CN114826117A - Rope pulling type supporting assembly for mounting outer wall of photovoltaic cell panel - Google Patents

Abstract

The invention discloses a rope-pulling type supporting assembly for mounting an outer wall of a photovoltaic cell panel, and relates to the technical field of photovoltaic cell panel application. The invention comprises a pair of support components which are arranged on the outer wall of a building in parallel up and down; the two supporting components are connected through a pair of first pull ropes arranged side by side and a pair of second pull ropes arranged side by side; the first pull rope and the second pull rope are connected through a plurality of bearing assemblies arranged side by side from top to bottom; the upper part of the bearing component is provided with an adjusting component; the adjusting component is provided with a photovoltaic cell panel body; the adjusting component is used for adjusting the elevation angle of the photovoltaic cell panel body. The photovoltaic solar panel mounting structure is reasonable in structural design and high in use stability, effectively improves the mounting quantity of the photovoltaic solar panel bodies, and has high market application value.

Description

Rope pulling type supporting assembly for mounting outer wall of photovoltaic cell panel

Technical Field

The invention belongs to the technical field of photovoltaic cell panel application, and particularly relates to a rope-pulling type supporting assembly for mounting an outer wall of a photovoltaic cell panel.

Background

Solar energy is a pollution-free renewable energy source, and with the development of photovoltaic photoelectric technology, the solar energy conversion efficiency is continuously improved, and the utilization of solar energy is more and more emphasized by people. The photovoltaic cell panel is a device which directly or indirectly converts solar radiation energy into electric energy through a photoelectric effect or a photochemical effect by absorbing sunlight, and is a more energy-saving and environment-friendly green product compared with a common battery and a recyclable rechargeable battery.

At present, a photovoltaic cell panel is generally installed on the ground, a lake surface or a building top layer when in application, and for the installation and use of the photovoltaic cell panel on the building top layer, although the photovoltaic cell panel can be ensured to have a good lighting effect, as other equipment such as a ventilation device and the like are generally installed on the building top layer, the occupied area of the photovoltaic cell panel is greatly reduced, the installation number of the photovoltaic cell panel is too small, and the application value of the photovoltaic cell panel is not enough to be obviously reflected; meanwhile, a device capable of installing the photovoltaic cell panel on the outer wall surface of the building does not appear in the current market. Therefore, there is a need to research a rope-pulling type supporting assembly for mounting an outer wall of a photovoltaic cell panel so as to solve the above problems.

Disclosure of Invention

The invention aims to provide a rope pulling type supporting assembly for mounting an outer wall of a photovoltaic cell panel, and aims to solve the problems in the background technology.

In order to solve the technical problems, the invention is realized by the following technical scheme:

the invention relates to a rope pulling type supporting assembly for mounting a photovoltaic cell panel outer wall, which comprises a pair of supporting assemblies which are mounted on a building outer wall in parallel up and down; the two supporting components are connected through a pair of first pull ropes arranged side by side and a pair of second pull ropes arranged side by side; the first pull rope and the second pull rope are connected through a plurality of bearing assemblies arranged side by side from top to bottom; the upper part of the bearing component is provided with an adjusting component; the adjusting assembly is provided with a photovoltaic cell panel body; the adjusting component is used for adjusting the elevation angle of the photovoltaic cell panel body.

As a preferred technical solution of the present invention, the supporting component includes a horizontally disposed supporting slat; the supporting lathes are in U-shaped structures; the two ends of the supporting lath are integrally provided with a vertically arranged mounting part; the mounting part is connected to the outer wall of the building through a bolt; a reinforcing rib is connected between the mounting part and the side arm of the supporting lath; the two side arms of the supporting lath are connected through a connecting lath; the connecting lath is connected to the outer wall of the building through a bolt.

As a preferred technical scheme of the invention, the bearing assembly comprises a pair of bearing plates which are respectively vertically arranged below two side arms of a supporting lath; one side edge of the bearing plate close to the building outer wall is fixed with the first pull rope; one side edge of the bearing plate, which is far away from the building outer wall, is fixed with the second pull rope; an accommodating frame is arranged between the two bearing plates; the two opposite sides of the accommodating frame are both vertically provided with a first positioning plate; a pair of guide rods arranged side by side are inserted into one side surface of the first positioning plate in a sliding mode along the length direction of the connecting lath; one end of each guide rod is vertically fixed on one side face of the adjacent bearing plate; the other end of the guide rod is vertically fixed on the lateral edge of the containing frame; a driving cylinder is rotatably inserted between the edges at the two sides of the accommodating frame; screw rods are in threaded fit in the two ports of the driving cylinder; the outer end of the screw rod is vertically fixed on one side surface of the adjacent first positioning plate; two the relative medial surface of first locating plate all is provided with a plurality of first gerar grinding side by side.

As a preferred technical scheme of the invention, a second positioning plate parallel to the connecting lath is vertically arranged between the two first positioning plates; two side edges of the second positioning plate are respectively connected with the two first positioning plates through a first transmission rod; and a plurality of second grinding teeth are arranged on one side surface of the second positioning plate far away from the containing frame side by side.

As a preferred technical solution of the present invention, a plurality of the bearing assemblies are connected by a first driving assembly; the first driving assembly comprises a pair of first rollers which are respectively and rotatably arranged on the two connecting laths; the two first rollers are connected through a first chain; a plurality of first chain wheels corresponding to the driving barrel are meshed with the first chain side by side; the first chain wheel is fixedly sleeved on the periphery of the driving cylinder.

As a preferred technical scheme of the invention, the adjusting assembly comprises a pair of driving shafts which are respectively and rotatably connected to the opposite outer side surfaces of the two bearing plates; a second transmission rod is fixed at one end of the driving shaft in the radial direction; a first sliding sleeve is slidably sleeved on the second transmission rod; one surface of the first sliding sleeve is rotatably connected with a vertically arranged lifting rod; a second sliding sleeve corresponding to a second pull rope is vertically fixed at the upper end and the lower end of the lifting rod; the second sliding sleeve is slidably sleeved on the second pull rope; the two second sliding sleeves positioned at the same horizontal position are connected through a first movable rod; the first movable rod is rotatably inserted on the lower edge of the photovoltaic cell panel body; a second movable rod is arranged above the first movable rod in parallel; support sleeves are vertically fixed at two ends of the second movable rod; the support sleeve is fixedly sleeved on the periphery of the second pull rope; a third transmission rod is rotatably connected to the second movable rod; one end of the third transmission rod is rotatably connected to the upper edge of the photovoltaic cell panel body.

As a preferred technical solution of the present invention, a plurality of the adjusting assemblies are connected through a second driving assembly; the second driving assembly comprises two pairs of second rollers which are respectively and rotatably arranged on the two side arms of the supporting lath and a pair of second chains which are respectively and vertically arranged on the two opposite sides of the bearing assembly; two ends of the second chain are respectively connected to the two second rollers positioned on the same side; a plurality of second chain wheels corresponding to the driving shaft are meshed on the second chain; the second chain wheel is fixedly sleeved on the periphery of the driving shaft.

The invention has the following beneficial effects:

according to the invention, the supporting assembly, the first pull rope, the second pull rope and the bearing assembly are used as supporting matrixes, the bearing assembly is used for installing the adjusting assembly for adjusting the elevation angle of the photovoltaic cell panel body, and the photovoltaic cell panel body is installed on the adjusting assembly, so that the photovoltaic cell panel body is arranged on the outer wall of a building, the installation number of the photovoltaic cell panel body is effectively increased, the application value of the photovoltaic cell panel body is obviously increased, and the photovoltaic cell panel is suitable for popularization and application.

Of course, it is not necessary for any product in which the invention is practiced to achieve all of the above-described advantages at the same time.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings used in the description of the embodiments will be briefly introduced below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and it is obvious for those skilled in the art that other drawings can be obtained according to the drawings without creative efforts.

Fig. 1 is a schematic structural diagram of a rope-pulling type support assembly for mounting a photovoltaic cell panel outer wall according to the invention.

Fig. 2 is a schematic structural diagram of the connection among the support assembly, the first pull rope and the second pull rope according to the present invention.

Fig. 3 is a schematic structural view of the connection between the support assembly and the carrying assembly of the present invention.

Fig. 4 is a schematic structural diagram of the support assembly of the present invention.

Fig. 5 is a schematic structural diagram of the load bearing assembly of the present invention.

Fig. 6 is a schematic structural view illustrating the connection between the first positioning plate and the second positioning plate according to the present invention.

Fig. 7 is a schematic structural view of an adjusting assembly of the present invention.

Fig. 8 is a front view of the structure of fig. 7.

Fig. 9 is a schematic view illustrating the installation of the rope-pulling type support assembly for photovoltaic cell panel outer wall installation on a building outer wall.

In the drawings, the components represented by the respective reference numerals are listed below:

a-an outer wall bearing column, b-a windowsill, 1-a support assembly, 2-a first pull rope, 3-a second pull rope, 4-a bearing assembly, 5-an adjusting assembly, 6-a photovoltaic cell panel body, 7-a first driving assembly, 8-a second driving assembly, 101-a support lath, 102-a mounting part, 103-a reinforcing rib, 104-a connecting lath, 401-a bearing plate, 402-a containing frame, 403-a first positioning plate, 404-a guide rod, 405-a driving cylinder, 406-a screw rod, 407-a tensioning spring, 408-a second positioning plate, 409-a first driving rod, 501-a driving shaft, 502-a second driving rod, 503-a first sliding sleeve, 504-a lifting rod, 505-a second sliding sleeve, 506-a first movable rod, 507-second movable bar, 508-support sleeve, 509-third transmission bar, 701-first roller, 702-first chain, 703-first sprocket, 801-second roller, 802-second chain, 803-second sprocket, 4031-first grinding tooth, 4081-second grinding tooth.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

The first embodiment is as follows:

referring to fig. 1, the invention relates to a rope-pull type supporting assembly for mounting a photovoltaic cell panel outer wall, wherein a building outer wall comprises a plurality of vertically arranged outer wall bearing columns a, and a windowsill b is arranged between two adjacent outer wall bearing columns a; the rope pulling type supporting component comprises a pair of supporting components 1 which are arranged on the outer wall of the building in parallel up and down; the two supporting components 1 are connected through a pair of first pull ropes 2 arranged side by side and a pair of second pull ropes 3 arranged side by side; the first pull ropes 2 are arranged between the second pull ropes 3 and the building outer wall, and the two first pull ropes 2 are respectively arranged on two opposite sides of the outer wall bearing column a and the two second pull ropes 3 are respectively arranged on two opposite sides of the outer wall bearing column a; the first pull rope 2 and the second pull rope 3 are both steel wire ropes; the first pull rope 2 and the second pull rope 3 are connected through a plurality of bearing components 4 which are arranged side by side from top to bottom; the bearing component 4 is detachably arranged on the outer wall bearing column a; the upper part of the bearing component 4 is provided with an adjusting component 5; the adjusting component 5 is provided with a photovoltaic cell panel body 6; the adjusting assembly 5 is used for adjusting the elevation angle of the photovoltaic cell panel body 6. As shown in fig. 9, during installation, two support assemblies 1 are respectively installed at the upper end and the lower end of the same outer wall bearing column a, and then a bearing assembly 4 is detachably installed on the outer wall bearing column a, so as to establish a stable support matrix for a photovoltaic cell panel body 6; when the photovoltaic solar panel is used, the elevation angle of the photovoltaic solar panel body 6 is adjusted through the adjusting assembly 5, so that the power generation rate of the photovoltaic solar panel body 6 is ensured.

The second embodiment is as follows:

on the basis of the first embodiment, as shown in fig. 2 to 4, the supporting component 1 comprises a horizontally arranged supporting lath 101; the supporting lath 101 is in a U-shaped structure; the supporting lath 101 is coated on the periphery of the bearing column a of the outer wall; the two ends of the supporting lath 101 are integrally formed with a vertically arranged mounting part 102; the mounting portion 102 is a plate structure; the mounting part 102 is connected to the outer wall of the building through bolts; a reinforcing rib 103 is connected between the mounting part 102 and a side arm of the supporting lath 101; the two side arms of the supporting lath 101 are fixedly connected through a connecting lath 104; the connecting battens 104 are connected to the building outer wall through bolts; the ends of the first and second ropes 2 and 3 are fixedly connected to the side arms of the supporting strip 101. In use, the mounting portion 102 and the connecting batten 104 are connected to the outer surface of the building outer wall by expansion bolts, so that the support assembly 1 can be stably connected to the building outer wall.

The third concrete embodiment:

on the basis of the second embodiment, as shown in fig. 3 and fig. 5-6, the carrying assembly 4 includes a pair of carrying plates 401 vertically disposed below the two side arms of the supporting slats 101; the two bearing plates 401 are respectively arranged on two opposite sides of the outer wall bearing column a; one side edge of the bearing plate 401 close to the building outer wall is fixed with the first pull rope 2; one side edge of the bearing plate 401, which is far away from the building outer wall, is fixed with the second pull rope 3; an accommodating frame 402 is arranged between the two bearing plates 401; the accommodating frame 402 is arranged on the front side of the outer wall bearing column a; the opposite sides of the accommodating frame 402 are vertically provided with first positioning plates 403; the first positioning plate 403 is arranged between the bearing plate 401 and the outer wall bearing column a; a pair of guide rods 404 arranged side by side are slidably inserted into one side surface of the first positioning plate 403 along the length direction of the connecting batten 104; one end of the guide rod 404 is vertically fixed on one side surface of the adjacent bearing plate 401; the other end of the guide bar 404 is vertically fixed on the side edge of the accommodating frame 402; a driving cylinder 405 is rotatably inserted between the two side edges of the accommodating frame 402; screw rods 406 are in threaded fit with the two ports of the driving barrel 405; the thread directions on the two ends of the driving cylinder 405 are opposite; the outer end of the screw 406 is vertically fixed on one side surface of the adjacent first positioning plate 403; a plurality of first grinding teeth 4031 made of elastic rubber are fixed on the opposite inner side surfaces of the two first positioning plates 403 in parallel. When the outer wall bearing column a is used, the driving cylinder 405 is rotated to drive the two screws 406 to synchronously move relative to each other or move back to back, so that the two first positioning plates 403 are driven to synchronously move relative to each other or move back to back, the two first positioning plates 403 can be respectively close to the two opposite side surfaces of the outer wall bearing column a, finally the two opposite side surfaces of the two first positioning plates 403 are driven to respectively cling to the two opposite side surfaces of the outer wall bearing column a, the friction force between the first positioning plates 403 and the outer wall bearing column a can be increased by using the first grinding teeth 4031, and the first positioning plates 403 can be guaranteed to stably cling to the outer wall bearing column a.

As shown in fig. 5-6, a second positioning plate 408 parallel to the connecting lath 104 is vertically disposed between the two first positioning plates 403; two side edges of the second positioning plate 408 are respectively connected with the two first positioning plates 403 through a first transmission rod 409; a plurality of second grinding teeth 4081 made of elastic rubber are fixed side by side on a side of the second positioning plate 408 away from the accommodating frame 402. When the two first positioning plates 403 are close to the two opposite side surfaces of the outer wall bearing post a, the first transmission rod 409 drives the second positioning plate 408 to be close to the front side surface of the outer wall bearing post a, and when the two opposite side surfaces of the two first positioning plates 403 are respectively attached to the two opposite side surfaces of the outer wall bearing post a, one side surface of the second positioning plate 408, which is far away from the accommodating frame 402, is also attached to the front side surface of the outer wall bearing post a, and the second grinding teeth 4081 can also increase the friction between the second positioning plate 408 and the outer wall bearing post a, so that the second positioning plate 408 can be ensured to be stably attached to the outer wall bearing post a, and the installation stability of the whole device on the outer wall of a building is effectively improved.

As shown in fig. 2-6, the plurality of bearing assemblies 4 are connected with each other through a first driving assembly 7; the first driving assembly 7 comprises a pair of first rollers 701 rotatably mounted on the two connecting strips 104; one end of a wheel shaft of the first roller 701 is fixed on an output shaft of a first driving motor; the first driving motor is fixed on the connecting batten 104; the two first rollers 701 are connected through a first chain 702; a plurality of first chain wheels 703 corresponding to the driving cylinder 405 are engaged with the first chain 702 side by side; the first sprocket 703 is fixedly sleeved on the outer circumference of the driving cylinder 405. During the use, realize first chain 702 upward movement or downstream through rotating first running roller 701 to drive a drive section of thick bamboo 405 through first sprocket 703 and rotate, and then realize that two screws 406 are synchronous relative motion or back of the body motion, can effectively adjust carrier assembly 4.

The fourth concrete embodiment:

on the basis of the third embodiment, as shown in fig. 3 and fig. 7-8, the adjusting assembly 5 includes a pair of driving shafts 501 rotatably connected to the opposite outer sides of the two bearing plates 401; a second transmission rod 502 is fixed at one end of the driving shaft 501 in the radial direction; the second transmission rod 502 is disposed on a side of the loading plate 401 away from the accommodating frame 402; a first sliding sleeve 503 is slidably sleeved on the second transmission rod 502; a lifting rod 504 which is vertically arranged is rotatably connected to one surface of the first sliding sleeve 503; the lifting rod 504 is in a [ -shaped structure; a second sliding sleeve 505 corresponding to the second pull rope 3 is vertically fixed at the upper end and the lower end of the lifting rod 504; the second sliding sleeve 505 is slidably sleeved on the second pull rope 3; the two second sliding sleeves 505 which are positioned at the same horizontal position are connected through a first movable rod 506; the first movable rods 506 are rotatably inserted on the lower edges of the photovoltaic cell panel bodies 6, and the first movable rods 506 are arranged on the pair of photovoltaic cell panel bodies 6 side by side; the two photovoltaic cell panel bodies 6 are arranged on two opposite sides of the first chain 702, and the upper edges of the two photovoltaic cell panel bodies 6 are fixed through connecting rods; the first chain 702 is disposed between the first movable bar 506 and the accommodating frame 402; a second movable rod 507 is arranged above the first movable rod 506 in parallel; support sleeves 508 are vertically fixed at both ends of the second movable rod 507; the support sleeve 508 is fixedly sleeved on the periphery of the second pull rope 3; a third transmission rod 509 is rotatably connected to the second movable rod 507; one end of the third driving rod 509 is rotatably connected to the upper edge of the photovoltaic cell panel body 6. When the photovoltaic cell panel elevation adjusting device is used, the driving shaft 501 is rotated to drive the second transmission rod 502 to rotate, the first sliding sleeve 503 is promoted to drive the second sliding sleeve 505 to slide on the second stay cord 3 through the lifting rod 504, and the third transmission rod 509 is respectively connected with the second movable rod 507 and the photovoltaic cell panel body 6 in a rotating mode, so that the elevation adjustment of the photovoltaic cell panel body 6 can be achieved.

As shown in fig. 2-3 and fig. 7-8, the plurality of adjusting assemblies 5 are connected with each other through a second driving assembly 8; the second driving assembly 8 comprises two pairs of second rollers 801 rotatably mounted on the arms at the two sides of the supporting lath 101 respectively and a pair of second chains 802 vertically arranged on the two opposite sides of the bearing assembly 4 respectively; one end of a wheel shaft of the second roller wheel 801 is coaxially fixed on an output shaft of the second driving motor; the second driving motor is fixed on the side arm of the supporting lath 101; two ends of the second chain 802 are respectively connected to the two second rollers 801 located on the same side; a plurality of second chain wheels 803 corresponding to the driving shaft 501 are engaged with the second chain 802; the second sprocket 803 is fixedly sleeved on the outer circumference of the driving shaft 501. During the use, realize second chain 802 upward movement or downstream through rotating second sprocket 801 to drive shaft 501 through second sprocket 803 and rotate, and then make first sliding sleeve 503 drive second sliding sleeve 505 through lifter 504 and slide on second stay cord 3, can effectively adjust the angle of elevation of photovoltaic cell panel body 6.

The preferred embodiments of the invention disclosed above are intended to be illustrative only. The preferred embodiments are not intended to be exhaustive or to limit the invention to the precise embodiments disclosed. Obviously, many modifications and variations are possible in light of the above teaching. The embodiments were chosen and described in order to best explain the principles of the invention and the practical application, to thereby enable others skilled in the art to best utilize the invention. The invention is limited only by the claims and their full scope and equivalents.

Claims (9)

1. The rope-pulling type supporting assembly for mounting the outer wall of the photovoltaic cell panel comprises a pair of supporting assemblies (1) which are mounted on the outer wall of a building in parallel up and down; the method is characterized in that:

the two supporting components (1) are connected through a pair of first pull ropes (2) arranged side by side and a pair of second pull ropes (3) arranged side by side; the first pull rope (2) and the second pull rope (3) are connected through a plurality of bearing components (4) which are arranged side by side from top to bottom; the upper part of the bearing component (4) is provided with an adjusting component (5); the adjusting assembly (5) is provided with a photovoltaic cell panel body (6); the adjusting assembly (5) is used for adjusting the elevation angle of the photovoltaic cell panel body (6).

2. Rope-pull type support assembly for the installation of external walls of photovoltaic panels according to claim 1, characterised in that said support assembly (1) comprises horizontally arranged support battens (101); the supporting lath (101) is of a U-shaped structure; both ends of the supporting lath (101) are integrally formed with vertically arranged mounting parts (102); the mounting part (102) is connected to the outer wall of the building through a bolt; a reinforcing rib (103) is connected between the mounting part (102) and a side arm of the supporting lath (101); the two side arms of the supporting lath (101) are connected through a connecting lath (104); the connecting battens (104) are connected to the building outer wall through bolts.

3. The rope-pull type support assembly for the installation of the outer wall of the photovoltaic cell panel is characterized in that the bearing assembly (4) comprises a pair of bearing plates (401) which are respectively vertically arranged below two side arms of a support batten (101); one side edge of the bearing plate (401), which is close to the building outer wall, is fixed with the first pull rope (2); one side edge of the bearing plate (401), which is far away from the building outer wall, is fixed with the second pull rope (3); an accommodating frame (402) is arranged between the two bearing plates (401); two opposite sides of the accommodating frame (402) are vertically provided with first positioning plates (403); a pair of guide rods (404) arranged side by side is inserted into one side surface of the first positioning plate (403) in a sliding mode along the length direction of the connecting batten (104); one end of the guide rod (404) is vertically fixed on one side surface of the adjacent bearing plate (401); the other end of the guide rod (404) is vertically fixed on the lateral edge of the accommodating frame (402); a driving cylinder (405) is rotatably inserted between the two side edges of the accommodating frame (402); a screw (406) is in threaded fit in each of two ports of the driving cylinder (405); the outer end of the screw rod (406) is vertically fixed on one side surface of the adjacent first positioning plate (403).

4. The rope-pull type support assembly for the installation of the outer wall of the photovoltaic cell panel is characterized in that a plurality of first grinding teeth (4031) are arranged on the opposite inner side surfaces of the two first positioning plates (403) side by side.

5. The rope-pull type support assembly for the installation of the outer wall of the photovoltaic cell panel is characterized in that a second positioning plate (408) parallel to the connecting batten (104) is vertically arranged between the two first positioning plates (403); two side edges of the second positioning plate (408) are respectively connected with the two first positioning plates (403) through a first transmission rod (409).

6. The rope-pull type support assembly for the installation of the outer wall of the photovoltaic cell panel is characterized in that a plurality of second grinding teeth (4081) are arranged on one side of the second positioning plate (408) far away from the accommodating frame (402) side by side.

7. The rope-pull type support assembly for the installation of the outer wall of the photovoltaic cell panel is characterized in that a plurality of bearing assemblies (4) are connected through a first driving assembly (7); the first driving component (7) comprises a pair of first rollers (701) which are respectively and rotatably arranged on the two connecting laths (104); the two first rollers (701) are connected through a first chain (702); a plurality of first chain wheels (703) corresponding to the driving barrel (405) are meshed with the first chain (702) side by side; the first chain wheel (703) is fixedly sleeved on the periphery of the driving cylinder (405).

8. The rope-pull type support assembly for the installation of the outer wall of the photovoltaic cell panel is characterized in that the adjusting assembly (5) comprises a pair of driving shafts (501) which are respectively and rotatably connected to the opposite outer side surfaces of the two bearing plates (401); a second transmission rod (502) is fixed at one end of the driving shaft (501) in the radial direction; a first sliding sleeve (503) is slidably sleeved on the second transmission rod (502); one surface of the first sliding sleeve (503) is rotatably connected with a lifting rod (504) which is vertically arranged; a second sliding sleeve (505) corresponding to a second pull rope (3) is vertically fixed at the upper end and the lower end of the lifting rod (504); the second sliding sleeve (505) is sleeved on the second pull rope (3) in a sliding manner; the two second sliding sleeves (505) which are positioned at the same horizontal position are connected through a first movable rod (506); the first movable rod (506) is inserted on the lower edge of the photovoltaic cell panel body (6) in a rotating mode; a second movable rod (507) is arranged above the first movable rod (506) in parallel; two ends of the second movable rod (507) are vertically fixed with support sleeves (508); the support sleeve (508) is fixedly sleeved on the periphery of the second pull rope (3); a third transmission rod (509) is rotatably connected to the second movable rod (507); one end of the third transmission rod (509) is rotatably connected to the upper edge of the photovoltaic cell panel body (6).

9. The rope-pull type support assembly for the installation of the outer wall of the photovoltaic cell panel is characterized in that a plurality of adjusting assemblies (5) are connected through a second driving assembly (8); the second driving assembly (8) comprises two pairs of second rollers (801) which are respectively and rotatably arranged on the arms at the two sides of the supporting lath (101) and a pair of second chains (802) which are respectively and vertically arranged at the two opposite sides of the bearing assembly (4); two ends of the second chain (802) are respectively connected to two second rollers (801) positioned on the same side; a plurality of second chain wheels (803) corresponding to the driving shafts (501) are meshed on the second chain (802); the second chain wheel (803) is fixedly sleeved on the periphery of the driving shaft (501).

Images