CN222745238U - Stepped water storage and drainage facility - Google Patents

Abstract

The utility model relates to the technical field of side slope treatment engineering, in particular to a stepped water storage and drainage facility. The utility model provides a cascaded drainage facility that holds, includes wireless water level controller, water level sensor and electric power storage formula photovoltaic board, and water level sensor establishes the upper wall at the water storage jar, and the front end of water storage jar is equipped with the outlet pipe, and the outlet pipe is equipped with the water pump, and the end connection of outlet pipe has a plurality of ways distributive pipe, and every way distributive pipe all is connected with a drip pipe net, and the upper wall of water storage jar is connected with the inlet tube, and the inlet tube passes through the linking union coupling with two water collecting components that are located the water storage jar top. The stepped water storage and drainage facility can drain part of rainwater to the bottom of the side slope when raining, reduce the water content of soil in the side slope and reduce the risks of water and soil loss and instability of the side slope. And secondly, the water stored in the water storage tank can irrigate vegetation on the side slope through the water dropping pipe network after rain, which is beneficial to the growth of the vegetation on the side slope and consolidates the soil on the side slope through the vegetation.

Description

Stepped water storage and drainage facility

Technical Field

The utility model relates to the technical field of side slope treatment engineering, in particular to a stepped water storage and drainage facility.

Background

The slope stability refers to the stability degree of the slope rock and soil mass under the conditions of a certain slope height and a certain slope angle. According to the cause, the slopes are divided into natural slopes and artificial slopes. The stability of the side slope is very important, particularly in northwest mountain areas, the side slope is often a soil side slope and is often adjacent to roads, farmlands, houses and the like, the water content of the side slope soil can be increased in rainy seasons, water and soil loss is caused by the running water of the side slope to form ravines, and the side slope is seriously unstable and wholly collapses, so that life and property safety is endangered. Therefore, the method is particularly important to solve the problems that the water content of the soil is increased and the soil erosion and the instability of the side slope are caused because the rainwater on the side slope can not be removed in time in rainy seasons.

Disclosure of utility model

Aiming at the existing problems, the utility model provides a stepped water storage and drainage facility to solve the problems that in the background art, the rainwater on a side slope in rainy season cannot be removed in time, so that the water content of soil is increased, and the water loss and the instability of the side slope are caused.

In order to solve the existing problems, the utility model provides a stepped water storage and drainage facility which comprises a wireless water level controller, a water level sensor and an electric storage type photovoltaic panel, wherein the water level sensor is electrically connected with the wireless water level controller, the wireless water level controller is electrically connected with the electric storage type photovoltaic panel, the water level sensor is arranged on the upper wall of a water storage tank, a probe of the water level sensor stretches into the tank body, the front end of the water storage tank is provided with a water outlet pipe, the water outlet pipe is provided with a water pump, the water pump is electrically connected with the wireless water level controller, the end part of the water outlet pipe is connected with a plurality of water diversion pipes, each water diversion pipe is connected with a water dripping pipe network, the bottom of the water storage tank is connected with a water drain pipe, an electromagnetic valve is connected with the water drain pipe, the electromagnetic valve is electrically connected with the wireless water level controller, the upper wall of the water storage tank is connected with a water inlet pipe, the water inlet pipe is connected with two water collecting assemblies above the water storage tank through a connecting pipe, and the upper wall of the water storage tank is connected with a water inlet pipe.

Further, the water collection assembly comprises a water collection tank connected with the upper end of the water inlet pipe, a fixing frame is arranged at the upper end of the water collection tank, clamping grooves are formed in the upper surfaces of the inner sides of four sides of the fixing frame, a water collection plate is arranged in the fixing frame, a flow guide assembly is uniformly arranged on the water collection plate, clamping pieces matched with the clamping grooves are connected to the four sides of the water collection plate, and the clamping pieces are clamped in the clamping grooves.

Further, the water conservancy diversion subassembly includes the mounting hole of seting up on the water collecting plate, two arc grooves have been seted up to the symmetry on the medial surface of mounting hole, are located arc groove one end and the vertical mounting groove of seting up in the medial surface of mounting hole, mounting groove and arc groove intercommunication, install the filter screen on the mounting hole, filter screen side symmetry is provided with two archs, two protruding sliding connection are in the arc inslot, the lower limb connection of mounting hole has the honeycomb duct.

Further, the rear end fixedly connected with bracing piece of fixed frame, the electric power storage formula photovoltaic board is installed to the bracing piece upper end.

Further, the wireless water level controller is installed in the middle of the supporting rod and is provided with a protective shell.

Further, a filter cover is arranged at the upper end of the air inlet pipe.

Compared with the prior art, the utility model has the beneficial effects that:

1. This cascaded retaining facility, the rainwater falls onto the subassembly that catchments, then the rainwater flows into behind the connecting pipe through the subassembly that catchments and gets into the inside of water storage tank through the inlet tube, when the water of water storage tank is full to contact water level sensor's probe, water level sensor can give wireless water level controller with information feedback, wireless water level controller can control the bottom of water storage tank 4 be connected with the solenoid valve on the bleeder, can drain the slope bottom with the water in the water storage tank through the bleeder, avoided can't continue to collect the rainwater because of water storage tank is full, also drain partial rainwater to the slope bottom simultaneously, the water content of soil in the side slope has been reduced, side slope soil erosion and water loss and the risk that the unstability of side slope collapses have been reduced.

2. This cascaded retaining facility, after the rainy day is fine, especially hot summer, the vegetation of planting on the side slope needs the periodic irrigation, can take out the water in the water storage jar through operating wireless water level control start-up water pump this moment, the water pump, in the pressurized back shunted every way shunt tubes through the outlet pipe, vegetation on the drip pipe network watering side slope through laying on the side slope at last does so and is favorable to the growth of side slope vegetation, has consolidated side slope soil through the vegetation further, further makes the side slope more firm.

Drawings

FIG. 1 is a schematic perspective view of the structure of the present utility model;

FIG. 2 is a schematic view of a part of the structure of the present utility model;

FIG. 3 is a schematic view of the split structure of the water collection assembly of the present utility model;

FIG. 4 is a schematic view of a flow guiding assembly according to the present utility model;

FIG. 5 is an enlarged schematic view of the utility model at A of FIG. 4;

In the figure, 1, a wireless water level controller, 2, a water level sensor, 3, an electric storage type photovoltaic panel, 4, a water storage tank, 5, a water outlet pipe, 6, a water pump, 7, a water diversion pipe, 8, a water dropping pipe network, 9, a water drain pipe, 10, an electromagnetic valve, 11, a water inlet pipe, 12, a water collection component, 1201, a water collection tank, 1202, a fixed frame, 1203, a clamping groove, 1204, a water collection panel, 1205, a flow guide component, 12051, a mounting hole, 12052, an arc-shaped groove, 12053, a filter screen, 12054, a bulge, 12055, a flow guide pipe, 12056, a mounting groove, 1206, a clamping piece, 13, a connecting pipe, 14, an air inlet pipe, 15, a support rod, 16 and a filter cover;

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

Referring to fig. 1-5, a stepped water storage and drainage facility comprises a wireless water level controller 1, a water level sensor 2 and an electric storage type photovoltaic panel 3, and is characterized in that the water level sensor 2 is electrically connected with the wireless water level controller 1, the wireless water level controller 1 is electrically connected with the electric storage type photovoltaic panel 3, the water level sensor 2 is arranged on the upper wall of a water storage tank 4, a probe of the water level sensor 2 stretches into the tank body, the front end of the water storage tank 4 is provided with a water outlet pipe 5, the water outlet pipe 5 is provided with a water pump 6, the water pump 6 is electrically connected with the wireless water level controller 1, the end part of the water outlet pipe 5 is connected with a plurality of water diversion pipes 7, each water diversion pipe 7 is connected with a water dripping pipe network 8, the bottom of the water storage tank 4 is connected with a water drain pipe 9, the water drain pipe 9 is connected with an electromagnetic valve 10, the electromagnetic valve 10 is electrically connected with the wireless water level controller 1, the upper wall of the water storage tank 4 is connected with a water inlet pipe 11, two water collection components 12 above the water storage tank 4 are connected with a water inlet pipe 11 through a connecting pipe 13, and the water inlet pipe 14 is connected with one side of the water inlet pipe 14.

In the embodiment 1, when raining, rainwater falls onto the water collecting assembly 12, then the rainwater flows into the connecting pipe 13 through the water collecting assembly 12 and then enters the water storage tank 4 through the water inlet pipe 11, when the water in the water storage tank 4 is full of water and contacts with the probe of the water level sensor 2, the water level sensor 2 feeds information back to the wireless water level controller 1, the wireless water level controller 1 controls the electromagnetic valve 10 on the drain pipe 9 connected with the bottom of the water storage tank 4 to be opened, and the water in the water storage tank 4 is discharged to the bottom of a slope through the drain pipe 9, so that the situation that the rainwater cannot be continuously collected due to the full water in the water storage tank 4 is avoided, and meanwhile, part of the rainwater is discharged to the bottom of the slope, the water content of soil in the slope is reduced, and the risks of water loss and instability and collapse of the slope are reduced.

Secondly, after the rainy day is sunny, especially in hot summer, the vegetation planted on the side slope needs to be irrigated regularly, at this moment, can be through operating wireless water level control 1 start water pump 6, water in the water storage tank 4 can be taken out to water pump 6, shunts to every way shunt tubes 7 through outlet pipe 5 after the pressurization, finally irrigates the vegetation on the side slope through the drip pipe network 8 of laying on the side slope, does so and is favorable to the growth of side slope vegetation, has consolidated the side slope soil through the vegetation further, further makes the side slope more firm.

The upper wall of the water storage tank 4 is provided with the air inlet pipe 14, so that when rainwater is collected into the water storage tank 4 through the water collecting assembly 12, air in the water storage tank 4 can be rapidly discharged through the air inlet pipe 14, and the collected rainwater can be ensured to rapidly flow into the water storage tank 4. Meanwhile, if the side slope is a multi-stage side slope, a set of stepped water storage and drainage facilities can be arranged on each stage of side slope.

The water collection assembly 12 comprises a water collection tank 1201 connected with the upper end of the water inlet pipe 11, a fixing frame 1202 is arranged at the upper end of the water collection tank 1201, clamping grooves 1203 are formed in the upper surfaces of the inner sides of four sides of the fixing frame 1202, a water collection plate 1204 is arranged in the fixing frame 1202, flow guide assemblies 1205 are uniformly arranged on the water collection plate 1204, clamping pieces 1206 matched with the clamping grooves 1203 are connected to four sides of the water collection plate 1204, and the clamping pieces 1206 are clamped in the clamping grooves 1203.

The flow guiding assembly 1205 comprises a mounting hole 12051 formed in the water collecting plate 1204, two arc-shaped grooves 12052 are symmetrically formed in the inner side surface of the mounting hole 12051, a mounting groove 12056 is vertically formed in the inner side surface of the mounting hole 12051 and positioned at one end of the arc-shaped groove 12052, the mounting groove 12056 is communicated with the arc-shaped groove 12052, a filter screen 12053 is mounted on the mounting hole 12051, two protrusions 12054 are symmetrically arranged at the side end of the filter screen 12053, the two protrusions 12054 are slidably connected in the arc-shaped groove 12052, and a flow guiding pipe 12055 is connected to the lower edge of the mounting hole 12051.

By aligning two protrusions 12054 at the side end of the filter screen 12053 with two mounting grooves 12056 vertically formed on the inner side surface of the mounting hole 12051, pressing the filter screen 12053 downward drives the protrusions 12054 to slide downward in the mounting grooves 12056 and then enter the arc-shaped grooves 12052, and then rotating the filter screen 12053 to enable the protrusions and the mounting holes 12051 to slide in the arc-shaped grooves 12052 in a staggered manner and be clamped in the arc-shaped grooves 12052, so that the filter screen 12053 is fixed in the mounting holes 12051.

The rear end of the fixing frame 1202 is fixedly connected with a supporting rod 15, and the upper end of the supporting rod 15 is provided with an electric storage type photovoltaic panel 3.

The electricity storage type photovoltaic panel 3 can generate electricity and store enough electric energy in sunny days, and the electricity storage type photovoltaic panel is used for electric appliance parts of the whole facility in rainy days.

Wherein, wireless water level controller 1 installs at bracing piece 15 middle part, wireless water level controller 1 is provided with the protective housing.

It should be noted that, the wireless water level control sensor 1 belongs to the prior art, and the structure and the like thereof are not described again.

By arranging the protective shell for the wireless water level controller 1, the wireless water level controller 1 can be effectively protected from damage.

Wherein, the filter cover 16 is mounted on the upper end of the air inlet pipe 14.

By providing the filter cover 16 at the upper end of the air intake pipe 14, impurities can be filtered out, and the impurities are prevented from drifting into the air intake pipe 14.

Before use, the water storage tank 4 is buried in slope soil, the lower part of the water collection tank 1201 is buried in slope soil and is buried in parallel with the slope, the upper end of the water collection tank 1201 is ensured to be exposed out of the ground, then the fixing frame 1202 is arranged at the upper end of the water collection tank 1201, the clamping pieces 1206 on four sides of the water collection plate 1204 are pressed into the clamping grooves 1203 corresponding to the fixing frame 1202, then the connecting pipe 13 is connected with the water collection assembly 12 and the water inlet pipe 14 of the water storage tank 4, and the water outlet pipe 5 is connected with the water dropping pipe network 8 through the water distribution pipes 7. It should be noted that, although the water collecting assembly 12 is not fully covered on the side slope, one or more sets of stepped water storing and draining facilities may be provided according to the size of the side slope area, and most of the rainwater is taken away when the side slope is rainy, and only a small amount of rainwater permeates into the side slope.

In operation, rain water falls onto the water collecting plate 1204 in rainy days, then the rain water flows into the guide pipe 12055 from the mesh of the filter screen 12053, and flows into the water collecting tank 1201 from the lower end of the guide pipe 12055, because the water collecting tank 1201 is parallel to the slope, namely, the water collecting tank is in an inclined state, so that the rain water entering the water collecting tank 1201 flows into the lower end of the water collecting tank 1201, flows into the water storage tank 4 from the connecting pipe 13, when the water storage tank 4 is full of water and contacts with the probe of the water level sensor 2, the water level sensor 2 feeds information back to the wireless water level controller 1, the wireless water level controller 1 controls the electromagnetic valve 10 on the drain pipe 9 connected to the bottom of the water storage tank 4 to open, and the water in the water storage tank 4 is drained to the bottom of the slope through the drain pipe 9.

Secondly, after the rainy day is sunny, especially in hot summer, the vegetation planted on the side slope needs to irrigate regularly, at this moment can be through operating wireless water level controller 1 start water pump 6, and water in the water storage tank 4 can be taken out to water pump 6, and the pressurized back shunts to every way shunt tubes 7 through outlet pipe 5, and finally waters the vegetation on the side slope through dripping pipe network 8, does so and is favorable to the growth of side slope vegetation, has consolidated the side slope soil through the vegetation further, further makes the side slope more firm.

The foregoing description is only a preferred embodiment of the present utility model, and is not intended to limit the utility model in any way, and those skilled in the art may easily implement the present utility model as shown in the drawings and described above, but many modifications, adaptations and variations of the present utility model using the above disclosed technical matters will be equivalent to the embodiments of the present utility model without departing from the scope of the present utility model, and meanwhile, any equivalent changes, adaptations and variations of the above embodiments according to the essential technology of the present utility model are all within the scope of the technical matters of the present utility model.

Claims (6)

1. The utility model provides a cascaded drainage facility that holds, includes wireless water level controller (1), water level sensor (2) and electric power storage formula photovoltaic board (3), wherein water level sensor (2) electric connection has wireless water level controller (1), wireless water level controller (1) electric connection has electric power storage formula photovoltaic board (3), water level sensor (2) set up the upper wall at water storage tank (4), and the probe of water level sensor (2) stretches into the jar internally, the front end of water storage tank (4) is provided with outlet pipe (5), outlet pipe (5) are provided with water pump (6), water pump (6) and wireless water level controller (1) electric connection, the end connection of outlet pipe (5) has a plurality of water diversion pipes (7), and every way water diversion pipe (7) all are connected with a drip pipe network (8), the bottom of water storage tank (4) is connected with drain pipe (9), be connected with solenoid valve (10) on drain pipe (9), solenoid valve (10) and wireless water level controller (1) are provided with water pump (6), water pump (6) and water inlet pipe (11) are connected with water inlet pipe (11) and water storage tank (11) through connecting pipe (11) side of connecting, an air inlet pipe (14) is connected to the upper wall of the water storage tank (4) at one side of the water inlet pipe (11).

2. The stepped water storage and drainage facility according to claim 1, wherein the water collection assembly (12) comprises a water collection tank (1201) connected with the upper end of the water inlet pipe (11), a fixing frame (1202) is arranged at the upper end of the water collection tank (1201), clamping grooves (1203) are formed in the upper surfaces of the inner sides of four sides of the fixing frame (1202), a water collection plate (1204) is arranged in the fixing frame (1202), diversion assemblies (1205) are uniformly arranged on the water collection plate (1204), clamping pieces (1206) matched with the clamping grooves (1203) are connected to the four sides of the water collection plate (1204), and the clamping pieces (1206) are clamped in the clamping grooves (1203).

3. The stepped water storage and drainage facility according to claim 2, wherein the diversion assembly (1205) comprises a mounting hole (12051) formed in the water collecting plate (1204), two arc-shaped grooves (12052) are symmetrically formed in the inner side surface of the mounting hole (12051), a mounting groove (12056) is vertically formed in the inner side surface of the mounting hole (12051) and is positioned at one end of the arc-shaped groove (12052), the mounting groove (12056) is communicated with the arc-shaped groove (12052), a filter screen (12053) is mounted on the mounting hole (12051), two protrusions (12054) are symmetrically arranged at the side end of the filter screen (12053), the two protrusions (12054) are slidably connected in the arc-shaped groove (12052), and a diversion pipe (12055) is connected to the lower edge of the mounting hole (12051).

4. The stepped water storage and drainage facility according to claim 2, wherein the rear end of the fixing frame (1202) is fixedly connected with a supporting rod (15), and the upper end of the supporting rod (15) is provided with an electric storage type photovoltaic panel (3).

5. The stepped water storage and drainage facility according to claim 1, wherein the wireless water level controller (1) is arranged in the middle of the supporting rod (15), and the wireless water level controller (1) is provided with a protective shell.

6. A stepped water storage and drainage facility as claimed in claim 1, wherein a filter cover (16) is mounted at the upper end of the air inlet pipe (14).