply tank (3) far away from the corridor body (1), the second T-shaped slide block (92) is slidably connected in the second T-shaped chute (91), one end of the second T-shaped slide block (92) far away from the bottom of the second T-shaped chute (91) penetrates through the notch of the second T-shaped chute (91) and extends outwards, and is fixedly connected with the floating rod (93), the second valve plate (94) is fixedly connected to the upper end of the floating rod (93), and the floating ball (95) is fixedly connected to the lower end of the floating rod (93), and the floating ball (95) floats on the water surface.

5. The ecological landscape corridor for intelligent three-dimensional rainwater recycling according to claim 3, wherein a ball groove (12) is formed in one end, close to the groove bottom of the first T-shaped sliding groove (81), of the first T-shaped sliding block (82), a ball (13) is connected in the ball groove (12) in a rolling manner, and one end, far away from the groove bottom of the ball groove (12), of the ball (13) penetrates through the notch of the ball groove (12), extends outwards and is connected with the groove bottom of the first T-shaped sliding groove (81) in a rolling manner.

6. The ecological landscape corridor of three-dimensional rainwater retrieval and utilization of intelligence of claim 2, characterized in that, sealing mechanism includes seal groove (14) and sealed pad (15), the section of seal groove (14) and sealed pad (15) all is the annular setting, seal groove (14) are seted up on the annular lateral wall of closing plate (72), sealed pad (15) fixed connection is in seal groove (14), the one end that sealed pad (15) kept away from seal groove (14) tank bottom passes the notch of seal groove (14) and outwards extends, and with the sealed sliding connection of inner tank wall of transfer box (4).

7. The ecological landscape corridor for intelligent three-dimensional rainwater recycling according to claim 1, wherein a filter screen is fixedly connected to the opening of the collection box (2).

8. The ecological landscape corridor for intelligent three-dimensional rainwater recycling according to claim 1, wherein a valve is installed on the water inlet pipe (10).

9. The ecological landscape corridor for intelligent three-dimensional rainwater recycling according to claim 1, wherein the collection tank (2), the transfer tank (4) and the water supply tank (3) are coated with antirust paint.