CN219689142U - A lifting device for photovoltaic panels used in photovoltaic ceiling construction - Google Patents

Abstract

The utility model discloses a photovoltaic panel lifting device for photovoltaic ceiling construction, which comprises a lifting frame, wherein lifting units are correspondingly arranged on the lifting frame, adsorption units are correspondingly arranged on the lifting units, the photovoltaic panel is adsorbed and fixed by the adsorption units, the adsorption units are driven to move up and down by the lifting units, the lifting frame consists of two guide parts and a top connecting piece, and the two guide parts are symmetrically and parallelly distributed at intervals. According to the utility model, the number of the guide rails is increased according to the height of the ceiling, the dynamic adjustment of the lifting height of the lifting frame is realized, the rapid lifting operation of the photovoltaic panel can be realized, the safety, time and labor are saved, the back of the photovoltaic panel can be adsorbed and fixed by means of the adsorption unit, the lifting operation of the photovoltaic panel is realized under the cooperation of the lifting unit, the adsorption position of the adsorption unit can be dynamically adjusted, the photovoltaic panel with different sizes can be adapted for adjustment and use, and the operation is flexible.

Description

A photovoltaic panel lifting device for photovoltaic ceiling construction

Technical field

The utility model relates to the technical field related to photovoltaic equipment construction, and is specifically a photovoltaic panel lifting device used in photovoltaic ceiling construction.

Background technique

Photovoltaic power generation system refers to a power generation system that directly converts light energy into electrical energy without going through a thermal process. Its main components are solar cells, batteries, controllers and inverters. It is characterized by high reliability, long service life, no environmental pollution, and the ability to generate electricity independently and operate in parallel to the grid;

A solar roof is to install a solar power generation device on the top of a house, using solar photovoltaic technology to generate electricity in urban and rural buildings to achieve energy conservation and emission reduction goals. When constructing photovoltaic equipment on the roof, the photovoltaic panels need to be transported to the roof for assembly. However, the current handling methods of photovoltaic panels have the following shortcomings.

At present, most of the photovoltaic panels required for the ceiling construction process are carried manually, or manually dragged upward using a pull rope. This operation method is less safe, time-consuming and labor-intensive, and it is easy to cause safety hazards during the operation. accidents, and it is easy to cause damage to photovoltaic panels during operation, increasing construction costs.

Utility model content

The purpose of this utility model is to provide a photovoltaic panel lifting device for photovoltaic ceiling construction to solve the problems raised in the above background technology.

In order to achieve the above purpose, the present utility model provides the following technical solution: a photovoltaic panel lifting device for photovoltaic ceiling construction, including a lifting frame, a lifting unit is installed on the lifting frame, and an adsorption unit is installed on the lifting unit. The adsorption unit is used to adsorb and fix the photovoltaic panels, and the lifting unit is used to drive the adsorption unit to move up and down.

As a further preference of this technical solution, the lifting frame is composed of two guide parts and a top connector. The two guide parts are symmetrically distributed in parallel and spaced apart. The top connector is correspondingly installed on the top of the two guide parts, and on both sides. Reinforcements are installed between the guide parts.

As a further preferred embodiment of this technical solution, the guide part is made up of multiple guide rails, and the two ends of the reinforcement are detachably connected to the guide rails of the two guide parts respectively, and are directed toward the top and bottom ends of the guide rails on both sides. There are connecting pieces extending outward, and the connecting pieces are locked and fixed by bolts between adjacent guide rails.

As a further preferred embodiment of this technical solution, a connecting seat is welded to the bottommost guide rail, and through holes are drilled through the four corners of the connecting seat.

As a further preference of this technical solution, the lifting unit includes an electric hoist installed on the top connector, a slider is slidably installed in the guide rail, and a linkage platform is installed between the two guide parts, and the linkage platform is connected to the The slide block is fixedly connected, a lifting ring is welded on the top of the linkage platform, and the output end of the electric hoist is connected correspondingly to the lifting ring.

As a further preference of this technical solution, an adjustment area is provided at the front end of the linkage platform, and a threaded rod is installed for rotation in the adjustment area. A servo motor is installed on one side of the linkage platform, and the output end of the servo motor corresponds to the threaded rod. Transmission connection, and two threaded blocks are installed symmetrically and slidingly in the adjustment area, and the threaded blocks are correspondingly set on the outside of the threaded rod, and the threaded lines in the two threaded blocks are opposite. When the threaded rod rotates, the two threaded blocks are linked to each other. Move closer and move away from each other.

As a further preferred embodiment of this technical solution, the adsorption unit includes two electric modules symmetrically and slidingly installed on the front end of the linkage table. The electric modules are connected to the threaded block, and a No. 1 vacuum is installed at the output end of the electric module. There is a No. 2 vacuum electric suction cup installed at the front and bottom of the electric module. The No. 1 vacuum electric suction cup and the No. 2 vacuum electric suction cup can be used to adsorb and fix the photovoltaic panels.

The utility model provides a photovoltaic panel lifting device for photovoltaic ceiling construction, which has the following beneficial effects:

(1) This utility model is provided with an adsorption unit to place the photovoltaic panel in contact with the No. 1 vacuum electric chuck and the No. 2 vacuum electric suction cup and realize adsorption and fixation. The electric hoist is started to realize the lifting operation of the photovoltaic panel and the electric mold is started. group, thereby realizing the adjustment of the adsorption distance between the two, and by starting the servo motor, the two electric modules can be synchronously driven to follow each other closer to each other and away from each other, thereby further expanding the adsorption space of the adsorption unit and being able to adapt to different sizes. The photovoltaic panels are used for dynamic adjustment.

(2) When the lifting frame of this utility model is assembled, the adjacent guide rails are brought close to each other, and then the connecting pieces on the guide rails are locked with bolts, thereby realizing rapid connection of the guide rails, so that the lifting frame can obtain different height intervals, which can be realized Lifting operations at different heights, and reinforcements installed between the guide rails, improve the stability of the lifting frame.

Description of the drawings

Figure 1 is a schematic diagram of the overall structure of the utility model;

Figure 2 is a schematic diagram of the installation of the adsorption unit of the present utility model on the lifting frame;

Figure 3 is a schematic diagram of the distribution of the lifting unit and adsorption unit of the present utility model;

Figure 4 is a schematic structural diagram of the adsorption unit of the present utility model;

Figure 5 is a schematic structural diagram of the lifting unit of the present utility model;

Figure 6 is a schematic diagram of guide rail separation according to the present invention.

In the picture: 1. Lifting frame; 2. Top connector; 3. Reinforcement piece; 4. Guide rail; 5. Connecting piece; 6. Connecting seat; 7. Electric hoist; 8. Slider; 9. Linkage table; 10. Lifting ring; 11. Adjustment area; 12. Threaded rod; 13. Servo motor; 14. Threaded block; 15. Electric module; 16. No. 1 vacuum electric chuck; 17. No. 2 vacuum electric chuck.

Detailed ways

The technical solutions in the embodiments of the present utility model will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present utility model.

The utility model provides a technical solution: as shown in Figures 1, 3 and 6, in this embodiment, a photovoltaic panel lifting device for photovoltaic ceiling construction includes a lifting frame 1, and a lifting frame is installed on the lifting frame 1. unit, and an adsorption unit is installed correspondingly on the lifting unit. The adsorption unit is used to adsorb and fix the photovoltaic panels, and the lifting unit is used to drive the adsorption unit to move up and down;

The lifting frame 1 is composed of two guide parts and a top connector 2. The two guide parts are symmetrically spaced and distributed in parallel. The top connector 2 is correspondingly installed on the top of the two guide parts, and a reinforcement 3 is installed between the two guide parts. , the guide part is made up of multiple guide rails 4, the two ends of the reinforcement 3 are detachably connected to the guide rails 4 of the two guide parts, and there are connecting pieces 5 extending outward on both sides of the top and bottom ends of the guide rails 4, correspondingly The connecting pieces 5 are locked and fixed by bolts between the adjacent guide rails 4, and a connecting seat 6 is welded to the bottom guide rail 4, and through holes are drilled through the four corners of the connecting seat 6;

Among them, when splicing the lifting frame 1: bring the adjacent guide rails 4 close to each other, and then use bolts to lock the connecting pieces 5 on the guide rails 4, thereby realizing a quick connection to the guide rails 4, so that the lifting frame 1 can obtain different height intervals. , can realize lifting operations of different heights, and reinforcements 3 are installed between the guide rails 4, which improves the stability of the lifting frame 1.

As shown in Figure 5, the lifting unit includes an electric hoist 7 installed on the top connector 2, a slider 8 is slidably installed in the guide rail 4, and a linkage platform 9 is installed between the two guide parts, and the linkage platform 9 Fixedly connected to the slider 8, a lifting ring 10 is welded to the top of the linkage platform 9, and the output end of the electric hoist 7 is connected correspondingly to the lifting ring 10;

Preferably, an adjustment area 11 is provided at the front end of the linkage platform 9, and a threaded rod 12 is installed for rotation in the adjustment area 11. A servo motor 13 is installed on one side of the linkage platform 9, and the output end of the servo motor 13 is connected to the threaded rod 12 for transmission, and Two threaded blocks 14 are installed symmetrically and slidingly in the adjustment area 11, and the threaded blocks 14 are correspondingly sleeved on the outside of the threaded rod 12, and the threaded patterns in the two threaded blocks 14 are opposite. When the threaded rod 12 rotates, the two threaded blocks are linked. 14. Make moves toward each other and away from each other.

As shown in Figures 2 and 4, the adsorption unit includes two electric modules 15 symmetrically and slidingly installed on the front end of the linkage platform 9. The electric modules 15 are connected to the threaded block 14, and a No. 1 number is installed at the output end of the electric module 15. The vacuum electric chuck 16 is equipped with a No. 2 vacuum electric chuck 17 at the front and bottom of the electric module 15. The No. 1 vacuum electric chuck 16 and the No. 2 vacuum electric chuck 17 can be used to adsorb and fix the photovoltaic panels;

Among them, when adsorbing and fixing the photovoltaic panels: by providing an adsorption unit, the photovoltaic panels are in close contact with the No. 1 vacuum electric chuck 16 and the No. 2 vacuum electric chuck 17 to achieve adsorption and fixation. The adsorption method of the lifting device adopts the No. 1 vacuum electric chuck. The vacuum electric suction cup 16 and the No. 2 vacuum electric suction cup 17 are vacuum-adsorbed and fixed to ensure the stability of the photovoltaic panels and at the same time protect the photovoltaic panels, which facilitates subsequent lifting of the photovoltaic panels. Then, with the assistance of the lifting unit, the electric hoist is started. 7. Pull the linkage platform 9 where the photovoltaic panel is located to follow and rise, thereby realizing the lifting operation of the photovoltaic panel, and during the lifting process, the cooperation of the guide rail 4 and the slider 8 can play a guiding role in the lifting of the photovoltaic panel to ensure In order to ensure its stability, when it is necessary to adjust the adsorption positions of the No. 1 vacuum electric chuck 16 and the No. 2 vacuum electric chuck 17, it is only necessary to start the electric module 15 correspondingly, so that the No. 1 vacuum electric chuck 16 and the No. 2 vacuum electric chuck 17 Approach or move away from each other, thereby realizing the adjustment of the adsorption distance between the two, and by starting the servo motor 13, the threaded rod 12 can be driven to rotate, and the two electric modules 15 can be synchronously driven to follow each other closer and farther away, thus further expanding the The adsorption space of the adsorption unit can be adapted to photovoltaic panels of different sizes for dynamic adjustment.

The utility model provides a photovoltaic panel lifting device for photovoltaic ceiling construction. The specific working principle is as follows: during operation, the lifting frame 1 is first installed in the working position, and the number of guide rails 4 is increased according to the height of the ceiling to realize the lifting frame 1 The lifting height is dynamically adjusted, and the lifting frame 1 is easy to disassemble and assemble, making it convenient for workers to use, thereby ensuring a stable lifting range for subsequent photovoltaic panels. The photovoltaic panels can then be adsorbed and fixed on the back with the help of the adsorption unit, and at the same time, with the cooperation of the lifting unit Down, pull the adsorption unit and the photovoltaic panel to follow and lift up and down, thereby realizing the lifting work of the photovoltaic panel, and the adsorption unit can dynamically adjust its upper adsorption position, and can be adapted to photovoltaic panels of different sizes for adjustment and operation. Flexible and good adsorption stability to photovoltaic panels.

Although the embodiments of the present invention have been shown and described, those of ordinary skill in the art will understand that various changes and modifications can be made to these embodiments without departing from the principles and spirit of the present invention. , substitutions and modifications, the scope of the present invention is defined by the appended claims and their equivalents.

Claims (7)

1. A be used for photovoltaic ceiling construction photovoltaic board hoisting device, includes crane (1), its characterized in that: lifting units are correspondingly arranged on the lifting frames (1), adsorption units are correspondingly arranged on the lifting units, the photovoltaic panels are adsorbed and fixed by the adsorption units, and the adsorption units are driven to move up and down by the aid of the lifting units.

2. The lifting device for photovoltaic panels used in photovoltaic ceiling construction according to claim 1, characterized in that: the lifting frame (1) consists of two guide parts and a top connecting piece (2), wherein the two guide parts are symmetrically and parallelly distributed at intervals, the top connecting piece (2) is correspondingly arranged at the tops of the two guide parts, and a reinforcing piece (3) is arranged between the two guide parts.

3. The lifting device for photovoltaic panels used in construction of a photovoltaic ceiling according to claim 2, characterized in that: the guide parts are formed by splicing a plurality of guide rails (4), two ends of the reinforcing piece (3) are detachably connected with the guide rails (4) of the two guide parts respectively, connecting pieces (5) are outwards extended from two sides of the top end and the bottom end of each guide rail (4), and the connecting pieces (5) are locked and fixed between the adjacent guide rails (4) through bolts.

4. A photovoltaic panel lifting apparatus for use in a photovoltaic ceiling construction according to claim 3, wherein: and a connecting seat (6) is welded on the bottom-most guide rail (4), and through holes are formed in four corners of the connecting seat (6) in a penetrating manner.

5. The lifting device for photovoltaic panels used in photovoltaic ceiling construction according to claim 1, characterized in that: the lifting unit comprises an electric hoist (7) arranged on a top connecting piece (2), a sliding block (8) is arranged in the guide rail (4) in a sliding mode, a linkage table (9) is arranged between two guide parts, the linkage table (9) is fixedly connected with the sliding block (8), a lifting ring (10) is welded at the top of the linkage table (9), and the output end of the electric hoist (7) is correspondingly connected with the lifting ring (10).

6. The lifting device for photovoltaic panels used in photovoltaic ceiling construction according to claim 5, wherein: the utility model discloses a motor control device for a motor vehicle, including linkage platform (9), threaded rod (12) is installed in linkage platform (9) front end rotation, servo motor (13) are installed to linkage platform (9) one side, servo motor (13) output and threaded rod (12) correspond the transmission and are connected to symmetrical slidable mounting has two screw thread pieces (14) in regulation platform (11), and screw thread piece (14) correspond the cover and establish in threaded rod (12) outside, and the screw thread line in two screw thread pieces (14) is opposite, and two screw thread pieces (14) of linkage are done each other and are close to, are kept away from the action each other when threaded rod (12) rotate.

7. The lifting device for photovoltaic panels used in photovoltaic ceiling construction according to claim 1, characterized in that: the adsorption unit comprises two electric modules (15) which are symmetrically and slidably arranged on the front end face of the linkage table (9), the electric modules (15) are connected with the threaded blocks (14), a first vacuum electric sucker (16) is correspondingly arranged at the output end of each electric module (15), a second vacuum electric sucker (17) is correspondingly arranged at the bottom of the front end of each electric module (15), and the photovoltaic panel can be adsorbed and fixed by the aid of the first vacuum electric sucker (16) and the second vacuum electric sucker (17).