CN218810766U - Mine ecological remediation device - Google Patents

Abstract

The utility model relates to the technical field of ecological restoration, and provides a mine ecological restoration device, which comprises a first reservoir, wherein a first stirring rod is arranged in the first reservoir, a first filter screen with a conical structure is hinged at the top of the first reservoir, a first stirring motor is arranged outside the first filter screen, and an output shaft of the first stirring motor penetrates through the first filter screen and is connected with the first stirring rod; a second filter screen is arranged in the first water storage tank and below the first stirring rod, a partition plate is arranged below the second filter screen, and a telescopic motor is arranged below the partition plate; the output shaft of the telescopic motor penetrates through the partition plate and is connected with the second filter screen. The telescopic motor can drive the second filter screen to do up-and-down reciprocating motion, and water in the first reservoir is filtered for multiple times. When a large amount of silt deposited on the second filter screen influences the filtering effect, the first filter screen is uncovered, the telescopic motor is opened, the output shaft of the telescopic motor upwards pushes the push plate and the second filter screen to upwards move to a position where people can reach, the second filter screen is detached, and the filter screen is well installed after the silt is cleaned.

Description

Mine ecological restoration device

Technical Field

The utility model relates to an ecological remediation technical field, concretely relates to mine ecological remediation device.

Background

The mine ecological environment refers to an ecological system and an environmental system in a mining area, and comprises surface vegetation and landscape, biological diversity, an atmospheric environment, a water environment, a soil environment, a geological environment, a sound environment and the like. The mine restoration is to restore the pollution of the mining abandoned land, realize the restoration of the damaged ecological environment and realize the sustainable utilization of land resources. During mining, a large amount of land which cannot be used without treatment is generated, and the land is also called mining waste land, and various pollutions caused by production exist in the waste land. The ecological environment of the mine needs to be restored, and a water storage device is usually established in the mine to provide water for the ecology of the mine and ensure the growth of vegetation.

Water storage device among the prior art includes cistern, filter screen etc. and filter screen fixed connection only plays filterable effect to the rainwater in the top of cistern, this water storage device to avoid outdoor placing and cause the inside condition of piling up the leaf of cistern, reduce the jam of filter screen and water pipe. However, since there is a lot of grit in the mine air, this grit can be carried into the reservoir by rain water. This gravel build up in the reservoir can interfere with retaining water and clog the pipes in the reservoir. The device cannot clean silt in the reservoir.

SUMMERY OF THE UTILITY MODEL

The utility model aims at providing a mine ecological remediation device establishes the cistern in the mine, has solved the cistern among the prior art and can not clear up the problem of silt in the cistern when avoiding the branch leaf to fall into the cistern.

The utility model discloses a mine ecological remediation device, including first cistern:

a first filter screen with a conical structure is hinged to one side of the top of the first reservoir, a first stirring motor is arranged on the outer side of the first filter screen, a first stirring rod is arranged in the first reservoir, and an output shaft of the first stirring motor penetrates through the first filter screen and is connected with the first stirring rod;

a second filter screen is arranged in the first water storage tank and below the first stirring rod, a partition plate is arranged below the second filter screen, and a telescopic motor is arranged below the partition plate; an output shaft of the telescopic motor penetrates through the partition plate and is connected with the second filter screen;

preferably, the second filter screen both ends are provided with the elastic sealing pad respectively, and every the elastic sealing pad one end can be dismantled and connect in second filter screen tip, other end fixed connection in on the first cistern inner wall.

Preferably, still include the push pedal, the push pedal can dismantle connect in the second filter screen lower extreme, the output shaft of flexible motor runs through the baffle, and with the push pedal is connected.

Preferably, the lower end of the first reservoir is provided with an L-shaped guide pipe, one end, deviating from the first reservoir, of the L-shaped guide pipe is connected with a second reservoir, and the second reservoir is connected with a feeding pipe.

The second cistern outside is provided with second agitator motor, second agitator motor's output shaft runs through second cistern top is connected with the second puddler.

Preferably, a pH meter is arranged on the second reservoir, a water outlet pipe is arranged at the bottom of the second reservoir, and a second valve is arranged at one end of the water outlet pipe, which deviates from the second reservoir.

Preferably, a first valve is arranged on the L-shaped conduit.

Preferably, a first stirring blade is circumferentially arranged on the first stirring rod.

Preferably, the second stirring rod is circumferentially provided with a second stirring blade.

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

1. after multiple use, a large amount of silt can deposit on the second filter screen, influence the filter effect. At the moment, the first filter screen can be uncovered, the second filter screen is driven to move upwards to a position where people can reach through the telescopic motor, then the second filter screen is detached, and the second filter screen is washed clean of silt and then is filled into the first water storage tank. The second filter screen is convenient to disassemble and wash, can be recycled, and saves cost.

2. The utility model discloses first filter screen has been set up for block that the branch leaf falls into first cistern, and the toper structure of first filter screen, make the branch leaf that falls on it change from landing on first filter screen, reduce artifical clearance number of times.

3. The telescopic motor can drive the second filter screen to reciprocate up and down, so that water in the reservoir can be filtered for multiple times, and the filtering is more thorough.

4. The setting of elastic sealing gasket has guaranteed no matter the second filter screen is rising or the in-process that descends, and the aquatic after the filtration can not all be leaked from the gap between the tip of second filter screen and the first cistern to silt.

Drawings

Fig. 1 is a schematic structural view of a mine ecological restoration device provided by the utility model;

fig. 2 is a schematic structural diagram of the second filter screen in the mine ecological restoration device provided by the present invention in the ascending process;

fig. 3 is the utility model provides a pair of second filter screen decline process's among mine ecological remediation device structural schematic.

Description of reference numerals:

1-a telescopic motor; 2-a first reservoir; 21-a first screen; 22-a first stirring motor; 221-a first stirring rod; 222-a first stirring blade; 23-a second screen; 24-a push plate; a 25-L shaped catheter; 26-a first valve; 27-an elastic sealing gasket; 3-a second reservoir; 31-a second stirring motor; 32-a second stirring rod; 33-second stirring blade; 34-a feed pipe; 35-a pH meter; 36-a second valve; 37-a water outlet pipe; 4-a separator.

Detailed Description

In the following, an embodiment of the present invention will be described in detail with reference to the drawings, but it should be understood that the scope of the present invention is not limited by the embodiment.

Fig. 1 is the utility model provides a pair of mine ecological remediation device's schematic structure.

As shown in fig. 1, the utility model provides a mine ecological remediation device, including first cistern 2, 2 top one side of first cistern are articulated to have a first filter screen 21 of toper structure, and the first filter screen 21 outside is provided with first agitator motor 22, and first agitator motor 22's output shaft runs through first filter screen 21 and is connected with first puddler 221.

A second filter screen 23 is arranged in the first reservoir 2 and below the first stirring rod 221, a partition plate 4 is arranged below the second filter screen 23, and a telescopic motor 1 is arranged below the partition plate 4; the bottom side of the second filter screen 23 is connected with a push plate 24, and the output shaft of the telescopic motor 1 penetrates through the partition plate 4 and is connected with the second filter screen 23.

A first filter screen 21 with a conical structure is hinged on one side of the top of the first reservoir 2. Because of first filter screen 21 articulates in the cistern top, when needing to clear up silt on second filter screen 23, just can uncover first filter screen 21, operate. The first filter screen 21 is a conical structure, and the structure enables branches and leaves falling on the first filter screen 21 to slide off from the first filter screen more easily, so that the manual cleaning frequency is reduced. First trompil is provided with in the department that lies in first agitator motor 22 on the first filter screen 21, and the output shaft of first agitator motor 22 runs through first trompil and is connected with first puddler 221, and first puddler 221 self is unrotatable, is driven by the output shaft to rotate under first agitator motor 22's drive.

The telescopic motor 1 can drive the second filter screen 23 to reciprocate up and down, so that water in the first reservoir 2 can be filtered for multiple times, and the filtering is more thorough. After multiple uses, a large amount of silt can be deposited on the second filter screen 23, and the filtering effect is influenced. At this time, the first filter screen 21 can be uncovered, the first stirring motor 22 is driven to leave the first reservoir 2, the telescopic motor 1 is opened, the second filter screen 23 is pushed upwards through the telescopic motor 1, the second filter screen 23 moves upwards to a position where people can reach, the second filter screen 23 is detached again, and the sediment is washed out and then is filled into the first reservoir 2. The second filter screen 23 is convenient to disassemble and wash, and can be reused, so that the cost is saved.

The baffle 4 separates the water in flexible motor 1 and the first cistern 2, avoids flexible motor 1 long-time bubble in the water, reduces life.

Second filter screen 23 both ends are provided with elastic sealing pad 27 respectively, and every elastic sealing pad 27 one end can be dismantled and connect in second filter screen 23 tip upper surface, specifically, elastic sealing pad 27 second filter screen 23 tip upper surface spiro union, and other end fixed connection is on first cistern 2 inner wall.

Still include push pedal 24, push pedal 24 can dismantle and connect in second filter screen 23 lower extreme, specifically, push pedal 24 spiro union is in second filter screen 23 lower extreme, and the output shaft of flexible motor 1 runs through baffle 4 to be connected with push pedal 24. The output shaft and the push pedal 24 of flexible motor 1 are connected, and this setting can avoid the output shaft of flexible motor 1 to contact second filter screen 23 for a long time, causes wearing and tearing to second filter screen 23. The telescopic motor 1 can drive the push plate 24 to reciprocate up and down, so as to drive the second filter screen 23 to reciprocate up and down for filtering for multiple times.

The screw connection structure of the elastic sealing gasket 27, the second filter screen 23 and the push plate 24 is specifically as follows: the end part of the push plate 24 is provided with a through hole matched with the bolt, and the through hole penetrates through the upper surface and the lower surface of the push plate 24, so that the bolt sequentially passes through the second filter screen 23 and the elastic sealing gasket 27, enters the through hole from the upper surface of the push plate 24, extends out of the bottom of the push plate 24 and is fixed by a nut.

Fig. 2 is the utility model provides a pair of second filter screen rises in mine ecological remediation device's the schematic structure diagram.

As shown in fig. 2, one end of the elastic sealing gasket 27 is screwed to the end of the second filter 23, and the other end is fixedly connected to the inner wall of the first reservoir 2 on the same side. When the push plate 24 drives the second filter screen 23 to ascend, the end of the elastic sealing gasket 27 is still, but the elastic sealing gasket elastically extends to form a trapezoid structure with the second filter screen 23. Meanwhile, due to the existence of the elastic sealing gasket 27, silt existing at the joint of the second filter screen 23 and the side wall of the first reservoir 2 can fall on the elastic sealing gasket 27.

Fig. 3 is the utility model provides a pair of second filter screen decline process's among mine ecological remediation device structural schematic.

As shown in fig. 3, when the push plate 24 drives the second screen 23 to descend, the end of the elastic sealing pad 27 is still, but the elastic sealing pad is elastically extended to form an inverted trapezoid structure with the second screen 23. Due to the existence of the elastic sealing gasket 27, silt generated at the joint of the second filter screen 23 and the side wall of the first reservoir 2 cannot leak out of the second filter screen 23. Meanwhile, the sediment finally falls onto the second filter screen 23 due to the inverted trapezoidal structure.

The provision of the resilient gasket 27 ensures that silt will not leak into the filtered water from the gap between the end of the second screen 23 and the first reservoir 2 during the ascent or descent of the second screen 23.

As shown in fig. 1, an L-shaped conduit 25 is provided at the lower end of the first reservoir 2, a second reservoir 3 is connected to the end of the L-shaped conduit 25 facing away from the first reservoir 2, and the second reservoir 3 is disposed lower than the first reservoir 2. This arrangement creates a height difference, i.e. a pressure differential, between the two reservoirs, so that the filtered water from the first reservoir 2 can flow into the second reservoir 3 by means of the pressure differential.

A second stirring rod 32 is arranged in the second water reservoir 3, a second stirring motor 31 is arranged outside the second water reservoir 3, an output shaft of the second stirring motor 31 penetrates through the top wall of the second water reservoir 3 to be connected with the second stirring rod 32, an opening is formed in the position, located at the second stirring motor 31, of the top wall of the second water reservoir 3, an output shaft of the second stirring motor 31 penetrates through the opening to be connected with the second stirring rod 32, the second stirring rod 32 cannot rotate per se, and the second stirring rod is driven by the output shaft to rotate under the driving of the second stirring motor 31; the second reservoir 3 is connected with a feed pipe 34, the feed pipe 34 is screwed with a pipe cover 38, the second reservoir 3 is provided with a pH meter 35, the bottom of the second reservoir 3 is provided with a water outlet pipe 37, and one end of the water outlet pipe 37 departing from the second reservoir 3 is provided with a second valve 36.

After the filtered water enters the second water storage tank 3, the pH value of the filtered water is measured by a pH meter 35, and then a corresponding pH value neutralizer is selected according to the pH value. Opening the cover 38, adding pH neutralizer from the feeding pipe 34, opening the second stirring motor 31, stirring uniformly, measuring pH value, repeating the steps until the pH value is equal to 7, stopping stirring, opening the second valve 36, and irrigating with the rainwater.

The L-shaped conduit 25 is provided with a first valve 26. The first valve 26 is closed before the rainwater in the first reservoir 2 has not been filtered. After filtration is complete, the first valve 26 is opened and the pressure differential created by the difference in height causes filtered rainwater to enter the second reservoir 3.

The outside of the first water reservoir 2 is provided with a power supply, and the telescopic motor 1, the first stirring motor 22, the second stirring motor 31 and the pH meter 35 are all electrically connected with the power supply.

The first stirring motor 22 and the second stirring motor 31 both adopt a rotating motor structure in the prior art.

The first stirring blade 222 is circumferentially disposed on the first stirring rod 221, and the first stirring blade stirs while filtering, so as to accelerate the filtering speed.

The second stirring rod 32 is circumferentially provided with second stirring blades 33, and the circumferential arrangement of the second stirring blades 33 enables the stirring to be more uniform, so that the pH value can be more accurately measured.

The first filter screen 21 and the second filter screen 23 are both stainless steel filter screens, stainless steel materials are not easy to corrode, and the service life is longer.

The working principle and the using method are as follows: the utility model discloses in, first filter screen is used for blockking that the branch leaf falls into first cistern, and the toper structure of first filter screen, makes the branch leaf that falls on it change from landing on first filter screen, reduces artifical clearance number of times. The rainwater filters the bold impurity such as branch leaf earlier through first filter screen, passes through the second filter screen again, and the second filter screen is used for filtering the silt of rainwater. The telescopic motor can drive the push plate to do up-and-down reciprocating motion, the second filter screen also performs up-and-down reciprocating motion, and water in the first reservoir can be filtered for multiple times, so that the filtering is more thorough. Then the first valve is opened again, so that the rainwater enters the second reservoir through the guide pipe. As the second reservoir is lower than the first reservoir, a pressure differential is created and upon opening the valve, water flows from the first reservoir into the second reservoir. And (3) the pH value of the rainwater entering the second reservoir is measured by using a pH meter, a corresponding pH value neutralizer is added according to the pH value, the mixture is uniformly stirred until the pH value of the rainwater is equal to 7, and then the rainwater can be used for irrigating plants. After multiple use, a large amount of silt can deposit on the second filter screen, influence the filter effect. At this moment, can reveal first filter screen, open flexible motor, the output shaft through flexible motor promotes the push pedal, and the push pedal drives the second filter screen rebound to the position that the people can reach, tears the second filter screen down again, and the first cistern is gone into again to the clean silt of washing. The second filter screen is convenient to disassemble and wash, can be recycled, and saves cost.

The above disclosure is only for the specific embodiments of the present invention, but the embodiments of the present invention are not limited thereto, and any changes that can be considered by those skilled in the art should fall within the protection scope of the present invention.

Claims (8)

1. The mine ecological restoration device is characterized by comprising a first water reservoir (2);

a first filter screen (21) with a conical structure is hinged to one side of the top of the first reservoir (2), a first stirring motor (22) is arranged on the outer side of the first filter screen (21), and an output shaft of the first stirring motor (22) penetrates through the first filter screen (21) and is connected with a first stirring rod (221);

a second filter screen (23) is arranged in the first reservoir (2) and below the first stirring rod (221), a partition plate (4) is arranged below the second filter screen (23), and a telescopic motor (1) is arranged below the partition plate (4); the output shaft of the telescopic motor (1) penetrates through the partition plate (4) and is connected with the second filter screen (23).

2. The mine ecological restoration device according to the claim 1, wherein the second filter screen (23) is provided with elastic sealing gaskets (27) at two ends respectively, and one end of each elastic sealing gasket (27) is detachably connected to the end of the second filter screen (23), and the other end is fixedly connected to the inner wall of the first reservoir (2).

3. The mine ecological restoration device according to claim 1, further comprising a push plate (24), wherein the push plate (24) is detachably connected to the lower end of the second filter screen (23), and an output shaft of the telescopic motor (1) penetrates through the partition plate (4) and is connected with the push plate (24).

4. The mine ecology restoration device according to claim 1, wherein an L-shaped conduit (25) is arranged at the lower end of the first reservoir (2), a second reservoir (3) is connected to one end of the L-shaped conduit (25) away from the first reservoir (2), and a feeding pipe (34) is connected to the second reservoir (3);

second cistern (3) outside is provided with second agitator motor (31), the output shaft of second agitator motor (31) runs through second cistern (3) top is connected with second puddler (32).

5. The mine ecology restoration device according to claim 4, wherein a pH meter (35) is arranged on the second reservoir (3), a water outlet pipe (37) is arranged at the bottom of the second reservoir (3), and a second valve (36) is arranged at one end of the water outlet pipe (37) which is far away from the second reservoir (3).

6. The mine ecology restoration device according to claim 4, wherein a first valve (26) is arranged on the L-shaped conduit (25).

7. The mine ecology restoration device according to claim 1, wherein the first stirring rod (221) is circumferentially provided with first stirring blades (222).

8. The mine ecology restoration device according to claim 4, wherein the second stirring rod (32) is circumferentially provided with second stirring blades (33).

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