CN117691924B - Cable-stayed flexible photovoltaic bracket unit and photovoltaic bracket - Google Patents

Abstract

The invention relates to the technical field of photovoltaic supports, and provides a diagonal flexible photovoltaic support unit and a photovoltaic support, wherein the diagonal flexible photovoltaic support unit comprises two groups of bottom support assemblies, each group of bottom support assemblies comprises two support seats, a lifting slide cylinder, a bearing steel rope, a rotation limiting assembly, a circulating steel rope and a rotation control assembly, the top of each support seat is slidably connected with the lifting slide cylinder, a fixing assembly is arranged between the lifting slide cylinder and the support seat, the bearing steel rope is fixedly connected onto the lifting slide cylinder through a fastening clamp, the top of the lifting slide cylinder is provided with a rotation limiting assembly, the rotation limiting assembly is used for limiting the moving direction of the bearing steel rope, and a rotation control assembly is arranged between the two lifting slide cylinders positioned on the same side. Through above-mentioned technical scheme, the flexible photovoltaic support among the prior art has been solved and the problem that the operating personnel carries out fixed mounting with solar panel is inconvenient.

Description

Cable-stayed flexible photovoltaic bracket unit and photovoltaic bracket

Technical Field

The invention relates to the technical field of photovoltaic supports, in particular to a diagonal flexible photovoltaic support unit and a photovoltaic support.

Background

The photovoltaic support is the current mechanism for installing solar panel among the prior art, because the popularization to solar energy utilization among the prior art, so the demand of market is also higher and higher to photovoltaic support, wherein photovoltaic support is according to the difference of installation place, divide into ordinary photovoltaic support and flexible photovoltaic support, wherein ordinary photovoltaic support just is with solar panel slope installation at the top of various buildings for make solar panel carry out thorough fixed connection, and in order to make solar panel can install on various buildings or mountain, fix a plurality of solar panels through can adopting flexible photovoltaic support, and flexible photovoltaic support is different with ordinary photovoltaic support, and flexible photovoltaic support can make solar panel install in different regions.

The conventional flexible photovoltaic support is composed of two groups of support columns, at least two bearing steel ropes are used between the two groups of support columns, if the extending length of the bearing steel ropes is too long, a support assembly is further required to be arranged at the bottom of the bearing steel ropes, then a plurality of solar panels are installed among the plurality of bearing steel ropes through fasteners, so that the solar panels are fixedly installed, and the purpose of installing the solar panels by using the flexible photovoltaic support is to reduce the limit of topography on the installation of the solar panels to the maximum extent.

And when current installing the flexible photovoltaic support, in order to guarantee solar panel to the effect of utilizing of solar energy, so need install solar panel in the higher position of distance from ground, and because the length of bearing cable is longer, so when operating personnel installs solar panel, also more difficult messenger's solar panel slides on the bearing cable, consequently in prior art to the installation of solar panel, operating personnel is more difficult to remove the assigned position on the bearing cable with solar panel easily, and even after sliding solar panel to the assigned position, because need operating personnel thoroughly fasten solar panel on the bearing cable, so still need operating personnel to carry out the aerial work, not only improved operating difficulty, still reduced the efficiency to the solar panel of installing on the flexible photovoltaic support.

Disclosure of Invention

The invention provides a diagonal flexible photovoltaic bracket unit and a photovoltaic bracket, which solve the problem that the flexible photovoltaic bracket in the related art is inconvenient for operators to fixedly install a solar panel.

The technical scheme of the invention is as follows: the utility model provides a draw flexible photovoltaic support unit to one side, includes two sets of bottom sprag subassembly, every group bottom sprag subassembly all includes two supporting seats, still includes:

the top of the supporting seat is connected with the lifting sliding cylinder in a sliding manner, and a fixing assembly is arranged between the lifting sliding cylinder and the supporting seat;

the bearing steel cable is fixedly connected to the lifting slide cylinder through a fastening clamp;

The rotation limiting assembly is arranged at the top of the lifting slide cylinder and used for limiting the moving direction of the bearing steel cable;

a circulating steel rope;

The rotation control assembly is arranged between the two lifting sliding drums positioned on the same side, and the circulating steel cable is arranged between the two rotation control assemblies;

A plurality of shock absorbing plates;

The bottom of the shock absorbing plate is fixedly connected with the steel rope connecting component, the steel rope connecting component is used for fixing the shock absorbing plate and the circulating steel rope, and the bottom of the solar panel is also provided with the steel rope connecting component;

The steel cable descending components are arranged on the lifting sliding drums at two sides, and are used for driving the damping plates to descend.

In order to enable the lifting slide cylinder to be fixed with the supporting seat after the lifting slide cylinder is lifted to a certain height, preferably, the fixing assembly comprises a connecting plate and a supporting piece, the bottom of the lifting slide cylinder and the supporting seat are fixedly connected with the connecting plate, and the supporting piece is fixedly connected with one ends, close to the two connecting plates, of the connecting plate.

In order to prevent the bearing cable from sliding off at the top of the lifting slide cylinder, further, the rotation limiting assembly comprises a fixed frame, a sliding groove body, a damping spring device I, a rotating cylinder body, a rotating shaft, friction wheels and limiting assemblies, wherein the fixed frame is fixedly connected with the top of the lifting slide cylinder, the sliding groove bodies are fixedly connected to the inner walls of the two sides of the fixed frame, the sliding bodies are fixedly connected to the sliding groove bodies in a sliding manner, the damping spring device I is arranged between the sliding bodies and the inner top wall of the sliding groove bodies, the rotating cylinder bodies are fixedly connected to the sliding bodies in a sliding manner, the rotating shafts are fixedly connected to the two rotating cylinder bodies in a rotating manner, and the friction wheels are fixedly connected between the two rotating shafts, and the limiting assemblies are arranged between the inner parts of the rotating cylinder bodies and the rotating shafts.

In order to enable the circulating steel cable to move among the lifting sliding drums, the rotary control assembly comprises a rotary frame, a mounting plate body, rotary sleeves, rotary rings, rotary wheels, fixed groove bodies and two guide rollers, wherein the rotary frame is fixedly connected to the lifting sliding drums, a fixed rod is fixedly connected to the rotary frame, the mounting plate body is rotationally connected between the two fixed rods, the rotary sleeves are arranged on the mounting plate body in a penetrating mode, the rotary rings are rotationally connected to the rotary sleeves, rotary pieces are fixedly connected to two sides of the inner wall of each rotary ring, the rotary wheels are rotationally connected to the rotary pieces, the fixed groove bodies are fixedly connected to the bottoms of the rotary sleeves, and the guide rollers are longitudinally rotationally connected to the fixed groove bodies.

In order to make shock attenuation board and solar panel all fixed with circulation cable, still further, cable wire coupling assembling includes fixed block, rotation ring section of thick bamboo, friction seat and grip slipper, fixed block fixed connection is in the bottom of shock attenuation board, rotation ring section of thick bamboo rotates to be connected on the fixed block, the opening has been seted up on the rotation ring section of thick bamboo, friction seat fixed connection is in the rotation ring section of thick bamboo, the grip slipper slides through fixing screw and sets up on the rotation ring section of thick bamboo, threaded connection has the nut on the fixing screw.

In order to make the circulation cable descend, make the bearing cable surface possess sufficient tension, on the basis of this scheme, the cable descending subassembly includes L type frame, installing frame, mount pad and drive screw, L type frame fixed connection is in on the lift slide, the inside upper and lower both sides of installing frame are all rotated and are connected with the control wheel, the circulation cable passes two the control wheel, mount pad fixed connection is in the bottom of installing frame, the mount pad pass through the slide bar with L type frame sliding connection, drive screw threaded connection is in the bottom of L type frame, drive screw with the mount pad rotates to be connected.

On the basis of the scheme, the limiting assembly comprises an arc-shaped frame, an arc-shaped strip and a rotating seat, wherein the arc-shaped frame is fixedly connected in the rotating cylinder, one end of the arc-shaped strip is rotationally connected in the arc-shaped frame, an arc-shaped opening is formed in the rotating shaft corresponding to the arc-shaped strip, the rotating seat is slidingly connected to the bottom of the arc-shaped strip, a damping spring device II is arranged in the arc-shaped frame, and the top of the damping spring device II is rotationally connected with the rotating seat.

A diagonal flexible photovoltaic stent comprising a plurality of diagonal flexible photovoltaic stent units according to any one of the above-described schemes.

The working principle and the beneficial effects of the invention are as follows:

1. In the invention, when the solar panel is required to be installed on two bearing steel cables, and in order to enable the solar panel to be obliquely arranged on the two bearing steel cables, firstly, the lifting sliding drums are slid to longitudinally move on the top of the supporting seat, so that the two lifting sliding drums positioned on the same side are different in horizontal height, then, fixing pieces with corresponding lengths are arranged between the lifting sliding drums and the supporting seat to fix the bearing steel cables, when the bearing steel cables are subsequently fixed, the horizontal heights of the two bearing steel cables can be kept different, the bearing steel cables are fixedly arranged on the lifting sliding drums through fastening clamps, and the bearing steel cables are installed on the solar panel, the bearing steel cables are not kept to be tensioned, so that the bearing steel cables are kept relatively close to the supporting seat installation base surface, then, the plurality of solar panels and the plurality of shock absorbing plates are driven to move on the bearing steel cables through the circulating steel cables, so that operators can move the plurality of solar panels to corresponding positions on the bearing steel cables, and after the plurality of solar panels are sequentially installed on the two bearing steel cables, the two bearing steel cables are pulled towards opposite directions, the lifting steel cables are enabled to be kept between the two bearing steel cables to be tensioned, thus, the solar panel installation efficiency is improved, and the solar panel installation work efficiency is improved;

2. in the application, when the solar panel is installed at a designated position and the bearing steel cable is pulled, in order to avoid that a plurality of solar panels are installed on the bearing steel cable in the pulling process of the bearing steel cable, in order to avoid that the bearing steel cable slides towards the solar panel because of a large load on the bearing steel cable, the bearing steel cable can be effectively prevented from sliding towards the solar panel by arranging the rotation limiting component in the moving process of the bearing steel cable at the top of the lifting slide cylinder, so that the safety of the application in the implementation process is improved;

3. in the invention, in order to enable the circulating steel rope to drive the plurality of shock absorbing plates and the plurality of solar plates to move on the bearing steel rope, under the action of the rotating frame and the fixed rod, the mounting plate body can correspond to the inclination angle of the solar plates, so that the circulating steel rope can smoothly move between two rotating wheels, and the plurality of shock absorbing plates and the plurality of solar plates are sequentially fixed with the circulating steel rope through the steel rope fixing assembly, so that the circulating steel rope can sequentially drive the plurality of shock absorbing plates and the plurality of solar plates to move in the moving process, and the solar plates are moved to the designated positions on the bearing steel rope;

4. Therefore, the inclined-pulling type flexible photovoltaic bracket unit can reduce the distance between the bearing steel cables and the mounting base surface of the supporting seat in the process of mounting the solar panel between the bearing steel cables, so that operators can conveniently mount the solar panel at the appointed position of the bearing steel cables, the overhead workload of the operators is reduced, and the working efficiency of mounting the solar panel is improved.

Drawings

The invention will be described in further detail with reference to the drawings and the detailed description.

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

FIG. 2 is a schematic view of the cooperation structure of the support base, the lifting slide, the rotation limiting assembly and the rotation control assembly according to the present invention;

FIG. 3 is a schematic view of the load bearing cable, endless cable, cable connection assembly and cable lowering assembly of the present invention mated;

FIG. 4 is a schematic view of a partial enlarged structure of the present invention at A in FIG. 3;

FIG. 5 is a schematic view of a partially enlarged structure of the present invention at B in FIG. 3;

FIG. 6 is a schematic view of a partially enlarged structure of the present invention at C in FIG. 3;

FIG. 7 is a schematic view of the configuration of the engagement of the securing assembly, rotation limiting assembly, rotation control assembly, cable tie assembly and cable lowering assembly of the present invention;

FIG. 8 is a schematic view of a support base, lifting slide, rotation limiting assembly, rotation control assembly and cable lowering assembly of the present invention shown partially in cross-section;

FIG. 9 is a schematic view in partial cross-section of the rotation limiting assembly and the engagement of the limiting assembly of the present invention;

FIG. 10 is a schematic view of a partially enlarged structure of the present invention at D in FIG. 9;

FIG. 11 is a schematic view of a rotational control assembly according to the present invention;

fig. 12 is a schematic view of a cable lowering assembly according to the present invention.

In the figure: 100. a fixing assembly; 200. a rotation limiting assembly; 300. a rotation control assembly; 400. a wire rope connection assembly; 500. a cable lowering assembly; 600. a restriction assembly;

1. A support base; 2. lifting the sliding cylinder; 3. a load-bearing steel rope; 4. a circulating steel rope; 5. a shock absorbing plate; 6. a connecting plate; 7. a support; 8. a fixed frame; 9. a sliding groove body; 10. a sliding body; 11. damping the first spring device; 12. rotating the cylinder; 13. a rotating shaft; 14. a friction wheel; 15. a rotating frame; 16. a fixed rod; 17. a mounting plate body; 18. a rotating sleeve; 19. a rotating ring; 20. a rotating wheel; 21. a fixed groove body; 22. a guide roller; 23. a fixed block; 24. rotating the ring cylinder; 25. a friction seat; 26. a clamping seat; 27. an L-shaped frame; 28. a mounting frame; 29. a control wheel; 30. a mounting base; 31. a slide bar; 32. a drive screw; 33. an arc-shaped frame; 34. an arc-shaped strip; 35. a rotating seat; 36. damping spring device II; 37. fastening the ferrule.

Detailed Description

The technical solutions of the embodiments of the present invention will be clearly and completely described below in conjunction with the embodiments of the present invention, and it is apparent that the described embodiments are only some embodiments of the present invention, not all embodiments. All other embodiments, which can be made by one of ordinary skill in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

As shown in fig. 1 to 12, this embodiment proposes a cable-stayed flexible photovoltaic support unit, including two sets of bottom support components, each set of bottom support components includes two support bases 1, and further includes a lifting slide 2, a load-bearing steel cable 3 and a circulating steel cable 4, the top of the support base 1 is slidably connected with the lifting slide 2, a fixing component 100 is disposed between the lifting slide 2 and the support base 1, the load-bearing steel cable 3 is fixedly connected to the lifting slide 2 through a fastening clip, the fixing component 100 includes a connecting plate 6 and a support member 7, the bottom of the lifting slide 2 is fixedly connected with the connecting plate 6 on the support base 1, the support member 7 is fixedly connected to one end of the two connecting plates 6, in order to ensure that a solar panel has a good lighting effect, after the support base 1 is fixedly installed, the lifting slide 2 is slid on the corresponding support base 1, thereby adjusting the specific height of the lifting slide 2, after the height adjustment of the lifting slide 2 is completed, the load-bearing steel cable 3 is fixedly connected to the lifting slide 2 through a fastening clip, the connecting plate 6 is fixedly connected with the support base 1 through a fastening clip, the corresponding hoop 6 is disposed between the two support hoops 3, the two support hoops 3 are fastened, the solar panel 37 is fastened on the support hoops 3, the solar panel 37 is fixed on the support base 3, the solar panel is fixed on the support base 37, the solar panel is fixed on the base 37, and the distance between the support frame is fixed on the support frame 37 is fixed, and the base 37 is fixed, and the distance between the support frame is fixed, and the frame is fixed on the frame is fixed by the frame and the frame, and the frame is fixed, the endless steel cord 4 is enabled to move the solar panel and the tightening strap 37 over the load-bearing steel cord 3.

The top of the lifting sliding cylinder 2 is provided with a rotation limiting component 200, the rotation limiting component 200 is used for limiting the moving direction of the bearing steel rope 3, the rotation limiting component 200 comprises a fixed frame 8, a sliding groove body 9, a damping spring device I11, a rotating cylinder body 12, a rotating shaft 13, friction wheels 14 and a limiting component 600, the fixed frame 8 is fixedly connected to the top of the lifting sliding cylinder 2, sliding groove bodies 9 are fixedly connected to the inner walls of two sides of the fixed frame 8, sliding bodies 10 are fixedly connected to the two sliding groove bodies 9 in a sliding manner, the damping spring device I11 is arranged between the sliding bodies 10 and the inner top wall of the sliding groove body 9, the rotating cylinder bodies 12 are fixedly connected to the two sliding bodies 10 in a rotating manner, the rotating shafts 13 are rotatably connected to the two rotating cylinder bodies 12 in a rotating manner, the friction wheels 14 are fixedly connected between the two rotating shafts 13, the limiting component 600 is arranged between the inner part of the rotating cylinder bodies 12 and the rotating shafts 13, when two bearing steel ropes 3 are installed on the lifting slide cylinder 2 through fastening clamps, the bearing steel ropes 3 penetrate through the fixed frame 8 and penetrate between the bottom of the friction wheel 14 and the inner bottom wall of the fixed frame 8, the friction wheel 14 is contacted with the bearing steel ropes 3 under the action of the damping spring I11, the inner bottom wall of the fixed frame 8 is provided with grooves, the bearing steel ropes 3 move in the grooves, the problem that deviation is difficult to occur in the moving process of the bearing steel ropes 3 is ensured, in order to facilitate the solar panel to be moved to a designated position on the bearing steel ropes 3, an operator can conveniently screw bolts on the fastening hoops 37, so the bearing steel ropes 3 are kept loose in advance, the height of the bearing steel ropes 3 and the installation base surface of the supporting seat 1 is reduced, and after a plurality of solar panels are installed on the bearing steel ropes 3, the fastening effect of the fastening clamps on the bearing steel ropes 3 is temporarily loosened, the two sides of the bearing steel rope 3 are pulled in a direction away from the solar panel, so that the bearing steel rope 3 is kept tensioned, and the installation operation of the solar panel is completed, and in the pulling process of the bearing steel rope 3, in order to prevent the problem of deflection of the bearing steel rope 3, the friction wheel 14 and the fixed frame 8 are used for strictly controlling the pulling effect of the bearing steel rope 3;

The limiting component 600 comprises an arc-shaped frame 33, an arc-shaped strip 34 and a rotating seat 35, wherein the arc-shaped frame 33 is fixedly connected in a rotating cylinder 12, one end of the arc-shaped strip 34 is rotationally connected in the arc-shaped frame 33, an arc opening is formed in a rotating shaft 13 corresponding to the arc-shaped strip 34, the rotating seat 35 is slidingly connected at the bottom of the arc-shaped strip 34, a damping spring device II 36 is arranged in the arc-shaped frame 33, the top of the damping spring device II 36 is rotationally connected with the rotating seat 35, in order to prevent the bearing steel rope 3 from moving in the direction away from the solar plate, the problem that large gravity exists due to the fact that a plurality of solar panels are fixed on the bearing steel rope 3, when the bearing steel rope 3 moves in the direction away from the solar plate, the large friction force between the bearing steel rope 3 and a friction wheel 14, the friction wheel 14 can be driven in the pulling process of the bearing steel rope 3, and the rotating shaft 13 are rotated between the two rotating cylinders 12, and the arc opening and the arc-shaped strip 34 are all arranged, so that when the bearing steel rope 3 moves in the direction away from the solar plate, the bearing steel rope 3 does not enter the bearing steel rope 3, and the bearing steel rope 3 moves in the direction, and the arc-shaped strip 13 is controlled to move in the direction, and the rotating seat 13 is controlled, and the rotating in the direction of the bearing steel rope 3, and the rotating direction is in the direction, and the rotating direction, and is in the rotating direction, and is far away from the rotation.

A rotation control component 300 is arranged between two lifting sliding drums 2 positioned on the same side, a circulation steel rope 4 is arranged between the two rotation control components 300, the rotation control components 300 comprise a rotation frame 15, a mounting plate body 17, a rotation sleeve 18, a rotation ring 19, a rotation wheel 20, a fixed groove body 21 and two guide rollers 22, the two lifting sliding drums 2 are fixedly connected with the rotation frame 15, a fixed rod 16 is fixedly connected in the rotation frame 15, the mounting plate body 17 is rotatably connected between the two fixed rods 16, the rotation sleeve 18 penetrates through the mounting plate body 17, the rotation ring 19 is rotatably connected in the rotation sleeve 18, two rotation pieces are fixedly connected to the two sides of the inner wall of the rotation ring 19, the rotation wheel 20 is rotatably connected in the two rotation pieces, the fixed groove body 21 is fixedly connected to the bottom of the rotation sleeve 18, the two guide rollers 22 are longitudinally and rotatably connected in the fixed groove body 21, in order to enable the circulation steel rope 4 to smoothly drive a plurality of solar panels and damping plates 5 to move between the two bearing steel ropes 3, firstly, in order to enable the mounting plate 17 to correspond to the inclination angle of the solar panels, the rotation sleeve 17 is rotatably connected between the two bearing plates 16 after the two lifting sliding drums 2 are rotatably arranged, the rotation sleeve 18 is rotatably connected to the rotation ring 19, the rotation wheels 20 can enable the rotation wheels to rotate normally, and the rotation rings 20 can be stably move under the rotation of the rotation rings 20 through the two rotation rings 20, and the rotation rings 20 can be stably and enable the rotation rings to pass through the rotation rings to rotate the rotation rings 20 and the rotation rings 20 to enable the rotation rings to rotate under the rotation plate to rotate through the fixed rings and the fixed rings 20 to have a stable inclination angle to enable the rotation angle to be normally and stable. The endless steel rope 4 is connected end to end so that the endless steel rope 4 moves the damper plate 5 and the mounting base.

The quantity of shock attenuation board 5 is established to a plurality of, the equal fixedly connected with cable coupling assembling 400 in the bottom of shock attenuation board 5, cable coupling assembling 400 is used for making shock attenuation board 5 fixed with circulation cable 4, and the bottom of solar panel also is provided with cable coupling assembling 400, cable coupling assembling 400 includes fixed block 23, a rotating ring section of thick bamboo 24, friction seat 25 and grip slipper 26, fixed block 23 fixed connection is in the bottom of shock attenuation board 5, rotating ring section of thick bamboo 24 rotates to be connected on fixed block 23, the opening has been seted up on the rotating ring section of thick bamboo 24, friction seat 25 fixed connection is in rotating ring section of thick bamboo 24, grip slipper 26 slides through the fixing screw and sets up on rotating ring section of thick bamboo 24, the screw thread connection has the nut on the fixing screw, in order to prevent when circulation cable 4 drives solar panel and removes, the problem that two solar panel collide each other, when carrying on a plurality of solar panels, set up shock attenuation board 5 at the interval between two solar panel, both sides of shock attenuation board 5 all are provided with the shock pad, can alleviate the problem that the solar panel removes in the process through the shock pad, and in order to make circulation cable 4 and cable 5 take out the position and then take out the fixed ring section of thick bamboo 24 and the fixed connection through the fixed ring section of thick bamboo 24, take out the position and then rotate ring section of thick bamboo 24, take out the fixed connection in order to make the position of circulation cable 4 and the fixed ring section of thick bamboo and the fixed connection with the rotation 4, and take out the fixed position of the nut that the rotation cable 24 is followed the rotation, and the fixed ring is followed by rotating ring and fixed position and the rotation of the rotation 4 and the rotation is fixed, and the position of the rotation ring is rotated and the ring and the position of the ring is rotated.

The steel cable descending assemblies 500 are arranged on the lifting sliding drums 2 positioned on two sides, the steel cable descending assemblies 500 are used for driving the shock absorbing plates 5 to descend, the steel cable descending assemblies 500 comprise an L-shaped frame 27, a mounting frame 28, a mounting seat 30 and a transmission screw rod 32, the L-shaped frame 27 is fixedly connected to the lifting sliding drums 2, control wheels 29 are rotatably connected to the upper side and the lower side of the inside of the mounting frame 28, a circulating steel cable 4 passes through the two control wheels 29, the mounting seat 30 is fixedly connected to the bottom of the mounting frame 28, the mounting seat 30 is in sliding connection with the L-shaped frame 27 through a sliding rod 31, the transmission screw rod 32 is in threaded connection with the bottom of the L-shaped frame 27, the transmission screw rod 32 is in rotary connection with the mounting seat 30, and after the shock absorbing plates 5 and the solar panels are all moved to the designated positions on the bearing steel cable 3, the circulating steel cable 4 is fixed in the rotary ring drum 24 at the bottom of the shock absorbing plates 5, because of the sometimes long distance of the load-bearing wire rope 3, there is often a lack of sufficient tension in the central region of the load-bearing wire rope 3, and because the application is aimed at securing the load-bearing wire rope 3 after mounting the solar panel on the load-bearing wire rope 3, in order to avoid a large gap in the load-bearing wire rope 3, because the circulation wire rope 4 itself moves between the two control wheels 29 in the mounting frame 28 during movement, the drive screw 32 moves the mounting frame 28 and the circulation wire rope 4 downwards by rotating the drive screw 32, because the circulation wire rope 4 itself is at a position lower than the height of the uppermost load-bearing wire rope 3, the region of the circulation wire rope 4 between the two mounting plate bodies 17 and the plurality of rotating ring drums 24 is not parallel, whereas the circulation wire rope 4 of this region is in an obliquely upward posture, the circulating steel rope 4 is driven to descend through the mounting frame 28, the positions of the two mounting plate bodies 17 are unchanged, so that the region of the circulating steel rope 4 between the two mounting plate bodies 17 and the plurality of rotating ring drums 24 starts to develop in a parallel direction, the plurality of damping plates 5 are driven to descend through the circulating steel rope 4, the contact region of the bearing steel rope 3 with the damping plates 5 is sunken, the bearing steel rope 3 is ensured to have enough tension, the stability of the bearing steel rope 3 can be improved through the damping plates 5, gaps on the bearing steel rope 3 are reduced, and the plurality of solar panels are tightly arranged.

A diagonal flexible photovoltaic stent comprising a plurality of diagonal flexible photovoltaic stent units according to any one of the above-described schemes.

The use principle of the inclined-pulling type flexible photovoltaic bracket unit is as follows: the specific height of the lifting slide cylinder 2 is adjusted by sliding the lifting slide cylinder 2 on the corresponding supporting seat 1, after the height of the lifting slide cylinder 2 is adjusted, a supporting piece 7 with corresponding length is fixed between two connecting plates 6, so that the lifting slide cylinder 2 and the supporting seat 1 are kept fixed, then the bearing steel rope 3 is installed on the lifting slide cylinder 2 through a fastening clamp, the bearing steel rope 3 between the two lifting slide cylinders 2 is kept to be certain loose, the distance between the bearing steel rope 3 and the installation base surface of the supporting seat 1 is reduced, various fastening hoops 37 and other parts are fixedly installed at the bottom of a solar panel, the fastening hoops 37 are fixed on the bearing steel rope 3, bolts on the fastening hoops 37 are not required to be screwed, the fastening hoops 37 can not fall off on the bearing steel rope 3, and the circulating 4 can drive the solar panel and the fastening hoops 37 to move on the steel rope 3 during the movement of the circulating steel rope 4 between the two installation plate bodies 17 and the two fixing groove bodies 21;

After the plurality of shock absorbing plates 5 and the plurality of solar panels are moved onto the bearing steel rope 3, the transmission screw 32 is rotated to enable the transmission screw 32 to drive the mounting frame 28 and the circulating steel rope 4 to move downwards, so that the circulating steel rope 4 drives the plurality of shock absorbing plates 5 to descend, the contact area between the bearing steel rope 3 and the shock absorbing plates 5 is sunken, enough tension of the bearing steel rope 3 is ensured, the stability of the bearing steel rope 3 can be improved by the shock absorbing plates 5, gaps on the bearing steel rope 3 are reduced, and the plurality of solar panels are tightly arranged.

The foregoing description of the preferred embodiments of the invention is not intended to be limiting, but rather is intended to cover all modifications, equivalents, alternatives, and improvements that fall within the spirit and scope of the invention.

Claims (7)

1. The utility model provides a draw flexible photovoltaic support unit to one side, includes two sets of bottom sprag subassembly, every group bottom sprag subassembly all includes two supporting seats (1), its characterized in that still includes:

The lifting sliding cylinder (2) is connected with the top of the supporting seat (1) in a sliding manner, and a fixing assembly (100) is arranged between the lifting sliding cylinder (2) and the supporting seat (1);

the bearing steel cable (3) is fixedly connected to the lifting slide cylinder (2) through a fastening clamp;

The rotation limiting assembly (200) is arranged at the top of the lifting slide cylinder (2), and the rotation limiting assembly (200) is used for limiting the moving direction of the bearing steel rope (3);

A circulation cable (4);

The rotation control assembly (300) is arranged between the two lifting sliding drums (2) positioned on the same side, the rotation control assembly (300) is arranged between the two rotation control assemblies (300), and the circulating steel cable (4) is arranged between the two rotation control assemblies (300);

Damping plates (5), the number of the damping plates (5) is set to be a plurality;

The steel cable connecting assembly (400) is fixedly connected to the bottom of the damping plate (5) and the steel cable connecting assembly (400), the steel cable connecting assembly (400) is used for fixing the damping plate (5) and the circulating steel cable (4), and the steel cable connecting assembly (400) is also arranged at the bottom of the solar panel;

The steel cable descending assemblies (500) are arranged on the lifting sliding drums (2) at two sides, and the steel cable descending assemblies (500) are used for driving the damping plates (5) to descend;

the rotation limiting assembly (200) includes:

the fixed frame (8), the said fixed frame (8) is fixedly connected to the top of the said lifting slide (2);

The sliding groove bodies (9) are fixedly connected to the inner walls of the two sides of the fixed frame (8), and the sliding bodies (10) are slidably connected in the two sliding groove bodies (9);

A damping spring device I (11), wherein the damping spring device I (11) is arranged between the sliding body (10) and the inner top wall of the sliding groove body (9);

The rotary cylinder body (12) is fixedly connected with the rotary cylinder body (12) in each of the two sliding bodies (10);

The rotating shafts (13) are rotatably connected in the two rotating cylinder bodies (12);

the friction wheel (14), the said friction wheel (14) is fixedly connected between two said spindles (13);

And the limiting component (600) is arranged between the inside of the rotary cylinder (12) and the rotary shaft (13).

2. The cable-stayed flexible photovoltaic bracket unit according to claim 1, characterized in that the fixing assembly (100) comprises:

the bottom of the lifting sliding cylinder (2) and the supporting seat (1) are fixedly connected with the connecting plate (6);

The support piece (7), the support piece (7) fixed connection is in two the one end that connecting plate (6) are close.

3. The cable-stayed flexible photovoltaic module according to claim 2, characterized in that the rotation control assembly (300) comprises:

the lifting sliding drums (2) are fixedly connected with the rotating frames (15), and fixing rods (16) are fixedly connected in the rotating frames (15);

The mounting plate body (17), the said mounting plate body (17) rotates and connects between two said fixed levers (16);

the rotating sleeve (18) is arranged on the mounting plate body (17) in a penetrating way;

The rotating ring (19), the rotating ring (19) is rotatably connected in the rotating sleeve (18), and rotating pieces are fixedly connected on two sides of the inner wall of the rotating ring (19);

the rotating wheels (20) are rotatably connected in the two rotating pieces, and the rotating wheels (20) are rotatably connected in the two rotating pieces;

the fixed groove body (21), the fixed groove body (21) is fixedly connected to the bottom of the rotating sleeve (18);

And the two guide rollers (22) are longitudinally and rotatably connected in the fixed groove body (21).

4. A cable-stayed flexible photovoltaic bracket unit according to claim 3, characterized in that the cable connection assembly (400) comprises:

The fixed block (23), the said fixed block (23) is fixedly connected to the bottom of the said damper plate (5);

The rotating ring cylinder (24), the rotating ring cylinder (24) is rotatably connected to the fixed block (23), and an opening is formed in the rotating ring cylinder (24);

the friction seat (25), the said friction seat (25) is fixedly connected in the said rotary ring cylinder (24);

the clamping seat (26) is arranged on the rotating ring cylinder (24) in a sliding mode through a fixing screw rod, and a nut is connected to the fixing screw rod in a threaded mode.

5. The cable-stayed flexible photovoltaic module according to claim 4, characterized in that the cable lowering assembly (500) comprises:

The L-shaped frame (27) is fixedly connected to the lifting slide cylinder (2);

the device comprises a mounting frame (28), wherein control wheels (29) are rotatably connected to the upper side and the lower side of the inside of the mounting frame (28), and the circulating steel cable (4) passes through the two control wheels (29);

The mounting seat (30), the bottom of the said mounting frame (28) of fixed connection of the said mounting seat (30), the said mounting seat (30) is connected with said L-shaped frame (27) sliding through the slide bar (31);

the transmission screw (32), transmission screw (32) threaded connection is in the bottom of L type frame (27), transmission screw (32) with mount pad (30) rotation is connected.

6. The cable-stayed flexible photovoltaic module according to claim 5, characterized in that the limiting assembly (600) comprises:

the arc-shaped frame (33), the arc-shaped frame (33) is fixedly connected in the rotary cylinder (12);

The arc-shaped strip (34), one end of the arc-shaped strip (34) is rotatably connected in the arc-shaped frame (33), and an arc-shaped opening is formed in the rotating shaft (13) corresponding to the arc-shaped strip (34);

The rotary seat (35), the rotary seat (35) is in the bottom of arc strip (34) in sliding connection, be provided with damping spring ware two (36) in arc frame (33), the top of damping spring ware two (36) with the rotary seat (35) rotates to be connected.

7. A diagonal flexible photovoltaic support comprising a diagonal flexible photovoltaic support unit according to any one of claims 1 to 6.