CN110601640A - Photovoltaic power generation device based on wind power generation foundation and installation method thereof - Google Patents

Abstract

The invention discloses a photovoltaic power generation device based on a wind power generation foundation and an installation method thereof, wherein the photovoltaic power generation device based on the wind power generation foundation comprises a truncated cone-shaped wind power generation base arranged underground, and an annular inclined plane of the truncated cone-shaped wind power generation base consists of a sector annular lighting area and a sector maintenance area; the lighting area is fixedly connected with a plurality of steel piles, and the upper part of each steel pile is fixedly connected with a photovoltaic plate arranged above the ground; the maintenance area is provided with a sector radius in the due north direction; the installation method of the photovoltaic power generation device based on the wind power generation foundation comprises the steps of dividing installation areas and installing steel piles in a partition mode. Compared with the prior art, the invention can shorten the length of the steel pile, reduce the material consumption, provide the maintenance space for workers, and ensure the stability of the wind power generation base so that the fan on the wind power generation base always works normally. The invention is suitable for the circular truncated cone-shaped wind power generation base and is used for laying steel piles.

Description

Photovoltaic power generation device based on wind power generation foundation and installation method thereof

Technical Field

The invention belongs to the technical field of solar power generation, and particularly relates to a photovoltaic power generation device based on a wind power generation foundation and an installation method thereof.

Background

At present, the steel pile fixing mode of the photovoltaic plate in the photovoltaic power generation device is usually adopted to embed the steel pile into an underground concrete base for fixing, and the fixing mode has the following defects: firstly, the height of the photovoltaic panel on the ground is determined (about 1 m), and in order to ensure the stability of the concrete base, the concrete base is also placed underground to a determined depth (about 3 m); therefore, the plane on which the steel piles are arranged on the concrete base is a horizontal plane which is arranged underground to determine the depth, so that the lengths of the steel piles buried underground are the same, the purpose of saving materials cannot be achieved by shortening the length of the steel piles buried underground, and more materials are consumed; secondly, the concrete base in the prior art needs to be poured and manufactured in advance when in use, so that more labor force is consumed, the labor intensity is high, the time cost is increased, and the working efficiency is reduced; and thirdly, the area in the due north direction is a shadow area of the photovoltaic panel, and the electricity taking efficiency is low even if the photovoltaic panel is arranged.

At present, a concrete base with a prefabricated steel pile mounting hole is generally cast in advance, and the method needs to cast the concrete base in advance, so that more labor force is consumed, the labor intensity is high, more concrete materials are consumed, the energy consumption is high, the working time is long, and the production cost is high.

Disclosure of Invention

In order to solve the defects in the prior art, the invention aims to provide a photovoltaic power generation device based on a wind power generation foundation so as to achieve the purposes of shortening the length of a steel pile, reducing material consumption and providing a maintenance space for workers; the invention aims to provide a method for installing a photovoltaic power generation device based on a wind power generation foundation, which aims to achieve the aim of ensuring the stability of a wind power generation base and ensuring that a fan on the wind power generation base always works normally when the photovoltaic power generation device is installed.

In order to achieve the purpose, the technical scheme adopted by the invention is as follows: a photovoltaic power generation device based on a wind power generation foundation comprises a truncated cone-shaped wind power generation base arranged underground, wherein an annular inclined plane of the truncated cone-shaped wind power generation base consists of a sector annular lighting area and a sector maintenance area; the lighting area is fixedly connected with a plurality of steel piles, and the upper part of each steel pile is fixedly connected with a photovoltaic plate arranged above the ground; the service area has a sector radius in the true north direction.

As the limitation of the invention, the bottom end of each steel pile is fixedly connected with a steel plate parallel to the inclined plane of the wind power generation base, and the steel plate is fixedly connected with the wind power generation base through an expansion bolt.

As a further limitation of the invention, the symmetry axis of the inspection area is located in the true north direction, and the fan-shaped central angle of the inspection area is 90-105 deg.

As another limitation of the invention, a plurality of arcs concentric with the sector ring are arranged on the lighting area, and steel piles distributed in an arc shape are fixed on each arc.

As another limitation of the present invention, the sector annular lighting area is divided into a plurality of groups of sectors, photovoltaic panels in each sector are connected in series to form a group string through photovoltaic cables, and a plurality of groups of strings are connected in parallel to the group string inverter.

Due to the adoption of the technical scheme, compared with the prior art, the photovoltaic power generation device based on the wind power generation foundation has the following beneficial effects:

(1) according to the invention, on the premise that the wind power generation base is buried underground for a certain depth to ensure the stability of the wind power generation base, the buried length of the steel pile is shortened and the material consumption is reduced by utilizing the inclination of the annular inclined plane on the truncated cone-shaped wind power generation base; in the prior art, the diameter of the steel pile needs to consider the load in the vertical direction and the load in the horizontal direction, and the diameter of the steel pile is set only by considering the load in the horizontal direction, so that the diameter of the steel pile is greatly reduced, and the material consumption is reduced;

(2) the solar power generation device can utilize the existing circular truncated cone-shaped wind power generation base as a solar power generation foundation, and does not need to pour and mix in advance, so that the labor force is reduced, and the labor intensity is reduced;

(3) the maintenance area is arranged in the due north direction, and the photovoltaic panel has extremely low electricity taking efficiency because the maintenance area is a shadow area of the photovoltaic panel, so that the maintenance area arranged in the due north direction can provide space for workers to maintain standing or storing tools, and is favorable for smooth maintenance;

(4) according to the invention, the steel piles distributed in an arc shape are arranged, so that solar energy at different moments can be collected, and the utilization rate of the photovoltaic panel is improved; the steel plate arranged in parallel with the wind power generation base is arranged, so that the steel pile can be more stably connected with the wind power generation base;

(5) according to the invention, photovoltaic panels in each sector are connected in series through photovoltaic cables to form a group of strings, so that the loss of output electric energy caused by shielding of local shadows is prevented, and the condition that the power generation amount of the whole group of strings is obviously reduced due to shielding of local photovoltaic panels of each photovoltaic group string is avoided;

in conclusion, the photovoltaic power generation system is stable in structure, convenient to use, low in production cost, capable of saving land resources for building photovoltaic projects in China and high in practicability.

The invention is suitable for being used on the built circular truncated cone-shaped wind power generation base and is used for distributing solar photovoltaic panels.

The invention also provides a method for installing the photovoltaic power generation device based on the wind power generation foundation, which is realized by utilizing the photovoltaic power generation device based on the wind power generation foundation, and the technical scheme is as follows: the method comprises the following steps:

the method comprises the following steps: dividing installation area

Dividing a circular lighting area on the circular truncated cone-shaped wind power generation base into a first sector area, a second sector area and an … … (n) th sector area, wherein n is more than or equal to 2;

step two: sectional installation steel pile

The first step (first): first sector installation steel pile

Firstly, digging plain soil on a first sector area, and drilling a mounting hole in the first sector area; then fixing the steel piles below the photovoltaic plate in the mounting holes of the first sector area, and covering plain soil on the first sector area;

the second step: second sector installation steel pile

Firstly digging plain soil on the second sector area, and drilling mounting holes in the second sector area; then fixing the steel piles below the photovoltaic plate in the mounting holes of the second sector area, and covering plain soil on the second sector area;

……

the (n) th step: steel pile for installing sector (n)

Firstly, digging plain soil on the (n) th sector area, and drilling a mounting hole on the (n) th sector area; and then fixing the steel piles below the photovoltaic plate in the mounting holes of the (n) th sector, and covering plain soil on the (n) th sector.

For the limitation of the present invention, when n is an even number: the first sector and the second sector are symmetrically arranged about the symmetry axis of the sectored service area, … …, the (n) th sector and the (n-1) th sector are symmetrically arranged about the symmetry axis of the sectored service area;

when n is an odd number: the first sector and the second sector are symmetrically disposed about an axis of symmetry of the sectored service area, … …, and the (n-2) th sector and the (n-1) th sector are symmetrically disposed about the axis of symmetry of the sectored service area.

As a further limitation of the present invention, step two: sectional installation steel pile

The first step (first): first sector installation steel pile

The first step 1 is to dig out a first sector arc A₁B₁Along arc A in the first sector₁B₁A plurality of mounting holes are drilled, and the steel plate at the bottom end of the steel pile is mounted on the arc A through expansion bolts₁B₁In the mounting hole, the steel pile is embedded into plain soil;

the first step 2, digging out the arc A of the first sector area₂B₂Along arc A in the first sector₂B₂Drilling a plurality of mounting holes, and mounting the steel plate at the bottom end of the steel pile on the arc A through expansion bolts₂B₂In the mounting hole, the steel pile is embedded into plain soil;

……

in the first m step, digging out the arc A of the first sector_mB_mAlong arc A in the first sector_mB_mA plurality of mounting holes are drilled, and the steel plate at the bottom end of the steel pile is mounted on the arc A through expansion bolts_mB_mIn the mounting hole, the steel pile is embedded into plain soil;

wherein m is more than or equal to 1 and arc A₁B₁Arc A₂B₂… … arc A_mB_mIs the fan-shaped peak of the first sector and arc A₁B₁Arc length, arc A₂B₂Arc length of … …, arc A_mB_mThe arc length of the arc is sequentially increased or decreased;

the second step: second sector installation steel pile

The second step (1) is to dig out a second sector arc C₁D₁Upper plain soil along arc C in the second sector₁D₁A plurality of mounting holes are drilled, and the steel plate at the bottom end of the steel pile is mounted on the arc C through expansion bolts₁D₁In the mounting hole, the steel pile is embedded into plain soil;

the second step (2) is to dig out a second sector arc C₂D₂Upper plain soil along arc C in the second sector₂D₂A plurality of mounting holes are drilled, and the steel plate at the bottom end of the steel pile is mounted on the arc C through expansion bolts₂D₂In the mounting hole, the steel pile is embedded into plain soil;

……

a second q step of digging a second sector arc C_qD_qUpper plain soil along arc C in the second sector_qD_qA plurality of mounting holes are drilled, and the steel plate at the bottom end of the steel pile is mounted on the arc C through expansion bolts_qD_qThen embedding the steel piles into plain soil;

wherein q is not less than 1 and arc C₁D₁Arc C₂D₂… … arc C_qD_qIs the circular sector vertex of the second sector and is arc C₁D₁Arc length, arc C₂D₂The arc length of,… … arc C_qD_qThe arc length of the arc is sequentially increased or decreased;

……

the (n) th step: steel pile for installing sector (n)

In the (n 1) th step, the arc E of the (n) th sector is excavated₁F₁Upper plain soil along arc E in the (n) th sector₁F₁Drilling a plurality of mounting holes, and mounting the steel plate at the bottom end of the steel pile on the arc E through expansion bolts₁F₁In the mounting hole, the steel pile is embedded into plain soil;

in the (n 2) th step, the arc E of the (n) th sector is excavated₂F₂Upper plain soil along arc E in the (n) th sector₂F₂Drilling a plurality of mounting holes, and mounting the steel plate at the bottom end of the steel pile on the arc E through expansion bolts₂F₂In the mounting hole, the steel pile is embedded into plain soil;

……

at the (np) th step, the (n) th sector arc E is dug_pF_pUpper plain soil along arc E in the (n) th sector_pF_pDrilling a plurality of mounting holes, and mounting the steel plate at the bottom end of the steel pile on the arc E through expansion bolts_pF_pIn the mounting hole, the steel pile is embedded into plain soil;

wherein p is more than or equal to 1 and arc E₁F₁Arc E₂F₂… … arc E_pF_pIs the sector vertex of the (n) th sector and arc E₁F₁Arc length, arc E of₂F₂Arc length of … …, arc E_pF_pThe arc lengths of (a) and (b) are sequentially increased or sequentially decreased.

As yet a further limitation of the present invention, arc A₁B₁Arc C₁D₁… … arc E₁F₁Are positioned on the same circle; arc A₂B₂Arc C₂D₂… … arc E₂F₂Are positioned on the same circle; … …, respectively; arc A_mB_mArc C_qD_q… … arc E_pF_pLocated on the same circleThe above.

As another limitation of the present invention, in the second step, before the mounting holes are punched along the different arcs, the punching positions are marked along the arcs by scribing lines, and a plurality of mounting holes are punched according to the marked punching positions.

Due to the adoption of the technical scheme, compared with the prior art, the installation method of the photovoltaic power generation device based on the wind power generation foundation has the following beneficial effects:

(1) the conventional circular truncated cone-shaped wind power generation base is used as a solar power generation foundation, and concrete does not need to be poured in advance for manufacturing, so that concrete materials are saved, labor force is reduced, and labor intensity is reduced;

(2) the invention can ensure the stability of the wind power generation base by installing the steel piles in different areas, and does not influence the normal work of the fan on the basis of wind power generation in the process of punching and installing the steel piles.

In conclusion, the invention has the advantages of simple and convenient operation, convenient installation and easy popularization.

The invention is suitable for the circular truncated cone-shaped wind power generation base and is used for installing the steel pile.

Drawings

The invention is described in further detail below with reference to the figures and the embodiments.

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

fig. 2 is a schematic view of a connection relationship between a steel pile 4 and a wind power generation base 1 according to embodiment 1 of the present invention;

fig. 3 is a plan view of a wind turbine base 1 according to embodiment 1 of the present invention.

In the figure: 1. a wind power generation base; 2. a lighting area; 3. a maintenance area; 4. steel piles; 5. a photovoltaic panel; 6. a steel plate; 7. an expansion bolt; 8. a fan; 9. plain soil; 11. a first sector; 12. a second sector; 13. a third sector; 14. a fourth sector; 15. a fifth sector; 16. a sixth sector.

Detailed Description

Preferred embodiments of the present invention will be described below with reference to the accompanying drawings. It should be understood that the description of the preferred embodiment is only for purposes of illustration and understanding, and is not intended to limit the invention.

Embodiment 1 photovoltaic power generation device based on wind power generation foundation

As shown in fig. 1 to 3, in the present embodiment, a wind power generation base 1 is used as a solar power generation foundation, and steel piles 4 of photovoltaic panels 5 are arranged on the wind power generation base 1.

The wind power generation base 1 is arranged underground and is a circular truncated cone-shaped concrete wind power generation base. The curved surface (i.e., the inclined surface) of the wind power generation base 1 is circular, and the annular inclined surface of the wind power generation base 1 is divided into a lighting area 2 and an overhaul area 3.

(1) Service area 3

Maintenance area 3 is fan-shaped, and maintenance area 3 is located the north side, and the direct irradiation that can not accept the sunlight is the shadow district of photovoltaic board 5, does not set up photovoltaic board 5 and piling bar 4 in this region, can supply the equipment maintenance or provide the space for placing of maintenance instrument. The service area 3 has a sector radius in the north direction, preferably the axis of symmetry of the sector of the service area 3 is in the north direction. The fan-shaped central angle of the maintenance area 3 is 90-105 degrees.

(2) Daylighting area 2

The lighting area 2 is in a fan-shaped ring shape, and the central angle of the fan-shaped ring is 255-270 degrees. A plurality of steel piles 4 are fixed in the lighting area 2, and the upper part of each steel pile 4 is fixedly connected with a solar photovoltaic panel 5 arranged above the ground. The steel pile 4 is a steel pipe pile. The bottom end of each steel pile 4 is welded with a steel plate 6, and each steel plate 6 is fixedly connected with the wind power generation base 1 through an expansion bolt 7. The steel plate 6 has the same inclination angle with the inclined surface of the wind power generation base 1.

The lighting area 2 has a plurality of arcs concentric with the fan ring, such as arc A shown in FIG. 3₁C₁Arc line A₂C₂Arc line A₃C₃Each arc line is fixed with steel piles 4 distributed in an arc shape, namely, the arc line A₁C₁A plurality of steel piles 4 are distributed on the upper part of the arc line A₂C₂A plurality of steel piles 4 are distributed on the upper part of the arc line A₃C₃A plurality of steel piles 4 are distributed on the upper part. Thus, due to different arcsThe degree of depth on the relative ground of line is different, so the length of piling bar 4 is different on different arcs, arranges photovoltaic power generation piling bar on wind power generation base 1, compares in prior art can reduce the service length of piling bar 4, reduces the consumptive material.

The sector annular lighting area 2 is divided into a plurality of groups of sectors, such as a first sector 11, a second sector 12, … … and a sixth sector 16 in fig. 3, the photovoltaic panels 5 in each sector are connected in series through photovoltaic cables to form a group string, and a plurality of groups are connected in series and parallel to a group string type inverter. That is, the photovoltaic cables of each sector are connected to the input terminals of the string inverters, respectively. The string inverter is a device capable of converting direct current output by a power transmission line of a photovoltaic panel 5 into alternating current in the prior art. In this embodiment, the structure of the photovoltaic panel 5 and the components of the photovoltaic panel 5 that convert light energy into electric energy both adopt the common structure of solar power generation in the prior art.

The mounting method of the present embodiment can be referred to embodiment 2.

Embodiment 2 installation method of photovoltaic power generation device based on wind power generation foundation

The embodiment is a method for installing a photovoltaic power generation device based on a wind power generation foundation in embodiment 1, and the method comprises the following steps:

the method comprises the following steps: dividing installation area

A sector annular lighting area on the circular table-shaped wind power generation base 1 is divided into a first sector area 11, a second sector area 13 and an … … (n) th sector area, and (n) groups of sector areas are formed, wherein n is more than or equal to 2. And also satisfies the following conditions:

when n is an even number, the first sector 11 and the second sector 12 are arranged symmetrically with respect to the axis of symmetry of the sectored service area, … …, the (n) th sector and the (n-1) th sector being arranged symmetrically with respect to the axis of symmetry of the sectored service area;

when n is an odd number, the first sector 11 and the second sector 12 are symmetrically disposed about the axis of symmetry of the sectored service area, … …, and the (n-2) th sector and the (n-1) th sector are symmetrically disposed about the axis of symmetry of the sectored service area.

Step two: sectional installation steel pile 4

The first step (first): the first sector 11 is provided with a steel pile 4

Firstly, digging plain soil 9 on a first sector area 11, namely digging from the ground to the surface of the wind power generation base 1, and drilling a mounting hole by using an expansion bolt drilling machine (electric hammer) along a marked position; and then fixing the steel piles 4 below the photovoltaic plate 5 in the mounting holes of the first sector 11, backfilling plain soil 9 on the first sector 11, and tamping the plain soil 9. Specifically, the method comprises the following steps:

the first step 1 is to dig out the first sector 11 arc A₁B₁Upper plain soil 9 along arc a in first sector 11₁B₁Marking the position of the pile point (i.e. the location of the hole), along arc A, according to the position of the marked pile point₁B₁A plurality of mounting holes are drilled, and the steel plates 6 welded at the bottom end of the steel pile 4 are correspondingly mounted on the arc A one by one through expansion bolts 7₁B₁In the mounting hole, the steel pile 4 is embedded in plain soil, namely in the arc A₁B₁And backfilling plain soil 9 on the steel pile 4, and tamping the plain soil 9.

In the first step 2, the first sector 11 arc A is dug₂B₂Upper plain soil 9 along arc a in first sector 11₂B₂Marking the position of the pile point (i.e. the location of the hole), along arc A, according to the position of the marked pile point₂B₂A plurality of mounting holes are drilled, and the steel plates 6 fixed at the bottom end of the steel pile 4 are correspondingly mounted on the arc A one by one through expansion bolts 4₂B₂In the mounting hole, the steel pile 4 is embedded in plain soil, namely in the arc A₂B₂And backfilling plain soil 9 on the steel pile 4, and tamping the plain soil 9.

……

In the first step, the arc A of the first sector 11 is dug_mB_mUpper plain soil 9 along arc a in first sector 11_mB_mMarking the position of the pile point (i.e. the location of the hole), along arc A, according to the position of the marked pile point_mB_mDrilling a plurality of mounting holes, mounting each steel plate 6 fixed at the bottom end of the steel pile 4 in the mounting hole of the first sector through the expansion bolt 4, and then embedding the steel pile 4 in plain soil, namely in the arc A_mB_mThe steel pile 4 is backfilled with plain soil 9And tamping plain soil 9.

Wherein m is more than or equal to 1 and arc A₁B₁Arc A₂B₂… … arc A_mB_mIs the fan-shaped vertex of the first sector 11, and arc A₁B₁Arc length, arc A₂B₂Arc length of … …, arc A_mB_mThe arc lengths of (a) and (b) are sequentially increased or sequentially decreased.

The second step: second sector 12 is provided with a steel pile 4

Digging the plain soil 9 on the second sector 12, namely digging the plain soil from the ground to the surface of the wind power generation base 1, and drilling a mounting hole by using an expansion bolt drilling machine (electric hammer) along the marked position; and then fixing the steel piles 4 below the photovoltaic plate 5 in the mounting holes of the second sector area 12, backfilling plain soil 9 on the second sector area 12, and tamping the plain soil 9. Specifically, the method comprises the following steps:

the second step (second 1) is to dig out the 12 arc C of the second sector₁D₁Upper plain soil 9 along arc C in second sector 12₁D₁Marking the position of the pile point (i.e. the position of the hole), along the arc C, according to the position of the pile point₁D₁A plurality of mounting holes are drilled, and the steel plates 6 fixed at the bottom end of the steel pile 4 are correspondingly mounted on the arc C one by one through expansion bolts 7₁D₁In the mounting hole, the steel pile 4 is embedded in plain soil 9, namely in the arc C₁D₁And backfilling plain soil 9 on the steel pile 4, and tamping the plain soil 9.

The second step (2) is to dig out the 12 arc C of the second sector₂D₂Upper plain soil 9 along arc C in second sector 12₂D₂Marking the position of the pile point (i.e. the position of the hole), along the arc C, according to the position of the pile point₂D₂A plurality of mounting holes are drilled, and the steel plates 6 fixed at the bottom end of the steel pile 4 are correspondingly mounted on the arc C one by one through expansion bolts 7₂D₂In the mounting hole, the steel pile is embedded into the plain soil 9, namely in the arc C₂D₂And backfilling plain soil 9 on the steel pile 4, and tamping the plain soil 9.

……

A second q step of digging a second sector 12 arcs C_qD_qUpper plain soil 9 along arc C in second sector 12_qD_qMarking the position of the pile point (i.e. the position of the hole), along the arc C, according to the position of the pile point_qD_qA plurality of mounting holes are drilled, and the steel plates 6 fixed at the bottom end of the steel pile 4 are correspondingly mounted on the arc C one by one through expansion bolts 7_qD_qIn the mounting hole, the steel pile 4 is embedded in plain soil 9, namely in the arc C_qD_qAnd backfilling plain soil 9 on the steel pile 4, and tamping the plain soil 9.

Wherein q is not less than 1 and arc C₁D₁Arc C₂D₂… … arc C_qD_qIs the circular sector vertex of the second sector 12, and arc C₁D₁Arc length, arc C₂D₂Arc length of … …, arc C_qD_qThe arc lengths of (a) and (b) are sequentially increased or sequentially decreased.

……

The (n) th step: the (n) th sector is provided with a steel pile 4

Digging plain soil 9 on the (n) th sector, namely digging from the ground to the surface of the wind power generation base 1, and drilling a mounting hole by using an expansion bolt drilling machine (electric hammer) along a marked position; and then fixing the steel piles 4 below the photovoltaic plate 5 in the mounting holes of the (n) th sector, backfilling plain soil 9 on the (n) th sector, and tamping the plain soil 9. Specifically, the method comprises the following steps:

in the (n 1) th step, the arc E of the (n) th sector is excavated₁F₁Upper plain soil 9 along arc E in sector (n)₁F₁Marking the position of the pile point (i.e. the location of the hole), along arc E, according to the position of the pile point₁F₁A plurality of mounting holes are drilled, and the steel plates 6 fixed at the bottom end of the steel pile 4 are correspondingly mounted on the arc E one by one through expansion bolts 7₁F₁In the mounting hole, the steel pile 4 is embedded in plain soil 9, namely in the arc E₁F₁And backfilling plain soil 9 on the steel pile 4, and tamping the plain soil 9.

In the (n 2) th step, the arc E of the (n) th sector is excavated₂F₂Upper plain soil 9 along arc E in sector (n)₂F₂Marking of pile point location (i.e. punching location)According to the position of the marked pile point, along arc E₂F₂A plurality of mounting holes are drilled on the steel pile, and the steel plates 6 fixed at the bottom end of the steel pile 4 are correspondingly mounted on the arc E one by one through expansion bolts 7₂F₂In the mounting hole, the steel pile 4 is embedded in plain soil 9, namely in the arc E₂F₂And backfilling plain soil 9 on the steel pile 4, and tamping the plain soil 9.

……

At the (np) th step, the (n) th sector arc E is dug_pF_pUpper plain soil 9 along arc E in sector (n)_pF_pMarking the position of the pile point (i.e. the location of the hole), along arc E, according to the position of the pile point_pF_pA plurality of mounting holes distributed in an arc shape are drilled on the steel pile, and the steel plates 6 fixed at the bottom end of the steel pile 4 are correspondingly mounted on the arc E one by one through expansion bolts 7_pF_pIn the mounting hole, the steel pile 4 is embedded in plain soil 9, namely in the arc E_pF_pAnd backfilling plain soil 9 on the steel pile 4, and tamping the plain soil 9.

Wherein p is more than or equal to 1 and arc E₁F₁Arc E₂F₂… … arc E_pF_pIs the sector vertex of the (n) th sector and arc E₁F₁Arc length, arc E of₂F₂Arc length of … …, arc E_pF_pThe arc lengths of (a) and (b) are sequentially increased or sequentially decreased.

And, arc A₁B₁Arc C₁D₁… … arc E₁F₁On the same circle, i.e. arc A₁B₁Arc C₁D₁… … arc E₁F₁The centers of the circles are concurrent and have the same radius; arc A₂B₂Arc C₂D₂… … arc E₂F₂Are positioned on the same circle; … …, respectively; arc A_mB_mArc C_qD_q… … arc E_pF_pLocated on the same circle.

Thereby completing the fixing of the steel pile 4. After the steel piles 4 are arranged on the wind power generation base 1, the photovoltaic plate 5 can be fixed on the steel piles 4 by adopting a common connection mode of the steel piles 4 and the photovoltaic plate 5.

Embodiment 3 installation method of photovoltaic power generation device based on wind power generation foundation

In this embodiment, n =6 and m = q = p =3 are taken in addition to embodiment 2. Reference may be made to the illustration of fig. 3, specifically:

the method comprises the following steps: dividing installation area

The circular lighting area 2 on the circular truncated cone-shaped wind power generation base 1 is divided into a first sector 11, a second sector 12, a third sector 13, a fourth sector 14, a fifth sector 15 and a sixth sector 16. And the first sector 11 and the second sector 12 are arranged symmetrically with respect to the axis of symmetry JK of the sectored service area 3 (as shown in figure 3), the third sector 13 and the fourth sector 14 are arranged symmetrically with respect to the axis of symmetry JK of the sectored service area 3, and the fifth sector 15 and the sixth sector 16 are arranged symmetrically with respect to the axis of symmetry JK of the sectored service area 3.

And, arc A₁B₁X₁E₁F₁D₁C₁Arc A₂B₂X₂E₂F₂D₂C₂Arc A₃B₃X₃E₃F₃D₃C₃The center of the circle is the center of the sector annular lighting area 2, and the arc A₁B₁X₁E₁F₁D₁C₁Arc length < arc A₂B₂X₂E₂F₂D₂C₂Arc length < arc A₃B₃X₃E₃F₃D₃C₃Arc length of (2).

Step two: sectional installation steel pile 4

The first step (first): the first sector 11 is provided with a steel pile 4

Firstly, digging plain soil 9 on a first sector area 11, namely digging from the ground to the surface of the wind power generation base 1, and drilling a mounting hole by using an expansion bolt drilling machine (electric hammer) along a marked position; and then fixing the steel piles 4 below the photovoltaic plate 5 in the mounting holes of the first sector 11, backfilling plain soil 9 on the first sector 11, and tamping the plain soil 9. Specifically, the method comprises the following steps:

the first step 1 is to dig out the first sector 11 arc A₁B₁Upper plain soil 9 along arc a in first sector 11₁B₁Marking the position of the pile point (i.e. the location of the hole), along arc A, according to the position of the marked pile point₁B₁A plurality of mounting holes are drilled, and the steel plates 6 welded at the bottom end of the steel pile 4 are correspondingly mounted on the arc A one by one through expansion bolts 7₁B₁In the mounting hole, the steel pile 4 is embedded in plain soil 9, namely in the arc A₁B₁And backfilling plain soil 9 on the steel pile 4, and tamping the plain soil 9.

In the first step 2, the first sector 11 arc A is dug₂B₂Upper plain soil 9 along arc a in first sector 11₂B₂Marking the position of the pile point (i.e. the location of the hole), along arc A, according to the position of the marked pile point₂B₂A plurality of mounting holes are drilled, and the steel plates 6 fixed at the bottom end of the steel pile 4 are correspondingly mounted on the arc A one by one through expansion bolts 7₂B₂In the mounting hole, the steel pile 4 is embedded in plain soil 9, namely in the arc A₂B₂And backfilling plain soil 9 on the steel pile 4, and tamping the plain soil 9.

In the first step (3), the first sector 11 arc A is dug₃B₃Upper plain soil 9 along arc a in first sector 11₃B₃Marking the position of the pile point (i.e. the location of the hole), along arc A, according to the position of the marked pile point₃B₃Drilling a plurality of mounting holes, mounting each steel plate 6 fixed at the bottom end of the steel pile 4 in the mounting hole of the first sector through an expansion bolt 7, and embedding the steel pile 4 in plain soil 9, namely in the arc A₃B₃And backfilling plain soil 9 on the steel pile 4, and tamping the plain soil 9.

The second step: second sector 12 is provided with a steel pile 4

Digging the plain soil 9 on the second sector 12, namely digging the plain soil from the ground to the surface of the wind power generation base 1, and drilling a mounting hole by using an expansion bolt drilling machine (electric hammer) along the marked position; and then fixing the steel piles 4 below the photovoltaic plate 5 in the mounting holes of the second sector area 12, backfilling plain soil 9 on the second sector area 12, and tamping the plain soil 9. Specifically, the method comprises the following steps:

the second step (second 1) is to dig out the 12 arc C of the second sector₁D₁Upper plain soil 9 along arc C in second sector 12₁D₁Marking the position of the pile point (i.e. the position of the hole), along the arc C, according to the position of the pile point₁D₁A plurality of mounting holes are drilled, and the steel plates 6 fixed at the bottom end of the steel pile 4 are correspondingly mounted on the arc C one by one through expansion bolts 7₁D₁In the mounting hole, the steel pile 4 is embedded in plain soil 9, namely in the arc C₁D₁And backfilling plain soil 9 on the steel pile 4, and tamping the plain soil 9.

The second step (2) is to dig out the 12 arc C of the second sector₂D₂Upper plain soil 9 along arc C in second sector 12₂D₂Marking the position of the pile point (i.e. the position of the hole), along the arc C, according to the position of the pile point₂D₂A plurality of mounting holes are drilled, and the steel plates 6 fixed at the bottom end of the steel pile 4 are correspondingly mounted on the arc C one by one through expansion bolts 7₂D₂In the mounting hole, the steel pile 4 is embedded in plain soil 9, namely in the arc C₂D₂And backfilling plain soil 9 on the steel pile 4, and tamping the plain soil 9.

The second step (second 3) is to dig out the 12 arc C of the second sector₃D₃Upper plain soil 9 along arc C in second sector 12₃D₃Marking the position of the pile point (i.e. the position of the hole), along the arc C, according to the position of the pile point₃D₃A plurality of mounting holes are drilled, and the steel plates 6 fixed at the bottom end of the steel pile 4 are correspondingly mounted on the arc C one by one through expansion bolts 7₃D₃In the mounting hole, the steel pile 4 is embedded in plain soil 9, namely in the arc C₃D₃And backfilling plain soil 9 on the steel pile 4, and tamping the plain soil 9.

The third step: the third sector 13 is provided with a steel pile 4

Digging plain soil 9 on the third sector area 13, namely digging from the ground to the surface of the wind power generation base 1, and drilling a mounting hole by using an expansion bolt drilling machine (electric hammer) along a marked position; and then fixing the steel piles 4 below the photovoltaic plate 5 in the mounting holes of the third sector area 13, backfilling plain soil 9 on the third sector area 13, and tamping the plain soil 9. Specifically, the method comprises the following steps:

the third step 1, digging a third sector 13 arc B₁X₁Upper plain soil 9 along arc B in third sector 13₁X₁Marking the position of the pile point (i.e. the location of the hole), along arc B, according to the position of the pile point₁X₁A plurality of mounting holes are drilled, and the steel plates 6 fixed at the bottom end of the steel pile 4 are correspondingly mounted on the arc B one by one through expansion bolts 7₁X₁In the mounting hole, the steel pile 4 is embedded in plain soil 9, namely in the arc B₁X₁And backfilling plain soil 9 on the steel pile 4, and tamping the plain soil 9.

Step three 2, digging a third sector 13 arc B₂X₂Upper plain soil 9 along arc B in third sector 13₂X₂Marking the position of the pile point (i.e. the location of the hole), along arc B, according to the position of the pile point₂X₂A plurality of mounting holes are drilled, and the steel plates 6 fixed at the bottom end of the steel pile 4 are correspondingly mounted on the arc B one by one through expansion bolts 7₂X₂In the mounting hole, the steel pile 4 is embedded in plain soil 9, namely in the arc B₂X₂And backfilling plain soil 9 on the steel pile 4, and tamping the plain soil 9.

Step three 3, digging a third sector 13 arc B₃X ₃Upper plain soil 9 along arc B in third sector 13₃X ₃Marking the position of the pile point (i.e. the location of the hole), along arc B, according to the position of the pile point₃X ₃A plurality of mounting holes are drilled, and the steel plates 6 fixed at the bottom end of the steel pile 4 are correspondingly mounted on the arc B one by one through expansion bolts 7₃X ₃In the mounting hole, the steel pile 4 is embedded in plain soil 9, namely in the arc B₃X ₃And backfilling plain soil 9 on the steel pile 4, and tamping the plain soil 9.

The fourth step: fourth sector 14 is provided with a steel pile 4

Digging plain soil 9 on the fourth sector 14, namely digging from the ground to the surface of the wind power generation base 1, and drilling a mounting hole by using an expansion bolt drilling machine (electric hammer) along a marked position; and then fixing the steel piles 4 below the photovoltaic plate 5 in the mounting holes of the fourth sector 14, backfilling plain soil 9 on the fourth sector 14, and tamping the plain soil 9. Specifically, the method comprises the following steps:

step four 1, digging a fourth sector 14 arc D₁F₁Upper plain soil 9 along arc D in fourth sector 14₁F₁Marking pile point positions (i.e. punching positions), according to which, along arc D₁F₁A plurality of mounting holes are drilled, and the steel plates 6 fixed at the bottom end of the steel pile 4 are correspondingly mounted on the arc D one by one through expansion bolts 7₁F₁In the mounting hole, the steel pile 4 is embedded in plain soil 9, namely in arc D₁F₁And backfilling plain soil 9 on the steel pile 4, and tamping the plain soil 9.

Fourthly, a fourth sector 14 arc D is dug₂F₂Upper plain soil 9 along arc D in fourth sector 14₂F₂Marking pile point positions (i.e. punching positions), according to which, along arc D₂F₂A plurality of mounting holes are drilled, and the steel plates 6 fixed at the bottom end of the steel pile 4 are correspondingly mounted on the arc D one by one through expansion bolts 7₂F₂In the mounting hole, the steel pile 4 is embedded in plain soil 9, namely in arc D₂F₂And backfilling plain soil 9 on the steel pile 4, and tamping the plain soil 9.

Fourthly, a fourth sector 14 arcs D are dug₃F ₃Upper plain soil 9 along arc D in fourth sector 14₃F ₃Marking pile point positions (i.e. punching positions), according to which, along arc D₃F ₃A plurality of mounting holes are drilled, and the steel plates 6 fixed at the bottom end of the steel pile 4 are correspondingly mounted on the arc D one by one through expansion bolts 7₃F ₃In the mounting hole, the steel pile 4 is embedded in plain soil 9, namely in arc D₃F₃And backfilling plain soil 9 on the steel pile 4, and tamping the plain soil 9.

The fifth step: fifth sector 15 is provided with a steel pile 4

Digging the plain soil 9 on the fifth sector 15, namely digging the plain soil from the ground to the surface of the wind power generation base 1, and drilling a mounting hole by using an expansion bolt drilling machine (electric hammer) along the marked position; and then fixing the steel piles 4 below the photovoltaic plate 5 in the mounting holes of the fifth sector 15, backfilling plain soil 9 on the fifth sector 15, and tamping the plain soil 9. Specifically, the method comprises the following steps:

the fifth step 1, digging a fifth sector 15 arc X₁E₁Upper plain soil 9 along arc X in fifth sector 15₁E₁Marking the position of the pile point (i.e. the position of the hole), along the arc X, according to the position of the pile point₁E₁A plurality of mounting holes are drilled, and the steel plates 6 fixed at the bottom end of the steel pile 4 are correspondingly mounted on the arc X one by one through expansion bolts 7₁E₁In the mounting hole, the steel pile 4 is embedded in plain soil 9, namely in the arc X₁E₁And backfilling plain soil 9 on the steel pile 4, and tamping the plain soil 9.

Step (five 2), digging a fifth sector 15 arc X₂E₂Upper plain soil 9 along arc X in fifth sector 15₂E₂Marking the position of the pile point (i.e. the position of the hole), along the arc X, according to the position of the pile point₂E₂A plurality of mounting holes are drilled, and the steel plates 6 fixed at the bottom end of the steel pile 4 are correspondingly mounted on the arc X one by one through expansion bolts 7₂E₂In the mounting hole, the steel pile 4 is embedded in plain soil 9, namely in the arc X₂E₂And backfilling plain soil 9 on the steel pile 4, and tamping the plain soil 9.

Step (five 3), digging a fifth sector 15 arc X₃E₃Upper plain soil 9 along arc X in fifth sector 15₃E₃Marking the position of the pile point (i.e. the position of the hole), along the arc X, according to the position of the pile point₃E₃A plurality of mounting holes are drilled, and the steel plates 6 fixed at the bottom end of the steel pile 4 are correspondingly mounted on the arc X one by one through expansion bolts 7₃E₃In the mounting hole, the steel pile 4 is embedded in plain soil 9, namely in the arc X₃E₃And backfilling plain soil 9 on the steel pile 4, and tamping the plain soil 9.

The sixth step: sixth sector 16 is provided with a steel pile 4

Digging plain soil 9 on the sixth sector 16, namely digging from the ground to the surface of the wind power generation base 1, and drilling a mounting hole by using an expansion bolt drilling machine (electric hammer) along a marked position; and then fixing the steel piles 4 below the photovoltaic plate 5 in the mounting holes of the sixth sector 16, backfilling plain soil 9 on the sixth sector 16, and tamping the plain soil 9. Specifically, the method comprises the following steps:

the sixth step 1, digging a sixth sector 16 arcs F₁E₁Upper plain soil 9 along arc F in sixth sector 16₁E₁Marking pile point positions (i.e. punching positions), according to which, along arc F₂E₂A plurality of mounting holes are drilled, and the steel plates 6 fixed at the bottom end of the steel pile 4 are correspondingly mounted on the arc F one by one through expansion bolts 7₂E₂In the mounting hole, the steel pile 4 is embedded in plain soil 9, namely in the arc F₃E₃And backfilling plain soil 9 on the steel pile 4, and tamping the plain soil 9.

The sixth step 2, digging a sixth sector 16 arcs F₂E₂Upper plain soil 9 along arc F in sixth sector 16₂E₂Marking pile point positions (i.e. punching positions), according to which, along arc F₂E₂A plurality of mounting holes are drilled, and the steel plates 6 fixed at the bottom end of the steel pile 4 are correspondingly mounted on the arc F one by one through expansion bolts 7₂E₂In the mounting hole, the steel pile 4 is embedded in plain soil 9, namely in the arc F₂E₂And backfilling plain soil 9 on the steel pile 4, and tamping the plain soil 9.

The sixth step (3) is to dig a sixth sector of 16 arcs F₃E₃Upper plain soil 9 along arc F in sixth sector 16₃E₃Marking pile point positions (i.e. punching positions), according to which, along arc F₃E₃A plurality of mounting holes are drilled, and the steel plates 6 fixed at the bottom end of the steel pile 4 are correspondingly mounted on the arc F one by one through expansion bolts 7₃E₃In the mounting hole, the steel pile 4 is embedded in plain soil 9, namely in the arc F₃E₃And backfilling plain soil 9 on the steel pile 4, and tamping the plain soil 9.

Thereby completing the fixing of the steel pile 4. After the steel piles 4 are arranged on the wind power generation base 1, the photovoltaic plate 5 can be fixed on the steel piles 4 by adopting a common connection mode of the steel piles 4 and the photovoltaic plate 5.

The "plurality" or "sets" described in all the above embodiments means at least 2 or at least 2 sets.

Although the present invention has been described in detail with reference to the above embodiments, it will be apparent to those skilled in the art that modifications may be made to the embodiments described above, or equivalents may be substituted for elements thereof. Any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (10)

1. The utility model provides a photovoltaic power generation device based on wind power generation basis which characterized in that: the wind power generation device comprises a circular truncated cone-shaped wind power generation base arranged underground, wherein an annular inclined plane of the circular truncated cone-shaped wind power generation base consists of a sector annular lighting area and a sector maintenance area; the lighting area is fixedly connected with a plurality of steel piles, and the upper part of each steel pile is fixedly connected with a photovoltaic plate arranged above the ground; the service area has a sector radius in the true north direction.

2. The wind power foundation based photovoltaic power generation device of claim 1, wherein: and the bottom end of each steel pile is fixedly connected with a steel plate parallel to the inclined plane of the wind power generation base, and the steel plate is fixedly connected with the wind power generation base through expansion bolts.

3. The wind power foundation based photovoltaic power generation device of claim 1, wherein: the symmetry axis of the maintenance area is positioned in the north direction, and the fan-shaped central angle of the maintenance area is 90-105 degrees.

4. A wind power foundation based photovoltaic power generation device according to any one of claims 1-3, wherein: the lighting area is provided with a plurality of arcs which are concentric with the sector ring, and each arc is fixed with steel piles which are distributed in an arc shape.

5. The wind power foundation based photovoltaic power generation device of claim 4, wherein: the sector annular lighting area is divided into a plurality of groups of sector areas, photovoltaic panels in each sector area are connected in series through photovoltaic cables to form a group string, and a plurality of groups of strings are connected in parallel to a group string type inverter.

6. A method of installing a wind-based photovoltaic generator according to any of claims 1 to 5, wherein: the method comprises the following steps:

the method comprises the following steps: dividing installation area

Dividing a circular lighting area on the circular truncated cone-shaped wind power generation base into a first sector area, a second sector area and an … … (n) th sector area, wherein n is more than or equal to 2;

step two: sectional installation steel pile

The first step (first): first sector installation steel pile

Firstly, digging plain soil on a first sector area, and drilling a mounting hole in the first sector area; then fixing the steel piles below the photovoltaic plate in the mounting holes of the first sector area, and covering plain soil on the first sector area;

the second step: second sector installation steel pile

Firstly digging plain soil on the second sector area, and drilling mounting holes in the second sector area; then fixing the steel piles below the photovoltaic plate in the mounting holes of the second sector area, and covering plain soil on the second sector area;

……

the (n) th step: steel pile for installing sector (n)

Firstly, digging plain soil on the (n) th sector area, and drilling a mounting hole on the (n) th sector area; and then fixing the steel piles below the photovoltaic plate in the mounting holes of the (n) th sector, and covering plain soil on the (n) th sector.

7. The method of installing a wind power based photovoltaic power plant according to claim 6, wherein:

when n is an even number: the first sector and the second sector are symmetrically arranged about the symmetry axis of the sectored service area, … …, the (n) th sector and the (n-1) th sector are symmetrically arranged about the symmetry axis of the sectored service area;

when n is an odd number: the first sector and the second sector are symmetrically disposed about an axis of symmetry of the sectored service area, … …, and the (n-2) th sector and the (n-1) th sector are symmetrically disposed about the axis of symmetry of the sectored service area.

8. Method for mounting a photovoltaic installation based on a wind power generation foundation according to claim 6 or 7, characterized in that:

step two: sectional installation steel pile

The first step (first): first sector installation steel pile

The first step 1 is to dig out a first sector arc A₁B₁Along arc A in the first sector₁B₁A plurality of mounting holes are drilled, and the steel plate at the bottom end of the steel pile is mounted on the arc A through expansion bolts₁B₁In the mounting hole, the steel pile is embedded into plain soil;

the first step 2, digging out the arc A of the first sector area₂B₂Along arc A in the first sector₂B₂Drilling a plurality of mounting holes, and mounting the steel plate at the bottom end of the steel pile on the arc A through expansion bolts₂B₂In the mounting hole, the steel pile is embedded into plain soil;

……

in the first m step, digging out the arc A of the first sector_mB_mAlong arc A in the first sector_mB_mA plurality of mounting holes are drilled, and the steel plate at the bottom end of the steel pile is mounted on the arc A through expansion bolts_mB_mIn the mounting hole, the steel pile is embedded into plain soil;

wherein m is more than or equal to 1 and arc A₁B₁Arc A₂B₂… … arc A_mB_mIs the fan-shaped peak of the first sector and arc A₁B₁Arc length, arc A₂B₂Arc length of … …, arc A_mB_mThe arc length of the arc is sequentially increased or decreased;

the second step: second sector installation steel pile

The second step (1) is to dig out a second sector arc C₁D₁Upper plain soil along arc C in the second sector₁D₁A plurality of mounting holes are drilled, and the steel plate at the bottom end of the steel pile is mounted on the arc C through expansion bolts₁D₁In the mounting hole, the steel pile is embedded into plain soil;

the second step (2) is to dig out a second sector arc C₂D₂Upper plain soil along arc C in the second sector₂D₂A plurality of mounting holes are drilled, and the steel plate at the bottom end of the steel pile is mounted on the arc C through expansion bolts₂D₂In the mounting hole, the steel pile is embedded into plain soil;

……

a second q step of digging a second sector arc C_qD_qUpper plain soil along arc C in the second sector_qD_qA plurality of mounting holes are drilled, and the steel plate at the bottom end of the steel pile is mounted on the arc C through expansion bolts_qD_qThen embedding the steel piles into plain soil;

wherein q is not less than 1 and arc C₁D₁Arc C₂D₂… … arc C_qD_qIs the circular sector vertex of the second sector and is arc C₁D₁Arc length, arc C₂D₂Arc length of … …, arc C_qD_qThe arc length of the arc is sequentially increased or decreased;

……

the (n) th step: steel pile for installing sector (n)

In the (n 1) th step, the arc E of the (n) th sector is excavated₁F₁Upper plain soil along arc E in the (n) th sector₁F₁Drilling a plurality of mounting holes, and mounting the steel plate at the bottom end of the steel pile on the arc E through expansion bolts₁F₁In the mounting hole, the steel pile is embedded into plain soil;

in the (n 2) th step, the arc E of the (n) th sector is excavated₂F₂Upper plain soil along arc E in the (n) th sector₂F₂Drilling a plurality of mounting holes, and mounting the steel plate at the bottom end of the steel pile on the arc E through expansion bolts₂F₂In the mounting hole, the steel pile is embedded into plain soil;

……

at the (np) th step, the (n) th sector arc E is dug_pF_pUpper plain soil along arc E in the (n) th sector_pF_pDrilling a plurality of mounting holes, and mounting the steel plate at the bottom end of the steel pile on the arc E through expansion bolts_pF_pIn the mounting hole, the steel pile is embedded into plain soil;

wherein p is more than or equal to 1 and arc E₁F₁Arc E₂F₂… … arc E_pF_pIs the sector vertex of the (n) th sector and arc E₁F₁Arc length, arc E of₂F₂Arc length of … …, arc E_pF_pThe arc lengths of (a) and (b) are sequentially increased or sequentially decreased.

9. The method of installing a wind-based photovoltaic power generation unit as defined in claim 8, wherein: arc A₁B₁Arc C₁D₁… … arc E₁F₁Are positioned on the same circle; arc A₂B₂Arc C₂D₂… … arc E₂F₂Are positioned on the same circle; … …, respectively; arc A_mB_mArc C_qD_q… … arc E_pF_pLocated on the same circle.

10. The method of installing a wind-based photovoltaic power generation installation according to claim 9, wherein: in the second step, before the mounting holes are punched along different arcs, marking the punching positions along the arcs by scribing lines, and punching a plurality of mounting holes according to the marked punching positions.