CN217152181U - Energy storage equipment based on natural wind conversion is high-pressure gas - Google Patents

Abstract

An energy storage device based on natural wind conversion into high-pressure gas belongs to energy storage power generation equipment. Set up the high wind subassembly between first wind wheel and the second wind wheel, first wind wheel passes through the high wind subassembly and changes natural wind into high wind and give the second wind wheel for, be connected with the air pump between second wind wheel and the gas holder, the second wind wheel drives the air pump and rotates the high-pressure gas that produces and be stored by the gas holder, the external blowing pipe of gas holder, set up mechanical energy conversion device between blowing pipe and the generator, the blowing pipe passes through mechanical energy conversion device and converts the wind energy into mechanical energy and provides the power source for the generator, the air pump links into the electric wire netting. The utility model discloses it is rotatory to utilize natural wind to blow the wind wheel, can utilize irregular wind and the indefinite wind of size, does not receive the strong wind influence, turns into regular stable strong wind, and high-pressure gas and energy storage are transformed in order to guarantee balanced stable electricity generation once more.

Description

Energy storage equipment based on natural wind conversion is high-pressure gas

Technical Field

The utility model belongs to energy storage power generation equipment, concretely relates to energy storage equipment based on natural wind changes into high-pressure gas.

Background

The wind power generator is an electric power device which converts wind energy into mechanical work, and the mechanical work drives blades of the generator to rotate so as to finally output alternating current. However, the existing wind power generation technology has the problems that when the wind power is small, the wind cannot generate power without rotating the fan blades, the wind power is too large, the machine is stopped to be afraid of the problem that the fan blades are broken, and the generated power is unstable depending on natural wind.

SUMMERY OF THE UTILITY MODEL

The utility model aims to solve the problems existing in the prior art and further provides an energy storage device based on the conversion of natural wind into high-pressure gas;

the utility model adopts the technical proposal that: an energy storage device for converting natural wind into high-pressure gas comprises a first wind wheel, a second wind wheel, a strong wind assembly, a gas storage tank, an air pump, a blowing pipe, a mechanical energy conversion device and a generator; set up the high wind subassembly between first wind wheel and the second wind wheel, first wind wheel passes through the high wind subassembly and changes natural wind into high wind and give the second wind wheel for, is connected with the air pump between second wind wheel and the gas holder, and the second wind wheel drives the air pump and rotates the high-pressure gas that produces and store by the gas holder, the external blowing pipe of gas holder, set up mechanical energy conversion device between blowing pipe and the generator, the blowing pipe passes through mechanical energy conversion device and converts the wind energy into mechanical energy and provides the power source for the generator, the air pump even goes into the electric wire netting.

Compared with the prior art, the utility model following beneficial effect has:

1. the utility model discloses changed the tradition and directly blown the form of generator fan blade electricity generation with wind, avoided the irrotational problem of fan blade in the wind-force hour, the utility model discloses utilize natural wind to blow the wind wheel rotatory, can utilize irregular wind and the indefinite wind of size, not influenced by strong wind, turn into regular stable strong wind, high-pressure gas and the energy storage of reforming transform once more is in order to guarantee the balanced stable electricity generation.

2. The utility model discloses a wind wheel rigidity is strong, and the harm that strong wind brought can be overcome to the solid.

3. The utility model discloses can realize big-and-small-size miniaturisation, can be N middle-and-small-size mill construct power generation facility alone and with the synchronous power supply of electric wire netting, can promote fast, can solve the problem that the power consumption is with high costs, can realize the low carbon power consumption fast. Outdoor a plurality of pylon occupy the soil, because the utility model discloses a wind wheel is circular, is located the top of pylon, and the agricultural equipment can be built to the unnecessary space in solid lower part, improves more than 2 times at least of land utilization ratio, realizes agricultural batch production.

4. The utility model has the advantages of less investment, low maintenance cost, low failure rate and the like.

Drawings

FIG. 1 is a schematic structural view of the present invention;

wherein: 1. a first wind wheel; 2. a strong wind assembly; 3. a second wind wheel; 4. a second gearbox; 5. an air pump; 6. a second tower; 7. a gas storage tank; 8. an intake manifold; 9. a gas outlet header pipe; 10. a blowpipe; 11. a mechanical energy conversion device; 12. a generator; 13. a second conduit; 14. a third pipeline; 21. a first gearbox; 22. an impeller; 23. a first tower; 24. a wind cavity; 25. a first conduit; 111. a generator blade; 112. a third gearbox; 113. a third tower.

Detailed Description

The energy storage equipment utilizes natural irregular wind to blow the first wind wheel 1 to rotate and drives the impeller 22 in the first tower 23 to rotate at a high speed through the first gearbox 21 to produce high-strength wind. The first pipeline 25 is used for conveying high-intensity wind to the second tower 6 to blow the second wind wheel 3 to rotate, the speed is increased through the second gearbox 4 to drive the air pump 5 to work to produce high-pressure gas, the high-pressure gas is conveyed to the air storage tank 7 to be stored, the high-pressure gas is conveyed in a graded mode according to pressure in a grouping mode, the blades 111 of the generator are pushed to rotate, the speed is increased through the third gearbox 112 to drive the generator 12 to generate power in a balanced mode. Waste gas generated by pushing the generator blades 111 is conveyed to the second wind wheel 3 through the second pipeline 13, high-pressure gas is generated by secondarily utilizing the air pump 5, then the generator blades 111 are pushed to generate waste gas again, and the waste gas is conveyed to the first tower 23 through the third pipeline 14 to supplement an air source to push the first wind wheel 1 to rotate, and balanced power generation is achieved.

Because the natural wind comes and goes freely and uncontrollably, the air pump 5 is driven to work to generate high-pressure gas when the power grid is used at the low ebb of the power consumption in the absence of wind, the high-pressure gas is stored in the gas storage tank 7, and the power generation is carried out at the high ebb of the power consumption so as to ensure that the power generation equipment generates power uniformly every day. The system completely adopts a computer to automatically control the pressure, and the high-pressure gas is automatically regulated and controlled, so that unmanned control is completely realized.

The first specific implementation way is as follows: referring to fig. 1 to illustrate the present embodiment, the present embodiment provides an energy storage device for converting natural wind into high-pressure gas, which includes a first wind wheel 1, a second wind wheel 3, a strong wind assembly 2, an air storage tank 7, an air pump 5, a blowing pipe 10, a mechanical energy conversion device 11, and a generator 12; set up strong wind subassembly 2 between first wind wheel 1 and the second wind wheel 3, first wind wheel 1 changes the natural wind into strong wind and transmits for second wind wheel 3 through strong wind subassembly 2, is connected with air pump 5 between second wind wheel 3 and the gas holder 7, and second wind wheel 3 drives air pump 5 and rotates the high-pressure gas that produces and store by gas holder 7, the external blowing pipe 10 of gas holder 7, set up mechanical energy conversion device 11 between blowing pipe 10 and the generator 12, blowing pipe 10 provides the power source for generator 12 through mechanical energy conversion device 11 with wind energy conversion, the electric wire netting is even gone into to air pump 5.

The second embodiment is as follows: the present embodiment is described with reference to fig. 1, and is further limited to the first specific embodiment, in which the axes of the first wind rotor 1 and the second wind rotor 3 are both vertically arranged. Other components and connection modes are the same as those of the first embodiment.

The third concrete implementation mode: the present embodiment is described with reference to fig. 1, and the present embodiment further defines a second embodiment, and in the present embodiment, the strong wind module 2 includes an impeller 22, a first tower 23, and a first duct 25; first pylon 23 is installed subaerial, first pylon 23 upper end is equipped with wind chamber 24, impeller 22 is connected with first wind wheel 1, and impeller 22 installs in wind chamber 24, set up air inlet and air outlet on the wind chamber 24, the air outlet is connected with first pipeline 25 one end, the other end of first pipeline 25 sets up towards second wind wheel 3. The other components and the connection mode are the same as those of the second embodiment.

In this embodiment, natural wind blows the first wind wheel 1 to rotate, and drives the impeller 22 to generate strong wind in the wind cavity 24, and the first pipeline 25 is used to convey the strong wind to the second wind wheel 3, so that the second wind wheel 3 rotates.

In the fourth embodiment, the present embodiment is described with reference to fig. 1, and the third embodiment is further limited in this embodiment, and in this embodiment, the first wind turbine 1 is in transmission connection with the impeller 22 through the first transmission case 21.

In the present embodiment, the first transmission case 21 is used to increase the rotational speed of the impeller 22, thereby increasing the wind power.

The fifth concrete implementation mode: referring to fig. 1, the present embodiment is described, and the present embodiment further defines a first specific embodiment, in the present embodiment, the second wind turbine 3 is connected to the air pump 5 through the second gearbox 4, and the second wind turbine 3, the second gearbox 4 and the air pump 5 are all supported by the second tower 6. Other components and connection modes are the same as those of the first embodiment.

In the present embodiment, the second transmission case 4 is used to increase the rotation speed of the input shaft of the air pump 5, thereby increasing the output power of the air pump 5.

The sixth specific implementation mode: the present embodiment is described with reference to fig. 1, and the present embodiment further defines a first specific embodiment, and in the present embodiment, the mechanical energy conversion device 11 includes a generator blade 111, a third transmission case 112, and a third tower 113; the generator blade 111 is connected with an input shaft of the generator 12 through a third gearbox 112, and the generator blade 111, the third gearbox 112 and the generator 12 are all installed in a closed inner cavity of a third tower 113. Other components and connection modes are the same as those of the first embodiment.

The seventh embodiment: referring to fig. 1, the present embodiment is described, and the present embodiment further defines a sixth specific embodiment, in the present embodiment, the number of the air storage tanks 7 is multiple, and the multiple air storage tanks 7 are used for sequentially storing the high-pressure gas generated by the air pump 5, and sequentially conveying the high-pressure gas according to the pressure gradient in the air storage tanks 7 to push the generator blades 111 to rotate, the air inlet of each air storage tank 7 is collectively communicated with the air outlet of the air pump 5 through an air inlet manifold 8, and the air outlet of each air storage tank 7 is collectively communicated with the blowpipe 10 through an air outlet manifold 9. Other components and connection modes are the same as those of the sixth embodiment.

The specific implementation mode is eight: the present embodiment is described with reference to fig. 1, and the present embodiment further defines a first specific embodiment, and in the present embodiment, the first wind wheel 1 is a circular wind wheel formed by connecting a plurality of groups of blades in a surrounding manner. Other components and connection modes are the same as those of the first embodiment.

In this embodiment, the first wind wheel 1 has high rigidity, and can overcome the harm caused by strong wind.

The specific implementation mode is eight: the embodiment is described with reference to fig. 1, and the embodiment further defines a first specific embodiment, in which the energy storage equipment for converting natural wind into high-pressure gas further includes a second pipeline 13 and a third pipeline 14, one end of each of the second pipeline 13 and the third pipeline 14 is communicated with the sealed inner cavity of the third tower 113, an outlet at the other end of the second pipeline 13 is disposed at the second wind wheel 3, and an outlet at the other end of the third pipeline 14 is disposed at the first wind wheel 1. The method is used for secondary and tertiary utilization of the exhaust gas at the generator blade 111.

The first pipe 25, the second pipe 13 and the third pipe 14 are all provided with switch valves.

It is to be understood that the present invention has been described with reference to certain embodiments, and that various changes or equivalents may be substituted for elements thereof by those skilled in the art without departing from the spirit and scope of the invention. In addition, many modifications may be made to adapt a particular situation or material to the teachings of the invention without departing from the essential scope thereof. Therefore, the present invention is not limited to the specific embodiments disclosed herein, and all embodiments falling within the scope of the claims of the present application are intended to be covered by the present invention.

Claims (9)

1. The utility model provides an energy storage equipment based on natural wind changes to high-pressure gas which characterized in that: the wind power generation device comprises a first wind wheel (1), a second wind wheel (3), a strong wind component (2), a gas storage tank (7), an air pump (5), a blowing pipe (10), a mechanical energy conversion device (11) and a generator (12); set up strong wind subassembly (2) between first wind wheel (1) and second wind wheel (3), first wind wheel (1) through strong wind subassembly (2) with natural wind conversion for strong wind and transmit for second wind wheel (3), be connected with air pump (5) between second wind wheel (3) and gas holder (7), second wind wheel (3) drive air pump (5) and rotate the high-pressure gas that produces and store by gas holder (7), external blowing pipe (10) of gas holder (7), set up mechanical energy conversion device (11) between blowing pipe (10) and generator (12), blowing pipe (10) provide power source for generator (12) through mechanical energy conversion device (11) with wind energy conversion, air pump (5) are even gone into the electric wire netting.

2. The energy storage device based on natural wind conversion into high-pressure gas according to claim 1, characterized in that: the axes of the first wind wheel (1) and the second wind wheel (3) are both vertically arranged.

3. The energy storage device based on natural wind conversion into high-pressure gas according to claim 2, characterized in that: the strong wind assembly (2) comprises an impeller (22), a first tower (23) and a first pipeline (25); first pylon (23) is installed subaerial, first pylon (23) upper end is equipped with wind chamber (24), impeller (22) are connected with first wind wheel (1), and install in wind chamber (24) impeller (22), set up air inlet and air outlet on wind chamber (24), the air outlet is connected with first pipeline (25) one end, first pipeline (25) other end sets up towards second wind wheel (3).

4. The energy storage device based on natural wind conversion into high-pressure gas according to claim 3, characterized in that: the first wind wheel (1) is in transmission connection with the impeller (22) through a first gearbox (21).

5. The energy storage device based on natural wind conversion into high-pressure gas according to claim 1, characterized in that: the second wind wheel (3) is connected with the air pump (5) through a second gearbox (4), and the second wind wheel (3), the second gearbox (4) and the air pump (5) are all supported through a second tower (6).

6. The energy storage device based on natural wind conversion into high-pressure gas according to claim 1, characterized in that: the mechanical energy conversion device (11) comprises a generator blade (111), a third gearbox (112) and a third tower (113); the generator blade (111) is connected with an input shaft of the generator (12) through a third gearbox (112), and the generator blade (111), the third gearbox (112) and the generator (12) are all installed in a closed inner cavity of a third tower (113).

7. The energy storage device based on natural wind conversion into high-pressure gas according to claim 6, characterized in that: the quantity of gas holder (7) is a plurality of for store the high-pressure gas that air pump (5) produced in proper order, and carry out the order according to the pressure echelon in gas holder (7) and carry high-pressure gas and promote generator blade (111) rotation, the air inlet of every gas holder (7) all gathers the intercommunication through air intake manifold (8) and air pump (5)'s gas outlet, the gas outlet of every gas holder (7) all gathers the intercommunication through air outlet manifold (9) and blowing pipe (10).

8. The energy storage device based on natural wind conversion into high-pressure gas according to claim 1, characterized in that: the first wind wheel (1) is a circular wind wheel formed by connecting a plurality of groups of blades in a surrounding manner.

9. The energy storage device based on natural wind conversion into high-pressure gas according to claim 1, characterized in that: the energy storage equipment based on natural wind conversion to high-pressure gas further comprises a second pipeline (13) and a third pipeline (14), one end of the second pipeline (13) and one end of the third pipeline (14) are communicated with an airtight inner cavity of a third tower (113), the outlet of the other end of the second pipeline (13) is formed in the position of the second wind wheel (3), and the outlet of the other end of the third pipeline (14) is formed in the position of the first wind wheel (1).

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