CN218006141U - Wind resistance step type photovoltaic support - Google Patents

Abstract

The utility model provides a wind resistance step type photovoltaic bracket.A steel strand passes through a plurality of step type connecting components, a cross combined wire clamp, a first transverse steel cable clamp and a second transverse steel cable clamp on a bearing steel cable component, and the two ends of the steel strand are respectively fixed on a first step beam and a third step beam; a plurality of bearing steel cable assemblies are arranged between the first step beam and the third step beam, and a plurality of step-shaped connecting assemblies are arranged between the bearing steel cable assemblies and the first step beam or the third step beam; be provided with a plurality of notch cuttype coupling assembling between first step roof beam and the third step roof beam, be provided with a plurality of notch cuttype coupling assembling between bearing cable wire subassembly and the bearing cable wire subassembly, notch cuttype coupling assembling be at least one, its is rational in infrastructure, when meeting strong wind, produce resonance between photovoltaic support and the photovoltaic support, strengthened the anti-wind ability, reduced windage intensity, make the photovoltaic support after establishing ties firm and not fragile.

Description

Wind resistance step type photovoltaic support

Technical Field

The utility model relates to a photovoltaic support equipment field especially relates to a cascaded photovoltaic support of resistant windage.

Background

The photovoltaic support is designed for placing, installing and fixing a solar panel in a solar photovoltaic power generation system, and is structurally characterized in that the support is connected through a steel cable, and then the solar panel is fixed on the steel cable and arranged in a large scale to form a square matrix.

Application number 202220228248.3 discloses a cable wire photovoltaic support, and it is the stable cable wire structure of pocket in one kind, goes up the bracing piece and stabilizes the pull rod between the many battle arrays, and the interval has great space between two rows of panels in front and back, and such project organization plays the effect of leaking down the wind, can effectual reduction wind pressure. However, the structure of the oblique beam is in a straight line state, the installation structure of the front row of solar panels and the rear row of solar panels is inevitably on an inclination angle line due to the oblique beam structure, and due to the design structure, when the wind speed is high, most of the wind blowing through the first row of solar panels is received by the rear row of solar panels, so that the wind pressure of the rear row of solar panels is too high, and the potential safety hazard of the whole support is increased. And the connecting stabilizing pull rod between the front square matrix and the rear square matrix adopts a giant steel pipe, and the middle pile adopts a combined structure of I-shaped steel and a support rod, so that the manufacturing cost is increased.

Disclosure of Invention

In order to solve the above problem, the utility model provides a cascaded photovoltaic support of resistant windage, its is rational in infrastructure, has solved above-mentioned problem.

The technical scheme of the utility model is that: the wind resistance resistant stepped photovoltaic support comprises a first stepped beam, a third stepped beam, a bearing steel cable assembly, stepped connecting assemblies, a longitudinal connecting cable, a lower bearing steel cable and an upper bearing steel cable, wherein a steel strand penetrates through the stepped connecting assemblies, a cross combined cable clamp on the bearing steel cable assembly, a transverse steel cable clamp I and a transverse steel cable clamp II, and two ends of the steel strand are fixed on the first stepped beam and the third stepped beam respectively; a plurality of bearing steel cable assemblies are arranged between the first step beam and the third step beam, and a plurality of step-shaped connecting assemblies are arranged between the bearing steel cable assemblies and the first step beam or the third step beam; a plurality of step-shaped connecting assemblies are arranged between the first step beam and the third step beam, a plurality of step-shaped connecting assemblies are arranged between the bearing steel cable assembly and the bearing steel cable assembly, and at least one of the bearing steel cable assembly and the step-shaped connecting assemblies is arranged;

the longitudinal connecting cable penetrates through a plurality of pipelines formed by connecting the arc-shaped end part III with the arc-shaped end part III, two ends of the longitudinal connecting cable are respectively fixed on anchor fixing parts at the upper ends of the first upright post and the second upright post through anchors, or the longitudinal connecting cable penetrates through the anchor fixing parts at the upper ends of the first upright post and the second upright post through anchors and is fixed on the other reinforcing upright post I and the reinforcing upright post II through rigging tools, a first inclined pull-up steel strand penetrates through the pipelines formed by connecting the arc-shaped end parts I and the arc-shaped end parts II and is connected with arc-shaped wire clamps on the third step beam and the first step beam, and one ends of the front stay bar, the middle connecting post and the rear stay bar are all fixed between the upper clamping piece I and the upper clamping piece II through bolts;

the bearing steel cable piles are a plurality of, and the bearing steel cable piles further comprise extension bearing steel cable tension piles and lower bearing steel cable anchoring piles, wherein lower bearing steel cable hoops are arranged on the bearing steel cable piles, lower bearing steel cable clamps are arranged on the lower bearing steel cable hoops, a post top cable clamp fixing frame is arranged at the tops of the bearing steel cable piles, and bearing steel cable clamps and arc-shaped cable clamps are arranged on the post top cable clamp fixing frame;

the bearing steel cable assembly comprises a first steel cable connecting rod, a second steel cable connecting rod, an upper bearing steel cable clamp, a first transverse steel cable clamp, a second transverse steel cable clamp, a lower bearing steel cable, an upper bearing steel cable and a cross-shaped combined wire clamp, wherein the upper end of each of the first steel cable connecting rod and the second steel cable connecting rod is provided with the upper bearing steel cable clamp, the lower end of each of the first steel cable connecting rod and the second steel cable connecting rod is provided with the lower bearing steel cable clamp, the outer side of the middle lower end of the second steel cable connecting rod is provided with the first transverse steel cable clamp, the inner side of the middle upper end of the first steel cable connecting rod is provided with the second transverse steel cable clamp, and the upper bearing steel cable clamp and the lower bearing steel cable clamp are respectively positioned on two sides of the first steel cable connecting rod and the second steel cable connecting rod; the lower bearing steel cable penetrates through lower bearing steel cable clamps on the first steel cable connecting rods, the lower bearing steel cable clamp is arranged on the lower bearing steel cable hoop, the lower bearing steel cable clamp is arranged on the second steel cable connecting rod, two ends of the lower bearing steel cable are respectively fixed on an anchorage device fixing piece at the upper end of the extension bearing steel cable tension pile through anchorage devices, or the lower bearing steel cable clamp penetrates through the anchorage device fixing piece at the upper end of the extension bearing steel cable tension pile and is fixed on the lower bearing steel cable anchoring pile through the anchorage devices, and the plurality of lower bearing steel cable clamps, the lower bearing steel cable hoop and the lower bearing steel cable clamp are at least one; the steel strand three passes through the transverse steel cable clamp I, and the steel strand two passes through the transverse steel cable clamp II; the upper bearing steel cable penetrates through upper bearing steel cable clamps on the first steel cable connecting rods, the bearing steel cable clamps and the upper bearing steel cable clamps on the second steel cable connecting rods, two ends of the upper bearing steel cable clamps are fixed on anchorage device fixing parts at the upper ends of the three upright posts respectively through anchorage devices, or the upper bearing steel cable clamps and the upper bearing steel cable clamps are fixed on the third reinforced upright posts through riggings through the anchorage devices, the number of the upper bearing steel cable clamps, the bearing steel cable clamps and the upper bearing steel cable clamps is at least one, the first steel strand is connected with the upper bearing steel cable through the cross-shaped combined wire clamp, and the fourth steel strand is connected with the lower bearing steel cable through the cross-shaped combined wire clamp;

the first ladder beam and the third ladder beam are connected through steel strands, the steel strands comprise a first steel strand, a second steel strand, a third steel strand and a fourth steel strand, and the first steel strand, the second steel strand, the third steel strand and the fourth steel strand respectively penetrate through steel strand pressing codes, bearing steel cable assemblies and two ends of bearing steel cable clamps at the upper ends of the plurality of ladder-shaped connecting assemblies and are respectively connected with a first anchorage device on the first ladder beam and a second anchorage device on the third ladder beam; the solar panel comprises a first solar panel and a second solar panel, the first solar panel is arranged on the first steel strand and the second steel strand, the second solar panel is arranged on the third steel strand and the fourth steel strand, and an air release groove is formed between the first solar panel and the second solar panel.

Optionally, the stepped connection assembly comprises a first inclined upward-pulling steel strand, a front stay bar, a middle connecting column, a rear stay bar, a first-level stepped beam, a second-level stepped beam, a first connection steel cable, a second connection steel cable and a longitudinal connection cable, wherein the front stay bar, the middle connecting column and one end of the rear stay bar are fixed on the connection assembly, one end of the first-level stepped beam is installed at the top of the front stay bar, the other end of the first-level stepped beam is installed at the side part of the middle connecting column, one end of the second-level stepped beam is installed at the top of the middle connecting column, the other end of the second-level stepped beam is installed at the top of the rear stay bar through bolts, steel strand pressing codes are arranged at the upper end of the first-level stepped beam and the upper end of the second-level stepped beam, the first-level stepped beam is provided with the first U-shaped connection piece through an anchorage device and connected with the first connection steel cable, one end of the first U-shaped connection piece is installed on the longitudinal connection cable through a cable transfer clamp, a second-level stepped beam through an anchorage device and connected with the first U-shaped connection steel cable.

Optionally, the first step beam comprises a first upright post I, a first upright post II, a first upright post III, a first hoop I, a first hoop III, a first support rod I, a first support rod II, a first support rod III, a first support rod IV, a first primary step beam upright post, a first middle connecting upright post, a first secondary step beam upright post, a first primary step beam and a first secondary step beam, wherein the upper end of the first upright post is provided with the first primary step beam upright post, the upper end of the first upright post II is provided with the first middle connecting upright post, the upper end of the first upright post III is provided with the first secondary step beam upright post, the first upright post I and the first upright post III are respectively provided with the first hoop I and the first hoop III, the two ends of the first hoop I are provided with the first support rod I and the first support rod II, the other ends of the first support rod I and the first support rod II are connected with the first primary step beam respectively to form a triangular supporting portion, the two ends of the first hoop III are provided with a first support rod III and a first support rod IV, the other ends of the first support rod III and the first support rod IV are connected with the first secondary step beam respectively to form a triangular supporting portion, the upper end of the first primary step beam upright post is provided with the first primary step beam, the upper end of the first secondary step beam upright post is provided with the first secondary step beam, one end of the first primary step beam is connected with the middle portion of the first middle portion connecting upright post, the first secondary step beam is connected with the top portion of the first middle portion connecting upright post, the first primary step beam and the first secondary step beam are both provided with anchorage devices, and the first middle portion connecting upright post is provided with an arc-shaped wire clamp.

Optionally, the third step beam includes a first third column, a second third column, a first third hoop, a first third strut, a second third strut, a fourth third strut, a third first step Liang Lizhu, a third middle connecting column, a third second step Liang Lizhu, a third first step beam, and a third second step beam, the upper end of the first third column is provided with a third first step Liang Lizhu, the upper end of the second third column is provided with a third middle connecting column, the upper end of the third column is provided with a third second step Liang Lizhu, the first third column, the second third column, and the third column are respectively provided with a first third hoop and a third hoop, the two ends of the first third hoop are provided with a first third support rod and a second third support rod, the other ends of the first third support rod and the second third support rod are respectively connected with a first-level step beam to form a triangular supporting part, the two ends of the third hoop are provided with a third support rod and a fourth third support rod, the other ends of the third support rod and the fourth third support rod are respectively connected with a second-level step beam to form a triangular supporting part, the upper end of the third first-level step Liang Lizhu is provided with a first-level step beam, the upper end of the third second-level step Liang Lizhu is provided with a second-level step beam, one end of the third first-level step beam is connected with the middle part of the third connecting upright column, and the third second-level step beam is connected with the top part of the third connecting upright column.

Optionally, the connecting assembly comprises a first upper clamping piece, a second upper clamping piece, a first middle clamping piece, a second middle clamping piece, a first arc-shaped end part, a second arc-shaped end part, a first lower clamping piece, a second lower clamping piece and a third arc-shaped end part, wherein the first upper clamping piece and the second upper clamping piece are installed at the upper end of the first middle clamping piece, the first upper clamping piece and the second upper clamping piece are welded into an integral structure with the first middle clamping piece, corresponding holes are formed in the first upper clamping piece and the second upper clamping piece, the first arc-shaped end part is arranged on the first middle clamping piece, the second lower end of the second middle clamping piece is provided with the first lower clamping piece and the second lower clamping piece, the second middle clamping piece and the first lower clamping piece are welded into an integral structure, the second arc-shaped end part is arranged on the second middle clamping piece, symmetrical third arc-shaped end parts are arranged on the first lower clamping piece and the second middle clamping piece, the first middle clamping piece and the second middle clamping piece are connected through bolts, the first arc-shaped end part is connected into a pipeline, and the third arc-shaped end part is connected into a pipeline.

Optionally, the first steel strand penetrates through the steel strand pressing bars on the second-stage stepped beams and the cross-shaped combined wire clamp on the upper bearing steel cable, and two ends of the first steel strand are connected with the second anchorage on the third stepped beam and the first anchorage on the first stepped beam respectively.

Optionally, the second steel strand penetrates through the second steel strand pressing blocks on the second step beams and the first transverse steel cable clamps on the second steel cable connecting rods, and two ends of the second steel strand are connected with the second anchorage on the third step beam and the first anchorage on the first step beam respectively.

Optionally, the steel strand three passes through a steel strand pressing code on the plurality of first-stage stepped beams and a transverse steel cable clamp two on the steel cable connecting rod one respectively, and two ends of the steel strand three are connected with an anchorage device two on the third stepped beam and an anchorage device one on the first stepped beam respectively.

Optionally, the fourth steel strand penetrates through the steel strand pressing codes on the plurality of first-stage stepped beams and the cross combined wire clamp on the lower bearing steel cable respectively, and two ends of the fourth steel strand are connected with the second anchorage on the third stepped beam and the first anchorage on the first stepped beam respectively.

Optionally, the first primary stepped beam, the third primary stepped beam and the primary stepped beam are parallel to each other;

the first secondary stepped beam, the third secondary stepped beam and the second stepped beam are parallel to each other.

Optionally, the heights of the first primary stepped beam, the third primary stepped beam and the first stepped beam are all lower than the heights of the first secondary stepped beam, the third secondary stepped beam and the second stepped beam.

Optionally, the solar panels on the first steel strand and the second steel strand, the solar panels on the third steel strand and the fourth steel strand are in a stepped structure, and the air discharge grooves formed by the first solar panels and the second solar panels are spaced from each other by 15-90cm.

Compared with the prior art, the beneficial effects of the utility model are that: it is rational in infrastructure, the notch cuttype coupling assembling on the first row of photovoltaic support is connected with the notch cuttype coupling assembling on the second row of photovoltaic support, the notch cuttype coupling assembling on the second row of photovoltaic support is connected with the notch cuttype coupling assembling on the photovoltaic support of third batch, lower bearing cable wire, it establishes ties bearing cable wire subassembly to go up the bearing cable wire, steel strand wires pass notch cuttype coupling assembling, bearing cable wire subassembly is with the third step roof beam, first step roof beam is connected, install panel one and panel two again, it is inseparabler to make to be connected between photovoltaic support and the photovoltaic support, when meeting strong wind, produce resonance between photovoltaic support and the photovoltaic support, the wind resistance has been strengthened, the windage intensity has been reduced, make the photovoltaic support after establishing ties firm and not fragile.

Drawings

The invention is further explained below with reference to the figures:

fig. 1 is a schematic structural view of the installation state of the present invention;

FIG. 2 is a block diagram of the present invention;

FIG. 3 is a block diagram of the present invention;

FIG. 4 is a block diagram of the present invention;

FIG. 5 is a block diagram of the present invention;

fig. 6 is a structural diagram of the stepped connection assembly of the present invention;

FIG. 7 is a block diagram of the present invention;

figure 8 is a block diagram of the load bearing wire rod assembly of the present invention;

fig. 9 is a structural diagram of the stepped connection assembly of the present invention;

FIG. 10 is a view of the first step beam of the present invention;

fig. 11 is a structural view of a third step beam of the present invention;

fig. 12 is a block diagram of the connection assembly of the present invention;

fig. 13 is an exploded view of the connection assembly of the present invention;

fig. 14 is an enlarged structural view of a portion a of fig. 9 according to the present invention;

fig. 15 is an enlarged structural view of a portion B of fig. 9 according to the present invention;

fig. 16 is an enlarged view of the portion C of fig. 9 according to the present invention;

fig. 17 is an enlarged structural view of a portion D in fig. 9 according to the present invention;

fig. 18 is an enlarged structural view of portion E of fig. 8 according to the present invention;

fig. 19 is an enlarged structural view of a portion F in fig. 8 according to the present invention;

fig. 20 is an enlarged structural view of a portion H of fig. 9 according to the present invention;

fig. 21 is an enlarged structural view of a portion G in fig. 8 according to the present invention;

fig. 22 is an enlarged view of a portion J of fig. 8 according to the present invention;

Detailed Description

The present invention will be described in further detail with reference to the drawings, which are only used for explaining the present invention, and are schematic illustrations of the embodiments of the present invention, and should not be construed as limiting the present invention.

In the description of the present invention, it should be noted that the calculation of the flow rate by using the infrared transmitter and the infrared receiver is a common technical means in the art, and unless otherwise explicitly specified and limited, the terms "connected" and "connected" should be understood in a broad sense, and for example, may be a fixed connection, a detachable connection, or an integral connection; can be mechanically or electrically connected; may be directly connected or indirectly connected through an intermediate. The specific meaning of the above terms in the present invention can be understood in specific cases to those skilled in the art.

Example 1

As shown in fig. 1, fig. 2, fig. 3, fig. 4, fig. 5, fig. 6, fig. 7, fig. 8, fig. 9, fig. 10, fig. 11, fig. 12, fig. 13, fig. 14, fig. 15, fig. 16, fig. 17, fig. 18, fig. 19, fig. 20, fig. 21 and fig. 22, a first steel strand 9-1 respectively passes through a plurality of steel strand pressing blocks 58 on a second step beam 21-9 and a cross combination wire clamp 70-9 on an upper bearing steel cable 70-8, and two ends of the first steel strand are respectively connected with a second anchorage 10-17 on a third step beam 10 and a first anchorage 1-16 on a first step beam 1;

the second steel strand 9-2 penetrates through the second steel strand pressing codes 58 on the second step beams 21-9 and the second transverse steel cable clamps 70-5 on the first steel cable connecting rod 70-1 respectively, and the two ends of the second steel strand are connected with the second anchorage 10-17 on the third step beam 10 and the first anchorage 1-16 on the first step beam 1 respectively;

the steel strand three 9-3 respectively passes through the steel strand pressing codes 58 on the plurality of first step beams 21-8 and the transverse steel cable clamps one 70-4 on the steel cable connecting rod two 70-2, and two ends of the steel strand three are respectively connected with the anchorage devices two 10-17 on the third step beam 10 and the anchorage devices one 1-16 on the first step beam 1;

the fourth steel strand 9-4 respectively penetrates through the steel strand pressing codes 58 on the plurality of first step beams 21-8 and the cross combined wire clamps 70-9 on the lower bearing steel cable 70-7, and the two ends of the fourth steel strand are respectively connected with the second anchorage 10-17 on the third step beam 10 and the first anchorage 1-16 on the first step beam 1;

the installed battery panel I15-1 and the installed battery panel II 15-2 are in a step shape, the air leakage grooves 15-3 are formed between the battery panel I15-1 and the battery panel II 15-2 and are arranged in a slope shape, the influence of strong wind on the battery panel and the photovoltaic support is reduced, and the wind flows through the air leakage grooves 15-3 between the battery panel I15-1 and the battery panel II 15-2.

The longitudinal connecting cable 35 penetrates through a pipeline formed by connecting a plurality of arc-shaped end parts three 3-7 with the arc-shaped end parts three 3-7, two ends of the longitudinal connecting cable 35 are fixed on anchor fixing parts at the upper ends of a first upright post 56 and a second upright post 57 respectively through anchors, or penetrate through anchor fixing parts at the upper ends of the first upright post 56 and the second upright post 57 through anchors, and are fixed on another reinforced upright post 56-1 and a reinforced upright post second 57-1 through rigging, a pipeline formed by connecting a plurality of arc-shaped end parts one 3-4 with arc-shaped end parts two 3-9 is connected with a third ladder beam 10 and an arc-shaped wire clamp 24 on a first ladder beam 1 through an inclined pull-up steel strand I21-1, and one end of a front brace rod 21-5, a middle connecting post 21-6 and a rear brace rod 21-7 is fixed between the upper clamp piece one 3-1 and the upper clamp piece two 3-2 through bolts;

the lower bearing steel cable 70-7 penetrates through a lower bearing steel cable clamp 70-6 on a plurality of steel cable connecting rods one 70-1, a lower bearing steel cable clamp 70-16 is arranged on a lower bearing steel cable hoop 70-17, a lower bearing steel cable clamp 70-6 on a steel cable connecting rod two 70-2 is arranged on the lower bearing steel cable hoop, two ends of the lower bearing steel cable clamp are respectively fixed on an anchorage fixing piece at the upper end of an extension bearing steel cable pull pile 70-11 through an anchorage, or penetrate through an anchorage fixing piece at the upper end of the extension bearing steel cable pull pile 70-11 through an anchorage and are fixed on a lower bearing steel cable anchor pile 70-12 through an anchorage, a steel strand three 9-3 penetrates through a transverse steel cable clamp one 70-4, and a steel strand two 9-2 penetrates through a transverse steel cable clamp two 70-5;

the upper bearing steel cable 70-8 penetrates through upper bearing steel cable clamps 70-3 on a plurality of steel cable connecting rods one 70-1, bearing steel cable wire clamps 24-1 and upper bearing steel cable clamps 70-3 on a plurality of steel cable connecting rods two 70-2, and two ends of the upper bearing steel cable clamps are respectively fixed on anchor fixing pieces at the upper ends of the upright posts three 70-13 through anchors or penetrate through the anchor fixing pieces at the upper ends of the upright posts three 70-13 through the anchors and are fixed on the other reinforcing upright post three 70-14 through rigging;

by analogy, the stepped connection assemblies 21 on the first row of photovoltaic supports are connected with the stepped connection assemblies 21 on the second row of photovoltaic supports, the stepped connection assemblies 21 on the second row of photovoltaic supports are connected with the stepped connection assemblies 21 on the third row of photovoltaic supports, the bearing steel cable assemblies 70-7 are connected in series by the lower bearing steel cable 70-8, the steel stranded wires 9 penetrate through the stepped connection assemblies 21 and the bearing steel cable assemblies 70 to connect the third step beam 10 and the first step beam 1, and then the first battery panel 15-1 and the second battery panel 15-2 are installed, so that the photovoltaic supports and the photovoltaic supports are connected more tightly, and when strong wind occurs, resonance is generated between the photovoltaic supports and the photovoltaic supports, the stress intensity is reduced, and the photovoltaic supports are not prone to damage.

On the basis of the embodiment 1, at least one of a plurality of lower bearing steel cable clamps 70-6, lower bearing steel cable hoops 70-17 and lower bearing steel cable clamps 70-6 is arranged;

on the basis of the embodiment 1, at least one of a plurality of upper bearing steel cable clamps 70-3, a bearing steel cable clamp 24-1 and an upper bearing steel cable clamp 70-3 is arranged;

on the basis of the embodiment 1, a plurality of first step beams 1, a plurality of third step beams 10, a bearing steel cable assembly 70, a step-shaped connecting assembly 21, a longitudinal connecting cable 35, a lower bearing steel cable 70-7, an upper bearing steel cable 70-8 and a steel strand 9 are criss-cross, and are stressed in multiple directions to form a step-shaped photovoltaic support, and an air discharge groove 15-3 between a first battery panel 15-1 and a second battery panel 15-2 at the upper end of the step-shaped photovoltaic support guides air to blow away.

The utility model discloses it is rational in infrastructure, make to be connected closely between photovoltaic support and the photovoltaic support, when meeting strong wind, produce resonance between photovoltaic support and the photovoltaic support, strengthened the anti-wind ability, reduced windage intensity, make the photovoltaic support after establishing ties firm and not fragile.

The above description is illustrative of the present invention and is not to be construed as limiting thereof, as numerous modifications and variations are possible to those skilled in the art. Any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included in the scope of the claims of the present invention.

Claims (10)

1. Cascaded photovoltaic support of resistant windage, its characterized in that: the steel strand connecting structure comprises a first stepped beam (1), a third stepped beam (10), a bearing steel cable assembly (70), stepped connecting assemblies (21), a longitudinal connecting cable (35), a lower bearing steel cable (70-7) and an upper bearing steel cable (70-8), wherein a steel strand (9) penetrates through a plurality of stepped connecting assemblies (21), a cross combined cable clamp (70-9) on the bearing steel cable assembly (70), a transverse steel cable clamp I (70-4) and a transverse steel cable clamp II (70-5), and two ends of the steel strand are respectively fixed on the first stepped beam (1) and the third stepped beam (10); a plurality of bearing steel cable assemblies (70) are arranged between the first step beam (1) and the third step beam (10), and a plurality of step-shaped connecting assemblies (21) are arranged between the bearing steel cable assemblies (70) and the first step beam (1) or the third step beam (10); a plurality of step-shaped connecting assemblies (21) are arranged between the first step beam (1) and the third step beam (10), a plurality of step-shaped connecting assemblies (21) are arranged between the bearing steel cable assembly (70) and the bearing steel cable assembly (70), and at least one of the bearing steel cable assembly (70) and the step-shaped connecting assemblies (21) is arranged;

a longitudinal connecting rope (35) penetrates through a pipeline formed by connecting a plurality of arc-shaped end parts III (3-7) with the arc-shaped end parts III (3-7), two ends of the longitudinal connecting rope (35) are respectively fixed on anchor fixing parts at the upper ends of a first upright post (56) and a second upright post (57) through anchors, or penetrate through anchor fixing parts at the upper ends of the first upright post (56) and the second upright post (57) through anchors and are fixed on another reinforcing upright post I (56-1) and a reinforcing upright post II (57-1) through rigging, a first inclined pull steel strand I (21-1) penetrates through a plurality of arc-shaped end parts I (3-4) and is connected with an arc-shaped end part II (3-9) to form a pipeline which is connected with a third ladder beam (10) and an arc-shaped wire clamp (24) on the first ladder beam (1), and one end of a front supporting rod (21-5), a middle connecting post (21-6) and a rear supporting rod (21-7) are all fixed between the first upper clamping piece (3-1) and the second clamping piece (3-2) through bolts;

the bearing steel cable piles (70-10) are multiple, and the bearing steel cable piles further comprise extension bearing steel cable pull piles (70-11) and lower bearing steel cable anchor piles (70-12), a lower bearing steel cable hoop (70-17) is arranged on each bearing steel cable pile (70-10), a lower bearing steel cable clamp (70-16) is arranged on each lower bearing steel cable hoop (70-17), a post top clamp fixing frame (70-15) is arranged at the top of each bearing steel cable pile (70-10), and a bearing steel cable clamp (24-1) and an arc-shaped clamp (24) are arranged on each post top clamp fixing frame (70-15);

the bearing steel cable assembly (70) comprises a first steel cable connecting rod (70-1), a second steel cable connecting rod (70-2), an upper bearing steel cable clamp (70-3), a first transverse steel cable clamp (70-4), a second transverse steel cable clamp (70-5), a lower bearing steel cable clamp (70-6), a lower bearing steel cable (70-7), an upper bearing steel cable (70-8) and a cross-shaped combined wire clamp (70-9), wherein the upper ends of the first steel cable connecting rod (70-1) and the second steel cable connecting rod (70-2) are respectively provided with the upper bearing steel cable clamp (70-3), the lower ends of the first steel cable connecting rod (70-2) are respectively provided with the lower bearing steel cable clamp (70-6), the outer side of the middle lower end of the second steel cable connecting rod (70-2) is provided with the first transverse steel cable clamp (70-4), the inner side of the middle upper end of the first steel cable connecting rod (70-1) is provided with the second transverse steel cable clamp (70-5), the upper bearing steel cable clamp (70-3) and the lower bearing steel cable clamp (70-6) are respectively positioned at two sides of the first steel cable connecting rod (70-1) and the second steel cable connecting rod (70-2); the lower bearing steel cable (70-7) penetrates through a lower bearing steel cable clamp (70-6) on a plurality of steel cable connecting rods I (70-1), a lower bearing steel cable clamp (70-16) is arranged on a lower bearing steel cable hoop (70-17), and a lower bearing steel cable clamp (70-6) on a steel cable connecting rod II (70-2), two ends of the lower bearing steel cable clamp are respectively fixed on an anchorage fixing piece at the upper end of an extension bearing steel cable pull pile (70-11) through an anchorage, or the lower bearing steel cable clamp penetrates through an anchorage fixing piece at the upper end of the extension bearing steel cable pull pile (70-11) and is fixed on a lower bearing steel cable anchor pile (70-12) through an anchorage, and the plurality of lower bearing steel cable clamps (70-6), the lower bearing steel cable hoop (70-17) and the lower bearing steel cable clamp (70-6) are at least one; the steel strand III (9-3) penetrates through the transverse steel cable clamp I (70-4), and the steel strand II (9-2) penetrates through the transverse steel cable clamp II (70-5); the upper bearing steel cable (70-8) penetrates through upper bearing steel cable clamps (70-3) on a plurality of steel cable connecting rods I (70-1), a bearing steel cable clamp (24-1) and upper bearing steel cable clamps (70-3) on a plurality of steel cable connecting rods II (70-2), two ends of each upper bearing steel cable clamp are respectively fixed on an anchorage fixing piece at the upper end of a vertical column III (70-13) through an anchorage, or each upper bearing steel cable clamp (70-3), a bearing steel cable clamp (24-1) and an upper bearing steel cable clamp (70-3) are at least one through an anchorage which penetrates through an anchorage fixing piece at the upper end of the vertical column III (70-13) and is fixed on another reinforcing vertical column III (70-14) through a rigging, a steel strand I (9-1) is connected with the upper bearing steel cable (70-8) through a cross combination wire clamp (70-9), and a steel strand IV (9-4) is connected with a lower bearing steel cable (70-7) through the cross combination wire clamp (70-9);

the first ladder beam (1) and the third ladder beam (10) are connected through a steel strand (9), the steel strand (9) comprises a first steel strand (9-1), a second steel strand (9-2), a third steel strand (9-3) and a fourth steel strand (9-4), the first steel strand (9-1), the second steel strand (9-2), the third steel strand (9-3) and the fourth steel strand (9-4) respectively penetrate through a steel strand pressing code (58) at the upper end of the ladder-type connecting assembly (21), the bearing steel cable assembly (70) and the two ends of the bearing steel cable clamp (24-1) are respectively connected with a first anchorage (1-16) on the first ladder beam (1) and a second anchorage (10-17) on the third ladder beam (10); the battery plate (15) comprises a battery plate I (15-1) and a battery plate II (15-2), the battery plate I (15-1) is arranged on the steel strand I (9-1) and the steel strand II (9-2), the battery plate II (15-2) is arranged on the steel strand III (9-3) and the steel strand IV (9-4), and an air release groove (15-3) is arranged between the battery plate I (15-1) and the battery plate II (15-2).

2. The wind-resistant stepped photovoltaic support according to claim 1, wherein: the ladder-shaped connecting assembly (21) comprises a first inclined pull-up steel strand (21-1), a front support rod (21-5), a middle connecting column (21-6), a rear support rod (21-7), a first-stage ladder beam (21-8), a second-stage ladder beam (21-9), a first connecting steel cable (21-10), a second connecting steel cable (21-11) and a longitudinal connecting cable (35), wherein one end of the front support rod (21-5), one end of the middle connecting column (21-6) and one end of the rear support rod (21-7) are fixed on the connecting assembly (3), one end of the first-stage ladder beam (21-8) is installed at the top of the front support rod (21-5), the other end of the first-stage ladder beam (21-6) is installed at the side of the middle connecting column (21-6), the other end of the second-stage ladder beam (21-7) is installed at the top of the rear support rod (21-7) and fixed through a bolt, the first-stage ladder beam (21-8) and the second-9) are provided with a steel strand pressing code (58), one end of the first-shaped connecting piece (51) which is installed on the first connecting cable (51) and a first connecting clamp (35), the first-stage ladder beams (21-8) are also provided with a second U-shaped connecting piece (52), the second U-shaped connecting piece (52) is connected with a second connecting steel cable (21-11) through an anchorage device, and the other end of the second connecting steel cable (21-11) is connected with a first U-shaped connecting piece (51) on the second-stage ladder beams (21-9) through an anchorage device.

3. The wind-resistant stepped photovoltaic support according to claim 1, wherein: the first step beam (1) comprises a first upright post I (1-1), a first upright post II (1-2), a first upright post III (1-3), a first hoop I (1-4), a first hoop III (1-6), a first support rod I (1-7), a first support rod II (1-8), a first support rod III (1-9), a first support rod IV (1-10), a first primary step beam upright post (1-11), a first middle connecting upright post (1-12), a first secondary step beam upright post (1-13), a first primary step beam (1-14) and a first secondary step beam (1-15), the upper end of the first upright post I (1-1) is provided with a first primary step beam upright post (1-11), the upper end of the first upright post II (1-2) is provided with a first middle connecting upright post (1-12), the upper end of the first secondary step beam upright post I (1-3) is provided with a first secondary step beam upright post (1-13), the first hoop II (1-7) and the first hoop II (1-4) and the first support rod II (1-7), the other ends of the first support rods (1-7) and the second support rods (1-8) are respectively connected with the first primary stepped beams (1-14) to form triangular support portions, the two ends of the first hoop III (1-6) are provided with the first support rods (1-9) and the first support rods (1-10), the other ends of the first support rods (1-9) and the first support rods (1-10) are respectively connected with the first secondary stepped beams (1-15) to form triangular support portions, the upper ends of the first primary stepped beam upright columns (1-11) are provided with the first primary stepped beams (1-14), the upper ends of the first secondary stepped beam upright columns (1-13) are provided with the first secondary stepped beams (1-15), one ends of the first primary stepped beams (1-14) are connected with the middle portions of the first middle connecting upright columns (1-12), the first secondary beams (1-15) are connected with the top portions of the first middle connecting upright columns (1-12), and the first primary stepped beams (1-14) and the middle portions of the first secondary stepped beam (1-12) are provided with first arc-shaped anchors (24).

4. The wind resistance stepped photovoltaic support of claim 1, wherein: the third step beam (10) comprises a first third upright post (10-1), a second third upright post (10-2), a third upright post (10-3), a first third hoop (10-4), a third hoop (10-6), a first third support rod (10-7), a second third support rod (10-8), a third support rod (10-9), a fourth third support rod (10-10), a third first-stage step Liang Lizhu (10-11), a third middle connecting upright post (10-12), a third second-stage step Liang Lizhu (10-13), a third first-stage step beam (10-14) and a third second-stage step beam (10-15), the upper end of the first third upright post (10-1) is provided with a first-level ladder Liang Lizhu (10-11), the upper end of the second third upright post (10-2) is provided with a third middle connecting upright post (10-12), the upper end of the third upright post (10-3) is provided with a second-level ladder Liang Lizhu (10-13), the first third upright post (10-1), the second third upright post (10-2) and the third upright post (10-3) are respectively provided with a first third hoop (10-4) and a third hoop (10-6), and the two ends of the first third hoop (10-4) are provided with a first third support rod (10-7), the other ends of the first third support rod (10-7) and the second third support rod (10-8) are respectively connected with a third first-stage step beam (10-14) to form a triangular supporting part, the two ends of the third hoop III (10-6) are provided with a third support rod (10-9) and a third support rod IV (10-10), the other ends of the third support rod III (10-9) and the third support rod IV (10-10) are respectively connected with a third second-stage step beam (10-15) to form a triangular supporting part, the upper end of the third first-stage step Liang Lizhu (10-11) is provided with a third first-stage step beam (10-14), the upper end of the third second-stage step Liang Lizhu (10-13) is provided with a third second-stage step beam (10-15), one end of the third first-stage step beam (10-14) is connected with the middle part of the third middle part of the upright post (10-12), and the third-stage beam (10-15) is connected with the top part of the upright post (10-12).

5. The wind resistance stepped photovoltaic support of claim 1, wherein: the connecting component (3) comprises a first upper clamping piece (3-1), a second upper clamping piece (3-2), a first middle clamping piece (3-3), a second middle clamping piece (3-8), a first arc-shaped end (3-4), a second arc-shaped end (3-9), a first lower clamping piece (3-5), a second lower clamping piece (3-6) and a third arc-shaped end (3-7), wherein the first upper clamping piece (3-1) and the second upper clamping piece (3-2) are arranged at the upper end of the first middle clamping piece (3-3), the first upper clamping piece (3-1), the second upper clamping piece (3-2) and the first middle clamping piece (3-3) are welded into an integral structure, corresponding holes are formed in the first upper clamping piece (3-1) and the second upper clamping piece (3-2), the first arc-shaped end (3-4) is arranged on the first middle clamping piece (3-3), the first lower end of the second middle clamping piece (3-8) is provided with the first lower clamping piece (3-5) and the second lower clamping piece (3-6), the second middle clamping piece (3-8) and the second arc-shaped clamping piece (3-5) are symmetrically welded into an integral structure, the upper clamping piece (3-7) and the lower clamping piece (3-7), the middle clamping piece I (3-3) is connected with the middle clamping piece II (3-8) and fixed through bolts, the arc-shaped end part I (3-4) is connected with the arc-shaped end part II (3-9) to form a pipeline, and the arc-shaped end part III (3-7) is connected with the arc-shaped end part III (3-7) to form a pipeline.

6. The wind resistance stepped photovoltaic support of claim 1, wherein: the first steel strand (9-1) penetrates through the steel strand pressing codes (58) on the secondary ladder beams (21-9) and the cross-shaped combined wire clamps (70-9) on the upper bearing steel cable (70-8) respectively, and two ends of the first steel strand (9-1) are connected with the second anchorage devices (10-17) on the third ladder beam (10) and the first anchorage devices (1-16) on the first ladder beam (1) respectively.

7. The wind resistance stepped photovoltaic support of claim 1, wherein: the second steel strand (9-2) penetrates through the second steel strand pressing codes (58) on the second-stage step beams (21-9) and the second transverse steel cable clamp (70-5) on the first steel cable connecting rod (70-1) respectively, and two ends of the second steel strand (9-2) are connected with the second anchorage device (10-17) on the third step beam (10) and the first anchorage device (1-16) on the first step beam (1) respectively.

8. The wind resistance stepped photovoltaic support of claim 1, wherein: the steel strand III (9-3) respectively penetrates through the steel strand pressing codes (58) on the first-stage step beams (21-8) and the transverse steel cable clamps I (70-4) on the steel cable connecting rod II (70-2), and two ends of the steel strand III are respectively connected with the anchorage devices II (10-17) on the third step beam (10) and the anchorage devices I (1-16) on the first step beam (1).

9. The wind-resistant stepped photovoltaic support according to claim 1, wherein: the four steel strands (9-4) respectively penetrate through the steel strand pressing codes (58) on the first-stage stepped beams (21-8) and the cross combined wire clamps (70-9) on the lower bearing steel cable (70-7), and two ends of the four steel strands are respectively connected with the second anchorage devices (10-17) on the third stepped beam (10) and the first anchorage devices (1-16) on the first stepped beam (1).

10. The wind resistance stepped photovoltaic support of claim 3, wherein: the first primary step beams (1-14), the third primary step beams (10-14) and the primary step beams (21-8) are parallel to each other;

the first secondary stepped beam (1-15), the third secondary stepped beam (10-15) and the second stepped beam (21-9) are parallel to each other;

the heights of the first primary stepped beams (1-14), the third primary stepped beams (10-14) and the primary stepped beams (21-8) are all lower than the heights of the first secondary stepped beams (1-15), the third secondary stepped beams (10-15) and the secondary stepped beams (21-9);

the solar panel (15) on the first steel strand (9-1) and the second steel strand (9-2), the solar panel (15) on the third steel strand (9-3) and the fourth steel strand (9-4) are of a ladder structure, and the air discharge groove (15-3) formed by the first solar panel (15-1) and the second solar panel (15-2) is spaced from each other by 15-90cm.

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