CN111670722A - Ecological corridor vegetation wall ecological regulation system - Google Patents

Abstract

The invention discloses an ecological corridor vegetation wall ecological adjusting system which comprises a wall body, wherein the side wall of the wall body is provided with a plurality of planting grooves, the upper end of the wall body is provided with a water collecting groove, a sliding plug cavity is formed in the wall body, the inner wall of the water collecting groove is connected with a sliding plate in a sliding mode, and a driving mechanism capable of driving the sliding plate to slide up and down discontinuously on the inner wall of the water collecting groove is installed in the sliding plug cavity. According to the invention, the temperature in the planting groove rises to enable the memory spring to deform and extend to push the magnetic sliding plug to slide upwards, so that the sliding plate drives the plug head to be separated from the water outlet pipeline, the planting groove is irrigated, the magnetic sliding plug moves up and down to drive the fan-shaped gear to rotate forwards and backwards, the temperature controller can intermittently energize the electromagnet under the action of the radiating fin, the magnetic sliding plug moves up and down in the inner wall of the sliding plug cavity in a reciprocating mode, water in the water collecting groove is intermittently discharged, soil in the planting groove can fully absorb the water, and water resources are saved.

Description

Ecological corridor vegetation wall ecological regulation system

Technical Field

The invention relates to the technical field of ecological galleries, in particular to an ecological regulating system for vegetation walls of an ecological gallery.

Background

In the construction process of the ecological corridor, in order to better embody the environmental protection of the ecological corridor, vegetation walls are generally constructed on two sides of the ecological corridor, and green plants are planted on two sides of the vegetation walls to further purify the air in a city.

In high temperature weather such as noon in summer, because present vegetation wall is most to adopt concrete material to make, make the moisture in the planting groove evaporate sharply, and then make the plant dehydration, make a series of harm such as withering and withering can appear in the plant, direct influence vegetation wall's effect nature, it is artifical to it to sprinkle when watering to vegetation wall at present, but the manual work is to its watering needs use tools to sprinkle it, intensity of labour is big and consume more, and very easy heatstroke when working under high temperature weather, bring harm to workman's health, in addition carry out watering to it through the manual work and can't punctual carry out corresponding watering according to the temperature in the planting groove, can't ensure the normal growth of planting inslot plant.

Therefore, the ecological corridor vegetation wall ecological regulation system is provided.

Disclosure of Invention

The invention aims to solve the defects in the prior art and provides an ecological corridor vegetation wall ecological regulation system.

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

the utility model provides an ecological corridor vegetation wall ecological regulation system, includes the wall body, the wall body lateral wall has seted up a plurality of planting grooves, and is adjacent the planting groove passes through the infiltration plate and connects, the water catch bowl has been seted up to the wall body upper end, set up the outlet conduit with the bottom intercommunication in the water catch bowl in the wall body, the outlet conduit inner wall passes through inlet channel and corresponding planting inslot wall intercommunication, set up the sliding plug chamber in the wall body, sliding plug intracavity bottom has the magnetic sliding plug through memory spring elastic connection, the memory spring lateral wall passes through the heat conduction pole and is connected with the planting groove, water catch bowl inner wall sliding connection has the slide, just the slide adopts magnetic material to make, slide lower extreme fixedly connected with and outlet conduit complex end cap, install in the sliding plug chamber and can drive the slide and be interrupted gliding actuating mechanism from top to bottom at the water catch bowl.

Preferably, actuating mechanism is including rotating the sector gear who connects at sliding plug intracavity wall, magnetism sliding plug upper end fixedly connected with and sector gear meshing's rack is located sector gear breach fixedly connected with electro-magnet, just electro-magnet and magnetism sliding plug like one sex repel each other, sector gear lateral wall fixedly connected with temperature controller, the temperature controller is connected with the electro-magnet coupling, the inner wall fixedly connected with fin of rack is kept away from in the sliding plug chamber.

Preferably, an annular cooling box is embedded in the inner wall of the water outlet pipeline, and liquid nitrogen is filled in the cooling box.

The invention has the following beneficial effects:

1. by arranging the heat conducting rod, the memory spring, the magnetic sliding plug, the magnetic plate and the plug, when the temperature in the planting groove rises, the heat conducting rod can transfer the temperature in the planting groove to the memory spring, so that the temperature on the memory spring reaches the abnormal temperature, the memory spring extends to push the magnetic sliding plug to slide upwards, the magnetic plate is driven to slide upwards, the plug is separated from the pipe orifice of the water outlet pipeline, the water in the water collecting tank enters the planting groove through the water outlet pipeline and the water inlet pipeline, the plants in the planting groove are irrigated, the plants are prevented from being watered manually, the labor intensity of workers is high, a large amount of time and energy are saved, corresponding irrigation can be accurately carried out according to the change of the temperature in the planting groove, and the normal growth of the plants is guaranteed;

2. by arranging the rack, the sector gear, the temperature controller and the radiating fin, when the temperature on the temperature controller is higher than the critical value in high-temperature weather, the temperature controller is electrified, and then the electrification generates magnetism, the rack drives the sector gear to rotate when the magnetic sliding plug moves upwards, when the sector gear rotates to be opposite to the magnetic sliding plug, the sum of the magnetic repulsion force and the gravity of the magnetic sliding plug is larger than the elastic force of the memory spring, the magnetic sliding plug moves downwards to drive the sliding plate to slide downwards, so that the plug blocks a water outlet pipeline, the magnetic sliding plug moves downwards to reverse the sector gear, when the temperature controller rotates to the radiating fin, as the temperature at the radiating fin is lower, the current on the temperature controller disappears, and then the magnetism disappears, so that the magnetic repulsion force does not exist between the magnetic sliding plug and the magnetic sliding plug, and the magnetic sliding plug slides upwards under the action of the memory spring, when the temperature of the soil in the planting groove is rotated to the lowest end, the environmental temperature is gradually increased to the critical value of the temperature controller, magnetism is generated, repulsive force is generated on the magnetic sliding plug, the magnetic sliding plug moves downwards, and the process is repeated, so that the water in the water collecting groove is discharged discontinuously, the soil in the planting groove can fully absorb the water, and water resources are saved;

3. through setting up cooling box and liquid nitrogen, can cool off the water in the outlet conduit, avoid the temperature rise in the water catch bowl under high temperature weather for the higher water of temperature waters the plant, leads to the production of heat evil phenomenon, and then harms the normal growth of plant.

Drawings

Fig. 1 is a schematic structural diagram of a first embodiment of the present invention;

FIG. 2 is an enlarged view of the structure at A in FIG. 1;

FIG. 3 is a schematic structural diagram of a second embodiment of the present invention;

fig. 4 is an enlarged schematic view of the structure at B in fig. 3.

In the figure: 1 wall body, 2 planting grooves, 3 osmotic plates, 4 water collecting grooves, 5 sliding plug cavities, 6 water outlet pipelines, 7 water inlet pipelines, 8 memory springs, 9 magnetic sliding plugs, 10 heat conducting rods, 11 sliding plates, 12 plugs, 13 racks, 14 sector gears, 15 and 16 temperature controllers, 17 radiating fins and 18 cooling boxes.

Detailed Description

In order to make the aforementioned objects, features and advantages of the present invention comprehensible, embodiments accompanied with figures are described in detail below. In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present invention. This invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein, but rather should be construed as broadly as the present invention is capable of modification in various respects, all without departing from the spirit and scope of the present invention.

It will be understood that when an element is referred to as being "secured to" another element, it can be directly on the other element or intervening elements may also be present. When an element is referred to as being "connected" to another element, it can be directly connected to the other element or intervening elements may also be present. The terms "vertical," "horizontal," "left," "right," and the like as used herein are for illustrative purposes only and do not represent the only embodiments.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. The terminology used in the description of the invention herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. As used herein, the term "and/or" includes any and all combinations of one or more of the associated listed items.

Example one

Referring to fig. 1-2, an ecological corridor vegetation wall ecological regulation system comprises a wall body 1, wherein a plurality of planting grooves 2 are formed in the side wall of the wall body 1, adjacent planting grooves 2 are connected through a penetration plate 3, further, water outlets are formed in the inner walls of the planting grooves 2 at the lowest end of the wall body 1, excessive water in the planting grooves 2 can be drained in a penetrating manner under the action of the penetration plate 3, the phenomenon that more water accumulates in the planting grooves 2 and normal growth of plants is influenced is avoided, a water collecting groove 4 is formed in the upper end of the wall body 1, water in the water collecting groove 4 can be supplemented externally or collected through rainwater, a water outlet pipeline 6 communicated with the bottom in the water collecting groove 4 is formed in the wall body 1, the inner wall of the water outlet pipeline 6 is communicated with the inner wall of the corresponding planting groove 2 through a water inlet pipeline 7, a sliding plug cavity 5 is formed in the wall body 1, and a magnetic sliding plug 9 is elastically connected to the bottom in, the side wall of the memory spring 8 is connected with the planting groove 2 through the heat conducting rod 10, furthermore, through holes are formed in the upper portion and the lower portion of the inner wall of the sliding plug cavity 5, pressure generated when the magnetic sliding plug 9 moves is balanced, the memory spring 8 is made of a nickel-titanium memory alloy material, the metamorphosis temperature of the nickel-titanium memory alloy material is 40 ℃, namely when the temperature in the planting groove 2 reaches the metamorphosis temperature of the memory spring 8, the memory spring 8 extends, when the temperature in the planting groove 2 is lower than the metamorphosis temperature of the memory spring 8, the memory spring 8 recovers to an initial state, the inner wall of the water collecting groove 4 is slidably connected with the sliding plate 11, the sliding plate 11 is made of a magnetic material, the lower end of the sliding plate 11 is fixedly connected with a plug 12 matched with the water outlet pipeline 6, and a driving mechanism capable of driving the sliding plate 11.

The driving mechanism comprises a sector gear 14 which is rotatably connected on the inner wall of the sliding plug cavity 5, the upper end of the magnetic sliding plug 9 is fixedly connected with a rack 13 which is meshed with the sector gear 14, the electromagnet 15 is fixedly connected at the notch of the sector gear 14, the like poles of the electromagnet 15 and the magnetic sliding plug 9 repel each other, the side wall of the sector gear 14 is fixedly connected with a temperature controller 16, the temperature controller 16 is coupled with the electromagnet 15, further, the temperature controller 16 can control the on-off of the current on the electromagnet 15 according to the temperature in the sliding plug cavity 5, when the magnetic sliding plug 9 moves upwards, the integral temperature in the sliding plug cavity 5 is higher at the moment, the temperature controller 16 can electrify the electromagnet 15 and generate magnetism, when the electromagnet 15 rotates to be aligned with the magnetic sliding plug 9 along with the rising of the magnetic sliding plug 9, the sum of the magnetic repulsion force of the electromagnet 15 to the magnetic sliding plug 9 and the gravity of the magnetic sliding plug 9, therefore, the magnetic sliding plug 9 moves downwards, the radiating fins 17 are fixedly connected to the inner wall, far away from the rack 13, of the sliding plug cavity 5, further, the radiating fins 17 can radiate heat in the sliding plug cavity 5, the temperature of the position, located at the radiating fins 17, in the sliding plug cavity 5 is lower, namely the temperature of any position in the sliding plug cavity 5 is higher than that of the radiating fins 17, when the magnetic sliding plug 9 moves downwards to enable the sector gear 14 to rotate reversely, the temperature controller 16 rotates to the radiating fins 17, the temperature of the position, located at the radiating fins 17, is lower than the critical value of the temperature controller 16 at the moment, the electromagnet 15 is powered off, magnetic force between the electromagnet 15 and the magnetic sliding plug 9 disappears, and the magnetic sliding plug 9 slides upwards under the action of the memory spring 8.

In the embodiment, when the temperature in the planting groove 2 rises in high-temperature weather, the heat conducting rod 10 transfers the temperature in the planting groove 2 to the memory spring 8, when the temperature on the memory spring 8 reaches the abnormal temperature, the memory spring 8 extends to push the magnetic sliding plug 9 to move upwards in the sliding plug cavity 5, further to drive the sliding plate 11 to move upwards on the inner wall of the water collecting groove 4, to drive the plug 12 fixedly connected to the lower end of the sliding plate 11 to be separated from the water outlet pipe 6, so that the water in the water collecting groove 4 flows out through the water outlet pipe 6 and is irrigated in the planting groove 2 from the water inlet pipe 7, the magnetic sliding plug 9 moves upwards to drive the rack 13 fixedly connected to the upper end of the magnetic sliding plug 9 to drive the sector gear 14 meshed with the magnetic sliding plug to rotate, because the integral temperature in the sliding plug cavity 5 is higher at the moment, the temperature controller 16 is electrified and generates magnetism to the electromagnet 15 coupled with the magnetic sliding plug, and rotates to the electromagnet 15 to be, at this time, the sum of the magnetic repulsion of the electromagnet 15 to the magnetic sliding plug 9 and the gravity of the magnetic sliding plug 9 is greater than the elastic force of the memory spring 8, so that the magnetic sliding plug 9 slides downwards, and the sliding plate 11 slides downwards to drive the plug 12 to plug the water outlet pipeline 6;

the magnetic sliding plug 9 moves downwards to enable the rack 13 to drive the sector gear 14 to rotate reversely, when the temperature controller 16 rotates to the radiating fin 17, the temperature of the radiating fin 17 is lower than the critical value of the temperature controller 16 at the moment, the electromagnet 15 is powered off, further the magnetic force between the electromagnet 15 and the magnetic sliding plug 9 disappears, the magnetic sliding plug 9 slides upwards under the action of the memory spring 8, the sliding plate 11 drives the plug 12 to be separated from the water outlet pipeline 6, the magnetic sliding plug 9 moves upwards to drive the sector gear 14 to rotate forwards, when the temperature controller 16 is separated from the radiating fin 17, the temperature in the sliding plug cavity 5 reaches the critical value of the temperature controller 16 at the moment, the electromagnet 15 is powered on continuously, when the electromagnet 15 and the magnetic sliding plug 9 are opposite, the magnetic sliding plug 9 slides downwards, the process is repeated, the plug 12 is blocked with the water outlet pipeline 6 discontinuously, and the water in the water collecting tank 4 enters the planting tank 2 discontinuously, so that the soil in the planting groove 2 can fully absorb water and reduce the waste of water resources.

Example two

Referring to fig. 3-4, different from the first embodiment, the inner wall of the water outlet pipe 6 is embedded with the annular cooling box 18, and the cooling box 18 is filled with liquid nitrogen, further, the liquid nitrogen has a lower boiling point under normal temperature adjustment, and is mostly used as a refrigerant, so that the water flowing through the water outlet pipe can be rapidly cooled.

In this embodiment, when water flows through the outlet conduit 6, the liquid nitrogen filled in the cooling box 18 can rapidly cool the water, the cooled water can reduce the temperature of the soil in the planting groove 2, and the water temperature in the water collecting groove 4 is prevented from rising in high-temperature weather, so that the water with higher temperature waters the plants, the heat damage phenomenon is caused, and the normal growth of the plants is damaged.

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 considered to be within the technical scope of the present invention, and the technical solutions and the inventive concepts thereof according to the present invention should be equivalent or changed within the scope of the present invention.

Claims (3)

1. The ecological corridor vegetation wall ecological regulation system comprises a wall body (1) and is characterized in that the side wall of the wall body (1) is provided with a plurality of planting grooves (2), the planting grooves (2) are adjacent to each other and are connected through penetration plates (3), the upper end of the wall body (1) is provided with a water collecting groove (4), a water outlet pipeline (6) communicated with the inner bottom of the water collecting groove (4) is arranged in the wall body (1), the inner wall of the water outlet pipeline (6) is communicated with the inner wall of the corresponding planting groove (2) through a water inlet pipeline (7), a sliding plug cavity (5) is arranged in the wall body (1), the inner bottom of the sliding plug cavity (5) is elastically connected with a magnetic sliding plug (9) through a memory spring (8), the side wall of the memory spring (8) is connected with the planting grooves (2) through a heat conducting rod (10), and the inner wall of the water collecting groove (4) is slidably, the sliding plate (11) is made of a magnetic material, a plug (12) matched with the water outlet pipeline (6) is fixedly connected to the lower end of the sliding plate (11), and a driving mechanism capable of driving the sliding plate (11) to intermittently slide up and down on the inner wall of the water collecting tank (4) is installed in the sliding plug cavity (5).

2. The ecological regulating system of claim 1, characterized in that actuating mechanism includes the sector gear (14) of rotation connection at sliding plug chamber (5) inner wall, magnetism sliding plug (9) upper end fixedly connected with sector gear (14) meshing rack (13), be located fixedly connected with electro-magnet (15) of sector gear (14) breach department, just electro-magnet (15) and magnetism sliding plug (9) homopolar repulsion each other, sector gear (14) lateral wall fixedly connected with temperature controller (16), temperature controller (16) and electro-magnet (15) coupling are connected, the inner wall fixedly connected with fin (17) of rack (13) are kept away from in sliding plug chamber (5).

3. The ecological regulating system for vegetation walls of ecological galleries according to claim 1, characterized in that the inner wall of the water outlet pipe (6) is embedded with an annular cooling box (18), and the cooling box (18) is filled with liquid nitrogen.

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