CN220768242U - Rainwater recycling device - Google Patents

Abstract

The utility model relates to a rainwater recycling device, which comprises a storage unit, a drainage unit, a spraying unit, a supporting unit and a water lifting unit, wherein the storage unit is buried in the ground, and the top end of the storage unit is exposed out of the ground and is used for storing rainwater; the drainage unit is arranged on the roof or the high position and communicated with the storage unit, and is used for draining rainwater to the storage unit; the water jet of spraying unit sets up in skylight or window department to communicate with the storage unit, be used for the storage unit to spray the rainwater. The device has the advantages that the water lifting unit is used as power, rainwater is lifted by wind power to irrigate crops, a water pump is used as power, a part of energy consumption generated by the water pump is offset, and the requirement on energy is relieved; the spraying unit is used for draining rainwater to the building roof or the skylight, and the rainwater spraying unit is used when the air temperature is high, so that the rainwater is used for spraying and cooling the building roof or the skylight.

Description

Rainwater recycling device

Technical Field

The utility model relates to the related technical field of rainwater collection and utilization, in particular to a rainwater recycling device.

Background

The rainwater recovery refers to the whole rainwater collection process, and can be used for collecting rainwater through a rainwater collecting pipeline, discarding and intercepting sewage, storing the rainwater in a PP rainwater collecting tank, filtering, sterilizing, purifying and recycling, and collecting the rainwater for irrigation of crops, supplementing groundwater, and also for non-domestic water use such as landscape environment, greening, water for a car washing station, road flushing and cooling water supplement, toilet flushing and the like. Can save water resources and greatly relieve the water shortage problem of China.

When the rainwater is collected and utilized, the water pump is adopted as all power for conveying the rainwater, and particularly when a plurality of water pumps are used for working, the energy consumption is higher, the recovered rainwater cannot play more roles, and the practicability is not high.

At present, no effective solution is proposed for the problems of higher energy consumption and failure of the recovered rainwater to play more roles in the related art.

Disclosure of Invention

The utility model aims at overcoming the defects in the prior art, and provides a rainwater recycling device for solving the problems that the energy consumption is high and the recycled rainwater cannot play more roles in the related art.

In order to achieve the above purpose, the technical scheme adopted by the utility model is as follows:

a rainwater recycling device, comprising:

the storage unit is buried in the ground, and the top end of the storage unit is exposed out of the ground and is used for storing rainwater;

the drainage unit is arranged on the roof or the high place and communicated with the storage unit, and is used for draining rainwater to the storage unit;

the water spraying port of the spraying unit is arranged at a skylight or a window and is communicated with the storage unit, and the storage unit is used for spraying rainwater;

The supporting unit is arranged at the top end of the storage unit and is connected with the storage unit;

the water lifting unit is arranged at the top end of the supporting unit and is movably connected with the supporting unit, and the bottom end of the water lifting unit is slidably arranged in the storage unit and is used for lifting out rainwater in the storage unit.

In some of these embodiments, the storage unit comprises:

the storage element is buried in the ground, the top end of the storage element is exposed to the ground and is respectively communicated with the drainage unit and the spraying unit for collecting rainwater;

the partition plate element is arranged in the storage element and is used for dividing the storage element into a storage cavity and a drainage cavity;

the first water inlet element is arranged at the side part of the storage element and is respectively communicated with the storage cavity and the drainage unit and used for guiding rainwater by the drainage unit;

the first water outlet element is arranged at the side part of the storage element and is respectively communicated with the storage cavity and the spraying unit and used for conveying rainwater to the spraying unit;

The second water outlet element is arranged at the side part of the storage element and communicated with the water drainage cavity, and is used for draining water under the action of the water lifting unit;

the first sliding element is arranged at the top end of the storage element and is in sliding connection with the water lifting unit.

In some of these embodiments, the storage unit further comprises:

the water collecting element is arranged in the storage element, the top end of the water collecting element is connected with the partition plate element, the water collecting element is in sliding connection with the water lifting unit, and the water collecting element is respectively communicated with the storage cavity and the drainage cavity;

the second water inlet element is arranged at the side part of the water collecting element and communicated with the storage cavity, and is used for enabling rainwater in the storage cavity to enter the water collecting element.

In some of these embodiments, the drainage unit comprises:

a collecting element provided on a roof or a high place for collecting rainwater by the storage unit;

the first drainage element is communicated with the collecting element and the storage unit respectively and is used for guiding rainwater to the storage unit.

In some of these embodiments, the spraying unit comprises:

a first bracket element disposed at a wall surface of a sunroof or window;

the second drainage element is arranged on the inner side of the first bracket element and is connected with the first bracket element;

the plurality of spraying elements are distributed and provided with the second drainage elements and are communicated with the second drainage elements for spraying rainwater;

the first driving element is communicated with the second drainage element and the storage unit and is used for guiding rainwater in the storage unit to the second drainage element.

In some of these embodiments, the spray unit further comprises:

a third drainage element in communication with the first drive element and the second drainage element, respectively;

and the fourth drainage element is respectively communicated with the first driving element and the storage unit.

In some of these embodiments, the support unit includes:

the second bracket element is arranged at the top end of the storage unit and is connected with the storage unit;

The first movable element is arranged at the top end of the second bracket element and is movably connected with the water lifting unit.

In some of these embodiments, the water lifting unit comprises:

the third bracket element is arranged at the top of the supporting unit and is connected with the supporting unit;

the first end of the first rotating element is arranged on one side of the third bracket element and is connected with the third bracket element;

the top end of the second movable element is rotationally connected with the second end of the first rotary element;

the third movable element is arranged on one side of the second movable element;

the two ends of the second rotating element are respectively connected with the bottom end of the second movable element and the bottom end of the third movable element;

the first end of the second driving element is connected with the top end of the third movable element and is used for driving the third movable element, the second rotating element, the second movable element and the third bracket element to rotate relatively;

The third rotating element is rotationally connected with the second rotating element;

the top end of the second sliding element is connected with the third rotating element and is in sliding connection with the storage unit;

and the top end of the third sliding element is connected with the bottom end of the second sliding element and is in sliding connection with the storage unit, and the third sliding element is used for discharging rainwater of the storage unit outwards.

In some of these embodiments, the water lifting unit further comprises:

the top end of the first connecting element is connected with the third rotating element;

the top end of the fourth rotating element is connected with the bottom end of the first connecting element;

a second connecting element, the bottom end of which is connected with the top end of the second sliding element;

and the fifth rotating element is arranged at the top end of the second connecting element and is rotationally connected with the fourth rotating element.

In some of these embodiments, the water lifting unit further comprises:

and the tail wing element is connected with the other side of the third support element and is used for driving the third support element to automatically seek.

In some of these embodiments, the water lifting unit further comprises:

and the fan blade element is arranged at the second end of the second driving element.

Compared with the prior art, the utility model has the following technical effects:

according to the rainwater recycling device, the water lifting unit is used as power, rainwater is lifted by wind power to irrigate crops, a water pump is used as power, a part of energy consumption generated by the water pump is offset, the requirement on energy is relieved, and the water lifting unit can be used as a decorative object to improve the attractiveness; utilize and spray the unit, can be with rainwater drainage to building roofing or skylight department, use when air temperature is higher to utilize the rainwater to spray cooling to building roofing or skylight department, reduce solar radiation to indoor temperature's influence, help promoting indoor comfort level, increase rainwater recycle's practicality.

Drawings

Fig. 1 is a schematic perspective view of a rainwater recycling apparatus according to an embodiment of the present utility model;

FIG. 2 is a partial internal construction view of a rainwater recycling apparatus according to an embodiment of the present utility model;

FIG. 3a is a schematic perspective view of a storage unit according to an embodiment of the utility model;

FIG. 3b is a schematic diagram illustrating an internal structure of a storage unit according to an embodiment of the present utility model;

fig. 4 is a schematic perspective view of a drainage unit according to an embodiment of the present utility model;

fig. 5 is a schematic perspective view of a spray unit according to an embodiment of the present utility model;

fig. 6 is a schematic perspective view of a supporting unit according to an embodiment of the present utility model;

FIG. 7a is an enlarged view of a portion of a water lifting unit according to an embodiment of the utility model;

FIG. 7b is a schematic view of a portion of a water lifting unit according to an embodiment of the present utility model;

FIG. 8 is an exploded view of a water lifting unit according to an embodiment of the present utility model;

wherein the reference numerals are as follows: 100. a storage unit; 101. a storage element; 102. a separator element; 103. a first water inlet element; 104. a first water outlet element; 105. a second water outlet element; 106. a first sliding element; 107. a water collecting element; 108. a second water inlet element;

200. a drainage unit; 201. a collection element; 202. a first drainage element;

300. a spraying unit; 301. a first bracket element; 302. a second drainage element; 303. a spray element; 304. a first driving element; 305. a third drainage element; 306. a fourth drainage element;

400. A supporting unit; 401. a second bracket element; 402. a first movable element.

500. A water lifting unit; 501. a third bracket element; 502. a first rotating element; 503. a second movable element; 504. a third movable element; 505. a second rotating element; 506. a second driving element; 507. a third rotating element; 508. a second sliding element; 509. a third sliding element; 510. a first connecting element; 511. a fourth rotating element; 512. a second connecting element; 513. a fifth rotating element; 514. a tail element; 515. a fan blade element.

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.

It should be noted that, without conflict, the embodiments of the present utility model and features of the embodiments may be combined with each other.

The utility model is further described below with reference to the drawings and specific examples, which are not intended to be limiting.

An exemplary embodiment of the present utility model, as shown in fig. 1 and 2, a rainwater recycling apparatus includes a storage unit 100, a drainage unit 200, a spray unit 300, a support unit 400, and a water lifting unit 500. The storage unit 100 is buried in the ground, and the top end of the storage unit 100 is exposed out of the ground for storing rainwater; the drainage unit 200 is disposed on a roof or at a high place, and is communicated with the storage unit 100, for draining rainwater to the storage unit 100; the water spray port of the spraying unit 300 is provided at a sunroof or a window and communicates with the storage unit 100 for spraying rainwater to the storage unit 100; the support unit 400 is disposed at the top end of the storage unit 100 and connected to the storage unit 100; the water lifting unit 500 is disposed at the top end of the supporting unit 400 and is movably connected with the supporting unit 400, and the bottom end of the water lifting unit 500 is slidably disposed inside the storage unit 100, so as to lift out rainwater in the storage unit 100.

Specifically, the drainage unit 200 drains rainwater to the storage unit 100; the storage unit 100 stores rainwater; the spraying unit 300 sprays rainwater in the storage unit 100 to a sunroof or a window; the water lifting unit 500 lifts the rainwater in the storage unit 100 to be discharged outward to irrigate plants.

As shown in fig. 3a and 3b, the storage unit 100 includes a storage element 101, a partition element 102, a first water inlet element 103, a first water outlet element 104, a second water outlet element 105, and a first sliding element 106. The storage element 101 is buried in the ground, and the top end of the storage element 101 is exposed to the ground and is respectively communicated with the drainage unit 200 and the spraying unit 300 for collecting rainwater; the partition member 102 is disposed inside the storage member 101 and is used for dividing the storage member 101 into a storage chamber and a drainage chamber; the first water inlet element 103 is arranged at the side part of the storage element 101 and is respectively communicated with the storage cavity and the drainage unit 200, and is used for the drainage unit 200 to drain rainwater; the first water outlet element 104 is arranged at the side part of the storage element 101 and is respectively communicated with the storage cavity and the spraying unit 300 for conveying rainwater to the spraying unit 300; the second water outlet element 105 is arranged at the side part of the storage element 101 and is communicated with the water discharge cavity for discharging water under the action of the water lifting unit 500; the first sliding element 106 is disposed at the top end of the storage element 101 and is slidably connected to the water lifting unit 500.

The storage element 101 has a hollow rectangular column structure.

In some of these embodiments, the storage element 101 is made of stainless steel.

In some of these embodiments, storage element 101 is a storage tank.

The spacer member 102 is rectangular in cross section. Specifically, the spacer member 102 includes a mounting plate and a mounting groove. Wherein the mounting plate is connected to the inside of the storage element 101; the installation groove penetrates through the installation plate and is in sliding connection with the water lifting unit 500.

The size of the mounting groove is matched with the size of the mounting plate. Typically, the length of the mounting slot is less than the length of the mounting plate, the width of the mounting slot is less than the width of the mounting plate, and the depth of the mounting slot is equal to the height of the mounting plate.

The dimensions of the spacer element 102 are matched to the dimensions of the storage element 101. Generally, the dimensions of the mounting plate match the dimensions of the storage element 101. Specifically, the length of the mounting plate is equal to the inside length of the storage element 101, the width of the mounting plate is equal to the inside width of the storage element 101, and the height of the mounting plate is smaller than the inside height of the storage element 101.

In some of these embodiments, the spacer member 102 is fixedly connected to the storage member 101, including but not limited to welding.

In some of these embodiments, the spacer member 102 is made of stainless steel.

In some of these embodiments, the spacer element 102 is a spacer.

The first water inlet element 103 is arranged on the left side of the storage element 101.

The first water inlet element 103 has a circular cross section.

The size of the first water inlet element 103 matches the size of the storage element 101. Typically, the diameter of the first water inlet element 103 is smaller than the outer width/height of the storage element 101, and the depth of the first water inlet element 103 is equal to the thickness of the inner wall of the storage element 101.

In some of these embodiments, the first water intake element 103 is a first water inlet.

The first water outlet element 104 is disposed on the right side of the storage element 101.

The first water outlet member 104 has a circular cross-section.

The size of the first water outlet member 104 matches the size of the storage member 101. Typically, the diameter of the first water outlet member 104 is smaller than the outer width/height of the storage member 101, and the depth of the first water outlet member 104 is equal to the thickness of the inner wall of the storage member 101.

In some of these embodiments, the first water outlet element 104 is a first water outlet.

The second water outlet member 105 is disposed at the front side of the storage member 101.

The second water outlet element 105 has a circular cross section.

The dimensions of the second outlet element 105 are matched to the dimensions of the storage element 101. Typically, the diameter of the second water outlet member 105 is smaller than the outer length/height of the storage member 101, and the depth of the second water outlet member 105 is equal to the thickness of the inner wall of the storage member 101.

In some of these embodiments, the second water outlet element 105 is a second water outlet.

The first sliding element 106 is circular in cross-section.

The size of the first sliding element 106 matches the size of the storage element 101. Typically, the diameter of the first sliding element 106 is smaller than the outer length/width of the storage element 101, and the depth of the first sliding element 106 is equal to the thickness of the inner wall of the storage element 101.

In some of these embodiments, the first sliding element 106 is a sliding aperture.

Further, the storage unit 100 further comprises a water collecting element 107 and a second water inlet element 108. Wherein, the water collecting element 107 is arranged in the storage element 101, the top end of the water collecting element 107 is connected with the baffle element 102, the water collecting element 107 is slidingly connected with the water lifting unit 500, and the water collecting element 107 is respectively communicated with the storage cavity and the drainage cavity; the second water inlet element 108 is provided at a side portion of the water collecting element 107 and communicates with the storage chamber for letting rainwater of the storage chamber into the inside of the water collecting element 107.

Specifically, the water collecting member 107 is connected with the mounting groove of the spacer member 102.

The water collecting element 107 is in a rectangular column structure hollowed out up and down.

The dimensions of the water collecting element 107 are matched to the dimensions of the spacer element 102. Generally, the size of the water collecting element 107 matches the size of the mounting groove. Specifically, the outer side length of the water collecting element 107 is equal to the length of the installation groove, the outer side width of the water collecting element 107 is equal to the width of the installation groove, and the outer side height of the water collecting element 107 is greater than the depth of the installation groove.

The size of the water collecting element 107 matches the size of the storage element 101. Generally, the outer length of the water collecting element 107 is smaller than the inner length of the storage element 101, the outer width of the water collecting element 107 is smaller than the inner width of the storage element 101, and the outer height of the water collecting element 107 is smaller than the inner height of the storage element 101.

The size of the water collecting element 107 matches the size of the storage element 101. Generally, the size of the water collecting element 107 matches the size of the storage chamber. Specifically, the outer length of the water collecting element 107 is smaller than the length of the storage chamber, the outer width of the water collecting element 107 is smaller than the width of the storage chamber, and the top end of the water collecting element 107 is higher than the top end of the storage chamber (and extends to the drainage chamber).

In some of these embodiments, the water collection element 107 is fixedly attached to the spacer element 102, including but not limited to welding.

In some of these embodiments, the water collection element 107 is made of stainless steel.

In some of these embodiments, the water collection element 107 is a drainage frame.

The second water inlet element 108 has a rectangular cross section.

The dimensions of the second water inlet element 108 match the dimensions of the water collecting element 107. Generally, the length of the second water inlet element 108 is smaller than the outer side length of the water collecting element 107, the depth of the second water inlet element 108 is equal to the thickness of the inner wall of the water collecting element 107, and the height of the second water inlet element 108 is smaller than the outer side height of the water collecting element 107.

In some of these embodiments, the second water intake element 108 is a plurality. The second water inlet elements 108 are distributed around the water collecting element 107.

Generally, a second water inlet member 108 is disposed around the water collecting member 107.

In some of these embodiments, the second water intake element 108 is a second water inlet.

As shown in fig. 4, the drainage unit 200 comprises a collecting element 201 and a first drainage element 202. Wherein the collecting element 201 is provided on a roof or a high place for collecting rainwater by the storage unit 100; the first drainage element 202 is respectively communicated with the collecting element 201 and the storage unit 100 for draining rainwater to the storage unit 100.

Specifically, the first drainage element 202 communicates with the first water intake element 103.

The collecting element 201 has a rectangular column structure with an open top. Specifically, the collecting element 201 comprises a collecting chamber, a filter mesh (not shown in the figures) and a first through hole. Wherein the collecting cavity is arranged on the roof or the high place; the filter screen is arranged in the collecting cavity and is connected with the collecting cavity; the first through hole is disposed through the bottom end of the collection chamber and communicates with the first drainage element 202.

In some of these embodiments, the collection element 201 is made of stainless steel.

In some of these embodiments, the collection element 201 is a collection sink.

The first drainage element 202 is circular in cross-section.

The dimensions of the first drainage element 202 are matched to the dimensions of the first water inlet element 103. Generally, the inner diameter of the first drainage element 202 is equal to the diameter of the first water inlet element 103.

The size of the first drainage element 202 matches the size of the collection element 201. Generally, the size of the first drainage element 202 matches the size of the collection chamber; the first drainage element 202 is sized to match the size of the first through-hole. Specifically, the outer diameter of the first drainage element 202 is smaller than the outer length/width of the collection chamber; the inner diameter of the first drainage element 202 is equal to the diameter of the first through hole.

In some of these embodiments, the first drainage element 202 is fixedly connected to the collection element 201, the storage element 101, respectively, including but not limited to a bolted connection.

In some of these embodiments, the first drainage element 202 is made of stainless steel.

In some of these embodiments, the first drainage element 202 is a first drainage tube.

As shown in fig. 5, the spray unit 300 comprises a first holder element 301, a second drainage element 302, several spray elements 303 and a first drive element 304. Wherein the first bracket element 301 is arranged at the wall surface of a skylight or window; the second drainage element 302 is disposed on the inner side of the first support element 301 and is connected to the first support element 301; the plurality of spraying elements 303 are distributed with the second drainage elements 302 and are communicated with the second drainage elements 302 for spraying rainwater; the first driving element 304 is in communication with the second drainage element 302 and the storage unit 100, and is configured to drain rainwater in the storage unit 100 to the second drainage element 302.

Specifically, the first driving element 304 communicates with the storage element 101 for transporting rainwater within the storage element 101.

The first bracket member 301 has a U-shaped cross-section. Wherein the first bracket element 301 comprises a bottom plate and two risers. Wherein, the bottom plate is arranged on the wall surface of the skylight or the window; the two vertical plates are perpendicular to the bottom plate and are connected with the bottom plate.

In some of these embodiments, the first bracket element 301 is made of stainless steel.

In some of these embodiments, the first bracket element 301 is a mounting bracket.

The second drainage element 302 is circular in cross-section.

The dimensions of the second drainage element 302 match those of the first stent element 301. In general, the dimensions of the second drainage element 302 match the dimensions of the two risers. Specifically, the outer diameter of the second drainage element 302 is smaller than the length/height of the risers, the axial dimension of the second drainage element 302 being equal to the distance between the risers.

In some of these embodiments, the second drainage element 302 is fixedly coupled to the first stent element 301, including but not limited to a bolted connection.

In some of these embodiments, the second drainage element 302 is made of stainless steel.

In some of these embodiments, the second drainage element 302 is a second drainage tube.

The spray element 303 comprises a manifold and a spray head. Wherein the conduit communicates with the second drainage element 302; the spray head is communicated with the pipeline.

The size of the spray element 303 matches the size of the second drainage element 302. Generally, the dimensions of the tubing match the dimensions of the second drainage element 302. Specifically, the outer diameter of the tubing is smaller than the axial dimension of the second drainage element 302.

In some of these embodiments, the spray elements 303 are five.

In some of these embodiments, the spray element 303 is fixedly connected to the second drainage element 302. For example, the spray element 303 is integrally formed with the second drainage element 302.

In some of these embodiments, the spray element 303 is made of stainless steel.

In some of these embodiments, the spray element 303 is a spray head.

The first drive element 304 is attached to the wall surface of the installed skylight or window, including but not limited to a bolted connection.

In some of these embodiments, the first driving element 304 is connected to an external power source and a switch, which guarantees the power supply requirements during operation.

In some of these embodiments, the first drive element 304 is a water pump.

Further, the spraying unit 300 further comprises a third drainage element 305 and a fourth drainage element 306. Wherein the third drainage element 305 is respectively communicated with the first driving element 304 and the second drainage element 302; the fourth drainage element 306 is in communication with the first drive element 304 and the storage unit 100, respectively.

The third drainage element 305 has a circular cross section.

The dimensions of the third drainage element 305 are matched to the dimensions of the second drainage element 302. Generally, the outer diameter of the third drainage element 305 is smaller than the outer diameter of the second drainage element 302.

In some of these embodiments, the third flow directing element 305 is made of stainless steel.

In some of these embodiments, the third drainage element 305 is a third drainage tube.

Specifically, the fourth drainage element 306 is connected to the storage element 101 and communicates with the first water outlet element 104.

The fourth drainage element 306 has a circular cross-section.

The fourth drainage element 306 is sized to match the size of the storage element 101. Typically, the outer diameter of the fourth drainage element 306 is smaller than the outer width/height of the storage element 101.

The fourth flow directing element 306 is sized to match the size of the first water outlet element 104. Generally, the inner diameter of the fourth flow directing element 306 is equal to the diameter of the first water outlet element 104.

In some of these embodiments, the fourth drainage element 306 is fixedly connected to the storage element 101. Including but not limited to bolting.

In some of these embodiments, the fourth drainage element 306 is made of stainless steel.

In some of these embodiments, the fourth drainage element 306 is a fourth drainage tube.

As shown in fig. 6, the support unit 400 includes a second bracket member 401 and a first movable member 402. The second bracket element 401 is disposed at the top end of the storage unit 100 and is connected to the storage unit 100; the first movable element 402 is disposed at the top end of the second support element 401 and is movably connected to the water lifting unit 500.

Specifically, the bottom end of the second holder member 401 is connected to the top end of the storage member 101.

The second bracket member 401 has an L-shaped cross section. Specifically, the second bracket member 401 includes a first riser, a first cross plate, and a second through hole. Wherein the bottom end of the first riser is connected with the storage element 101; the bottom end of the first transverse plate is connected with the top end of the first vertical plate; the second through hole penetrates through the top end of the first transverse plate.

The dimensions of the second bracket element 401 match the dimensions of the storage element 101. In general, the dimensions of the first riser match the dimensions of the storage element 101. Specifically, the length of the first riser is less than the outside length of the storage element 101 and the width of the first riser is less than the outside width of the storage element 101.

In some of these embodiments, the second bracket member 401 is fixedly connected to the storage member 101. Including but not limited to welding.

In some of these embodiments, the second bracket member 401 is made of stainless steel.

In some of these embodiments, the second bracket element 401 is a stand.

The first movable element 402 is circular in cross-section. Specifically, the first movable element 402 includes a bearing outer race and a bearing inner race. Wherein the bearing outer ring is connected with the first transverse plate; the bearing inner race is rotatably disposed within the bearing housing and is coupled to the water lifting unit 500.

The dimensions of the first movable element 402 match those of the second carriage element 401. Generally, the size of the bearing outer race matches the size of the first cross plate; the size of the bearing inner ring is matched with the size of the second through hole. Specifically, the outer diameter of the bearing outer race is less than the length/width of the first cross plate; the inner diameter of the bearing outer ring is equal to the inner diameter of the second through hole.

In some of these embodiments, the first movable element 402 is fixedly coupled to the second bracket element 401, including but not limited to a bolted connection.

In some of these embodiments, the first movable element 402 is made of a metal material.

In some of these embodiments, the first movable element 402 is a bearing housing.

As shown in fig. 7a, 7b and 8, the lifting unit 500 comprises a third bracket element 501, a first rotational element 502, a second movable element 503, a third movable element 504, a second rotational element 505, a second driving element 506, a third rotational element 507, a second sliding element 508 and a third sliding element 509. Wherein, the third bracket element 501 is disposed on top of the supporting unit 400 and is connected with the supporting unit 400; the first end of the first rotating element 502 is disposed on one side of the third bracket element 501 and is connected to the third bracket element 501; the top end of the second movable element 503 is rotatably connected with the second end of the first rotary element 502; the third movable element 504 is disposed on one side of the second movable element 503; two ends of the second rotating element 505 are respectively connected with the bottom end of the second movable element 503 and the bottom end of the third movable element 504; the first end of the second driving element 506 is connected to the top end of the third movable element 504, and is used for driving the third movable element 504, the second rotating element 505, the second movable element 503 and the third bracket element 501 to rotate relatively; the third rotating element 507 is rotatably connected to the second rotating element 505; the top end of the second sliding member 508 is connected to the third rotating member 507 and is slidably connected to the storage unit 100; the top end of the third sliding member 509 is connected to the bottom end of the second sliding member 508 and slidably connected to the storage unit 100 for draining rainwater of the storage unit 100 to the outside.

Specifically, the third support element 501 is disposed on top of the second support element 401 and is movably connected to the first movable element 402; the second slide member 508 is slidably coupled to the first slide member 106; the third sliding member 509 is slidably connected to the water collecting member 107.

More specifically, the third bracket element 501 is connected with the bearing inner ring.

The third bracket member 501 has an L-shaped cross section. Specifically, the third bracket member 501 includes a second cross plate, a second riser, and a third through hole. The second transverse plate is connected with the bearing inner ring; the second vertical plate is perpendicular to the top end of the second transverse plate and is connected with the second transverse plate; a third through hole is provided through the top end of the second cross plate for the second slide member 508 to pass through.

The third bracket element 501 is sized to match the size of the first movable element 402. Generally, the size of the second transverse plate is matched with the size of the bearing inner ring; the size of the third through hole is matched with the size of the bearing inner ring. Specifically, the length/width of the second cross plate is greater than the outer diameter of the bearing inner race; the diameter of the third through hole is equal to the inner diameter of the bearing inner ring.

In some of these embodiments, the third bracket element 501 is made of stainless steel.

In some of these embodiments, the third bracket element 501 is a support bracket.

The first rotating element 502 is circular in cross-section.

The first rotational element 502 is sized to match the size of the third bracket element 501. Generally, the first rotational element 502 is sized to match the size of the second riser. Specifically, the outer diameter of the first rotational element 502 is less than the length/height of the second riser.

In some of these embodiments, the first rotational element 502 is fixedly coupled to the third bracket element 501, including but not limited to welding.

In some of these embodiments, the first rotating element 502 is made of stainless steel.

In some of these embodiments, the first rotational element 502 is a rotational lever.

The second movable element 503 has a rectangular cross section.

The second movable element 503 is sized to match the size of the first rotatable element 502. Typically, the length/height of the second movable element 503 is greater than the diameter of the first rotatable element 502.

In some of these embodiments, the second movable element 503 is not separately rotationally coupled to the first rotatable element 502. For example, the second movable element 503 is connected to the first rotatable element 502 via a bearing housing.

In some of these embodiments, the second movable element 503 is made of stainless steel.

In some of these embodiments, the second movable element 503 is a first movable plate.

The third movable element 504 is rectangular in cross-section.

The dimensions of the third movable element 504 match those of the second movable element 503. In general, the length, width, and height of the third movable element 504 are equal to the length, width, and height of the second movable element 503.

In some of these embodiments, the third movable element 504 is made of stainless steel.

In some of these embodiments, the third movable element 504 is a second movable plate.

The second rotating member 505 has a circular cross section.

The dimensions of the second rotating element 505 match the dimensions of the second movable element 503/third movable element 504. Typically, the diameter of the second rotating element 505 is smaller than the length/height of the second moving element 503/the third moving element 504, and the axial dimension of the second rotating element 505 is equal to the distance between the second moving element 503 and the third moving element 504.

In some of these embodiments, the second rotating element 505 is fixedly coupled to the second movable element 503 and the third movable element 504, respectively, including but not limited to welding.

In some of these embodiments, the second rotating element 505 is made of stainless steel.

In some of these embodiments, the second rotating element 505 is a first rotating shaft.

The second drive element 506 is circular in cross-section.

The second drive element 506 is sized to match the size of the third movable element 504. Typically, the diameter of the second drive element 506 is smaller than the length/height of the third movable element 504.

In some of these embodiments, the second drive element 506 is fixedly coupled to the third movable element 504, including but not limited to welding.

In some of these embodiments, the second drive element 506 is made of stainless steel.

In some of these embodiments, the second drive element 506 is a second rotational shaft.

The third rotating element 507 has a circular cross section.

The third rotating element 507 is sized to match the size of the second rotating element 505. Generally, the inner diameter of the third rotating element 507 is not smaller than the diameter of the second rotating element 505.

Generally, the inner diameter of the third rotating element 507 is equal to the diameter of the second rotating element 505.

In some of these embodiments, the third rotating element 507 is made of stainless steel.

In some of these embodiments, the third rotational element 507 is a sleeve.

The second slide member 508 is circular in cross-section.

The dimensions of the second slide element 508 match the dimensions of the first slide element 106. Generally, the diameter of the second slide member 508 is smaller than the diameter of the first slide member 106.

In some of these embodiments, the second slide member 508 is made of nylon.

In some of these embodiments, the second slide element 508 is a rope.

The third slide member 509 has a rectangular cross-section.

The dimensions of the third sliding element 509 match those of the water collecting element 107. Typically, the length of the third sliding element 509 is equal to the inner side length of the water collecting element 107, the width of the third sliding element 509 is equal to the inner side width of the water collecting element 107, and the height of the third sliding element 509 is smaller than the inner side height of the water collecting element 107.

The dimensions of the third slide element 509 match those of the second slide element 508. Typically, the length/width of the third slide element 509 is greater than the diameter of the second slide element 508.

In some of these embodiments, the third slide element 509 is fixedly coupled to the second slide element 508, including but not limited to a bolted connection

In some of these embodiments, the third slide member 509 is made of stainless steel.

In some of these embodiments, the third slide element 509 is a lifting block.

Further, the water lifting unit 500 further includes a first connection member 510, a fourth rotation member 511, a second connection member 512, and a fifth rotation member 513. Wherein the top end of the first connecting element 510 is connected with the third rotating element 507; the top end of the fourth rotating member 511 is connected to the bottom end of the first connecting member 510; the bottom end of the second connecting element 512 is connected to the top end of the second sliding element 508; the fifth rotating member 513 is disposed at the top end of the second connecting member 512 and is rotatably connected to the fourth rotating member 511.

The first connection element 510 has a circular cross-section.

The first coupling element 510 is dimensioned to match the dimensions of the third rotating element 507. Generally, the diameter of the first coupling element 510 is not greater than the axial dimension of the third rotational element 507.

In some of these embodiments, the first coupling element 510 is fixedly coupled to the third rotational element 507, including but not limited to a bolted connection

In some of these embodiments, the first coupling element 510 is made of stainless steel.

In some of these embodiments, the first connection element 510 is a movable rod.

The fourth rotating element 511 has a U-shaped cross section. Specifically, the fourth rotating element 511 includes a third cross plate and two third risers. Wherein the top end of the third cross plate is connected with the first connecting element 510; the two third risers are symmetrically disposed at the bottom ends of the third transverse plates and are rotatably connected to the fifth rotating element 513.

The fourth rotating member 511 has a size matching that of the first coupling member 510. In general, the third cross plate has a size matching that of the first connection element 510. Specifically, the length/width of the third cross plate is greater than the diameter of the first connecting element 510.

In some of these embodiments, the fourth rotational element 511 is not separately rotationally coupled to the first coupling element 510. For example, the fourth rotating member 511 is connected to the first connecting member 510 through a bearing housing.

In some of these embodiments, the fourth rotating element 511 is made of stainless steel.

In some of these embodiments, the fourth rotating element 511 is a movable frame.

The second connecting element 512 has a rectangular cross section.

The second connecting element 512 is sized to match the size of the second sliding element 508. Typically, the length of the second connecting element 512 is greater than the diameter of the second sliding element 508, and the width of the second connecting element 512 is less than the diameter of the second sliding element 508.

In some of these embodiments, second coupling member 512 is fixedly coupled to second slide member 508, including, but not limited to, a bolted connection

In some of these embodiments, the second connecting element 512 is made of stainless steel.

In some of these embodiments, the second connecting element 512 is a third movable plate.

The fifth rotating element 513 has a circular cross section.

The fifth rotating element 513 is sized to match the size of the second connecting element 512. Generally, the diameter of the fifth rotating element 513 is smaller than the length/height of the second connecting element 512, and the axial dimension of the fifth rotating element 513 is larger than the width of the second connecting element 512.

The size of the fifth rotating member 513 is matched to the size of the fourth rotating member 511. Generally, the fifth rotating element 513 is sized to match the size of the two third risers. Specifically, the diameter of the fifth rotating element 513 is smaller than the length/width of the third risers, and the axial dimension of the fifth rotating element 513 is equal to the distance between the two third risers.

In some of these embodiments, the fifth rotating element 513 is fixedly coupled to the second connecting element 512, including but not limited to welding. For example, the fifth rotating element 513 is integrally formed with the second connecting element 512.

In some of these embodiments, the fifth rotating element 513 is not separately connected to the fourth rotating element 511. For example, the fifth rotating element 513 is connected to the fourth rotating element 511 through a bearing housing.

In some of these embodiments, the fifth rotating element 513 is made of stainless steel.

In some of these embodiments, the fifth rotating element 513 is a third rotating shaft.

Further, the lifting unit 500 also comprises a tail element 514. The tail element 514 is connected to the other side of the third support element 501, and is used for driving the third support element 501 to perform automatic direction finding.

The tail element 514 includes a mounting bar and a tail. Wherein the first end of the mounting rod is connected with the second vertical plate; the fin is connected with the second end of the mounting rod.

The size of the tail element 514 matches the size of the third bracket element 501. Generally, the mounting bar is sized to match the size of the second riser. In particular, the diameter of the mounting bar is smaller than the length/height of the second riser.

In some of these embodiments, the tail element 514 is fixedly attached to the third bracket element 501, including but not limited to welding.

In some of these embodiments, the tail element 514 is made of carbon fiber.

Further, the water lifting unit 500 further comprises a fan blade element 515. Wherein the fan blade element 515 is disposed at the second end of the second driving element 506.

The fan blade element 515 comprises a rotating disk and a number of fan blades. Wherein the rotating disc is connected to a second end of the second drive element 506; the fan blades are distributed on the end face of the rotating disc.

The fan blades are uniformly distributed along the axle center of the rotating disc.

In some embodiments, the number of fan blades is 7.

The dimensions of the blade element 515 match the dimensions of the second drive element 506. Generally, the size of the rotating disk matches the size of the second drive element 506. Specifically, the diameter of the rotating disk is greater than the diameter of the second drive element 506.

In some of these embodiments, the fan blade element 515 is fixedly coupled to the second drive element 506, including but not limited to welding.

In some of these embodiments, the blade element 515 is made of carbon fiber.

In some of these embodiments, the fan blade element 515 is a windmill.

The application method of the utility model is as follows:

(one) installation

Firstly, an operator opens a reserved landfill pit on a designated ground, places the storage element 101 in the landfill pit, and exposes the second water outlet element 105 to the ground;

next, the collecting element 201 is mounted by external bolts at the designated roof or high and the first drainage element 202 is put in communication with the first water intake element 103;

finally, the first bracket element 301 is mounted to the designated skylight or window by external bolts, the first drive element 304 is mounted to the skylight or window wall by external bolts, and the fourth drain element 306 is in communication with the first water outlet element 104.

(II) work

In rainy days, rainwater enters the storage element 101 through the collecting element 201 and the first drainage element 202 for storage (the rainwater is filtered by a conventional filtering means in the prior art before entering);

the first driving element 304 works to enable the rainwater of the storage element 101 to be conveyed to the third drainage element 305, the third drainage element 305 conveys the rainwater to the second drainage element 302, and finally the rainwater is sprayed out by the spraying element 303, so that the spraying on a building roof or a skylight is realized;

the second driving element 506 rotates under the action of manpower or wind force, and drives the third movable element 504, the second rotating element 505 and the second movable element 503 to rotate along the first rotating element 502;

the second rotating element 505 drives the first connecting element 510 and the fourth rotating element 511 to change positions along the first rotating element 502 through the third rotating element 507, and meanwhile, the third rotating element 507 drives the first connecting element 510 and the fourth rotating element 511 to change positions along the second rotating element 505;

the fourth rotating element 511 can drive the second sliding element 508 to move upwards along the first sliding element 106 through the fifth rotating element 513 and the second connecting element 512, and at this time, the second connecting element 512 will change position along the fifth rotating element 513 and drive the third sliding element 509 to reciprocate from the lower position to the higher position of the water collecting element 107;

When the third sliding element 509 moves to the lower position of the water collecting element 107 (and is lower than the second water inlet element 108), rainwater in the storage element 101 enters the water collecting element 107 through the second water inlet element 108, and as the third sliding element 509 moves upwards gradually, part of rainwater is driven to move upwards along the water collecting element 107 until flowing out into the drainage cavity of the storage element 101, and finally, is drained by the second water outlet element 105;

when the wind force is insufficient, the wind power can be used as standby power by an external water pump (not shown in the figure).

The utility model has the advantages that the water lifting unit is used as power, rainwater is lifted by wind power to irrigate crops, the water pump is replaced by the power, a part of energy consumption generated by the water pump is counteracted, the energy demand is relieved, and the water lifting unit can be used as a decorative object to improve the beauty; the rainwater can be drained to the building roof or the skylight by utilizing the spraying unit, and the rainwater can be used when the air temperature is higher, so that the building roof or the skylight is sprayed and cooled by utilizing the rainwater, the influence of solar radiation on the indoor temperature is reduced, and the indoor comfort level is improved.

The foregoing description is only illustrative of the preferred embodiments of the present utility model and is not to be construed as limiting the scope of the utility model, and it will be appreciated by those skilled in the art that equivalent substitutions and obvious variations may be made using the description and illustrations of the present utility model, and are intended to be included within the scope of the present utility model.

Claims (10)

1. A rainwater recycling device, comprising:

the storage unit (100), the said storage unit (100) is buried in the ground, the top of the said storage unit (100) exposes to the ground, is used for storing the rainwater;

the drainage unit (200) is arranged on a roof or at a high position and is communicated with the storage unit (100) and used for guiding rainwater to the storage unit (100);

a spraying unit (300), wherein a water spray port of the spraying unit (300) is arranged at a skylight or a window and is communicated with the storage unit (100) for spraying rainwater to the storage unit (100);

the supporting unit (400) is arranged at the top end of the storage unit (100) and is connected with the storage unit (100);

the water lifting unit (500), the water lifting unit (500) set up in the top of supporting unit (400), and with supporting unit (400) swing joint, the bottom of water lifting unit (500) slidingly set up in the inside of storing unit (100), be used for extracting the rainwater in storing unit (100).

2. The stormwater recycling apparatus as claimed in claim 1, wherein the storage unit (100) comprises:

the storage element (101) is buried in the ground, and the top end of the storage element (101) is exposed to the ground and is respectively communicated with the drainage unit (200) and the spraying unit (300) for collecting rainwater;

A partition member (102), the partition member (102) being provided inside the storage member (101) for partitioning the storage member (101) into a storage chamber and a drainage chamber;

the first water inlet element (103), the first water inlet element (103) is arranged at the side part of the storage element (101) and is respectively communicated with the storage cavity and the drainage unit (200) for the drainage unit (200) to drain rainwater;

the first water outlet element (104) is arranged at the side part of the storage element (101) and is respectively communicated with the storage cavity and the spraying unit (300) for conveying rainwater to the spraying unit (300);

a second water outlet element (105), wherein the second water outlet element (105) is arranged at the side part of the storage element (101) and is communicated with a water drainage cavity for draining water under the action of the water lifting unit (500);

the first sliding element (106) is arranged at the top end of the storage element (101) and is in sliding connection with the water lifting unit (500).

3. The stormwater recycling apparatus as claimed in claim 2, wherein the storage unit (100) further comprises:

the water collecting element (107), the water collecting element (107) is arranged in the storage element (101), the top end of the water collecting element (107) is connected with the partition plate element (102), the water collecting element (107) is slidably connected with the water lifting unit (500), and the water collecting element (107) is respectively communicated with the storage cavity and the drainage cavity;

And the second water inlet element (108) is arranged at the side part of the water collecting element (107) and is communicated with the storage cavity, and rainwater in the storage cavity enters the water collecting element (107).

4. The rainwater recycling apparatus according to claim 1, wherein the drainage unit (200) includes:

-a collecting element (201), the collecting element (201) being arranged on a roof or at a height for collecting rainwater by the storage unit (100);

the first drainage element (202), first drainage element (202) respectively with collecting element (201) storage unit (100) intercommunication is used for guiding rainwater to storage unit (100).

5. The rainwater recycling apparatus according to claim 1, wherein the spraying unit (300) includes:

-a first bracket element (301), said first bracket element (301) being arranged at a wall surface of a skylight or window;

a second drainage element (302), wherein the second drainage element (302) is arranged on the inner side of the first bracket element (301) and is connected with the first bracket element (301);

the plurality of spraying elements (303), the plurality of spraying elements (303) are distributed and provided with the second drainage elements (302) and are communicated with the second drainage elements (302) for spraying rainwater;

-a first driving element (304), the first driving element (304) being in communication with the second drainage element (302) and the storage unit (100) for drainage of rainwater in the storage unit (100) to the second drainage element (302).

6. The rainwater recycling apparatus according to claim 5, wherein the spraying unit (300) further includes:

-a third drainage element (305), the third drainage element (305) being in communication with the first drive element (304), the second drainage element (302), respectively;

-a fourth drainage element (306), the fourth drainage element (306) being in communication with the first drive element (304), the storage unit (100), respectively.

7. The rainwater recycling apparatus according to claim 1, wherein the supporting unit (400) includes:

a second bracket member (401), wherein the second bracket member (401) is arranged at the top end of the storage unit (100) and is connected with the storage unit (100);

the first movable element (402), the first movable element (402) set up in the top of second support component (401) and with water lifting unit (500) swing joint.

8. The rainwater recycling apparatus according to claim 1, wherein the water lifting unit (500) includes:

A third bracket member (501), the third bracket member (501) being provided on top of the support unit (400) and being connected to the support unit (400);

a first rotating element (502), wherein a first end of the first rotating element (502) is arranged at one side of the third bracket element (501) and is connected with the third bracket element (501);

a second movable element (503), wherein the top end of the second movable element (503) is rotatably connected with the second end of the first rotary element (502);

-a third movable element (504), the third movable element (504) being arranged to one side of the second movable element (503);

the two ends of the second rotating element (505) are respectively connected with the bottom end of the second movable element (503) and the bottom end of the third movable element (504);

the first end of the second driving element (506) is connected with the top end of the third movable element (504) and is used for driving the third movable element (504), the second rotating element (505), the second movable element (503) and the third bracket element (501) to rotate relatively;

a third rotating element (507), the third rotating element (507) being rotationally connected to the second rotating element (505);

-a second sliding element (508), the top end of the second sliding element (508) being connected to the third rotating element (507) and being slidingly connected to the storage unit (100);

and a third sliding element (509), wherein the top end of the third sliding element (509) is connected with the bottom end of the second sliding element (508) and is slidably connected with the storage unit (100) for draining rainwater of the storage unit (100) outwards.

9. The stormwater recycling apparatus as claimed in claim 8, wherein the water lifting unit (500) further comprises:

a first connecting element (510), the top end of the first connecting element (510) being connected to the third rotating element (507);

a fourth rotating element (511), a top end of the fourth rotating element (511) being connected to a bottom end of the first connecting element (510);

-a second connecting element (512), the bottom end of the second connecting element (512) being connected to the top end of the second sliding element (508);

and a fifth rotating element (513), wherein the fifth rotating element (513) is arranged at the top end of the second connecting element (512) and is rotationally connected with the fourth rotating element (511).

10. The stormwater recycling apparatus as claimed in claim 8 or 9, wherein the water lifting unit (500) further comprises:

The tail wing element (514) is connected with the other side of the third support element (501) and is used for driving the third support element (501) to automatically seek; and/or

-a fan blade element (515), said fan blade element (515) being arranged at a second end of said second drive element (506).