CN215146293U - Novel welding platform for photovoltaic panel - Google Patents

Abstract

The utility model discloses a novel welding platform of a photovoltaic panel, which comprises a guide rail component and a plurality of platform components capable of moving on the guide rail component, wherein two ends of the guide rail component are respectively provided with a driving component for pushing the platform components to move, and the platform components are used for placing battery pieces and splicing and welding the battery pieces; the guide rail assembly comprises two guide rails which are arranged in parallel; the platform assembly comprises a hot plate, a mounting plate, a jacking assembly, a movable assembly and a bottom plate, wherein two ends of the bottom plate are respectively provided with a sliding block used for sliding on a guide rail, the hot plate is arranged on the mounting plate, the movable assembly is arranged at the top of the bottom plate, the jacking assembly is fixedly connected with the bottom plate, one end of the mounting plate is fixed on the movable assembly, and the other end of the jacking assembly is used for driving the mounting plate to lift upwards. The utility model provides a novel welded platform of photovoltaic board can realize polylith panel automatic weld simultaneously.

Description

Novel welding platform for photovoltaic panel

Technical Field

The utility model relates to a novel welded platform of photovoltaic board.

Background

At present, the existing multi-main grid production process mainly comprises the steps of welding a plurality of (9-12) circular welding strips with the diameter of about 300 microns with grid lines of battery plates when the photovoltaic panel is produced, firstly welding two battery plates together through the welding strips, then placing one welding strip to weld a third battery plate, and so on, wherein one welding strip or 2-3 welding strips are used for welding once during welding. The welding strips are generally simultaneously pulled and laid, the laying precision is low, and the problems of white exposure of the front surface and the back surface of the battery piece and the like can be caused. The existing welding equipment has low welding efficiency and low automatic production capacity, and cannot meet the requirement of large-batch production.

SUMMERY OF THE UTILITY MODEL

The utility model aims to solve the technical problem that, overcome prior art not enough, provide a novel welded platform of photovoltaic board, can realize polylith panel automatic weld simultaneously.

In order to solve the technical problem, the technical scheme of the utility model is that:

a novel welding platform for photovoltaic panels comprises a guide rail assembly and a plurality of platform assemblies capable of moving on the guide rail assembly, wherein driving assemblies for pushing the platform assemblies to move are respectively arranged at two ends of the guide rail assembly, and the platform assemblies are used for placing battery pieces and splicing and welding the battery pieces;

the guide rail assembly comprises two guide rails which are arranged in parallel;

the platform assembly comprises a hot plate, a mounting plate, a jacking assembly, a movable assembly and a bottom plate, wherein two ends of the bottom plate are respectively provided with a sliding block used for sliding on a guide rail, the hot plate is arranged on the mounting plate, the movable assembly is arranged at the top of the bottom plate, the jacking assembly is fixedly connected with the bottom plate, one end of the mounting plate is fixed on the movable assembly, and the other end of the jacking assembly is used for driving the mounting plate to lift upwards.

Further, a heat insulation bakelite is arranged between the hot plate and the mounting plate.

Further, the movable assembly comprises a movable plate and a fixed block, the fixed block is fixed to the top of the bottom plate, a rotating shaft is connected to the fixed block in a rotating mode, the movable plate is fixed to the rotating shaft, and one end of the mounting plate is fixedly connected with the movable plate.

Further, the jacking assembly is a jacking cylinder, the jacking cylinder is fixed at the bottom of the bottom plate, and a piston rod of the jacking cylinder penetrates through the bottom plate and is located below the other end of the mounting plate.

Furthermore, springs are arranged on two side walls of the bottom plate, which are perpendicular to the guide rail.

Furthermore, every two are adjacent be provided with a pair of spacing subassembly between platform assembly's the bottom plate, spacing subassembly includes spacing double-screw bolt support frame, spacing double-screw bolt and locking block, spacing double-screw bolt support frame is fixed on two lateral walls parallel with the guide rail of bottom plate, spacing double-screw bolt is fixed on spacing double-screw bolt support frame, and two are adjacent spacing double-screw bolt sets up relatively, the mounting groove of placing the locking block is seted up at the top of spacing double-screw bolt support frame, the locking block sets up the top at per two adjacent spacing double-screw bolt support frames.

Further, the top surface of the hot plate is provided with a vacuum adsorption hole.

Further, a plurality of heating rods are arranged inside the hot plate.

Further, a temperature sensor is arranged inside the hot plate.

Further, the driving assembly is a driving cylinder, and a piston rod of the driving cylinder pushes a bottom plate of the platform assembly to move.

According to the technical scheme, the utility model discloses can install a plurality of platform subassemblies on the guide rail according to production needs, place the panel and weld the area on every platform subassembly, adsorb the panel through the hot plate and fix, promote each platform subassembly by drive assembly and be close to each other on the guide rail, realize assembling automatically and welding, the utility model discloses can weld polylith panel simultaneously, welding efficiency is high, is showing and has promoted the productivity. The utility model discloses when assembling, raise one side of panel slightly by the jacking subassembly, make to assemble more smoothly, efficiency is higher.

Drawings

Fig. 1 is a front view of the novel welding platform for photovoltaic panels of the present invention;

FIG. 2 is a front view of the platform assembly of the present invention;

fig. 3 is a schematic structural diagram of the mounting plate of the present invention;

fig. 4 is a schematic structural view of the movable assembly of the present invention;

fig. 5 is a schematic structural view of the limiting assembly of the present invention;

fig. 6 is a schematic structural view of the limit stud support frame of the present invention;

FIG. 7 is a front view of FIG. 1;

fig. 8 is an assembly schematic diagram of the novel welding platform for photovoltaic panels of the present invention;

FIG. 9 is a front view of FIG. 8;

FIG. 10 is an enlarged view of a portion of FIG. 8;

fig. 11 is a schematic structural view of the solder strip of the present invention.

Detailed Description

In order that the present invention may be more readily and clearly understood, the following detailed description of the present invention is provided in connection with the accompanying drawings.

As shown in fig. 1 to 11, the present embodiment provides a novel welding platform for photovoltaic panels, which includes a guide rail assembly and a plurality of platform assemblies 100 capable of moving on the guide rail assembly, wherein two ends of the guide rail assembly are respectively provided with a driving assembly 300 for pushing the platform assemblies 100 to move, a battery piece 200 is placed on each platform assembly 100, and a welding strip 400 is disposed between every two battery pieces 200. During assembly, one platform assembly 100 moves closer to the other platform assembly 100, and the two battery plates 200 and the welding strips 400 are assembled together for welding.

As shown in fig. 1 and 7, the guide rail assembly of this embodiment is two guide rails 81 arranged in parallel, a cylinder seat is connected between the ends of the two guide rails 81, the driving assembly 300 is fixed on the cylinder seat, the driving assembly 300 of this embodiment drives the driving cylinder, and the piston rod of the driving cylinder pushes the bottom plate 5 of the platform assembly 100 to move, so as to drive the platform assembly 100 to approach each other for assembling.

As shown in fig. 2 to 6, the platform assembly 100 of the present embodiment includes a hot plate 1, a heat insulation bakelite 2, a mounting plate 3, a jacking assembly 7, a movable assembly 4 and a bottom plate 5, four threaded holes are provided at four corners of the hot plate 1, and four long screws sequentially pass through the hot plate 1, the heat insulation bakelite 2 and the threaded holes in the mounting plate 3 for screwing.

The bottom both ends of bottom plate 5 are provided with respectively and are used for slider 8 on guide rail 81 slides, and hot plate 1 sets up on mounting panel 3, and battery piece 200 places on hot plate 1, adsorbs fixedly by the vacuum adsorption hole 15 of hot plate 1 top surface, and vacuum adsorption hole 15 passes through trachea and outside vacuum pump connection. Two heating rods 12 are arranged inside the hot plate 1 to heat the hot plate 1 and then weld the welding strip 400 and the two battery plates 200 together. The interior of the hot plate 1 is provided with a temperature sensor 13 for monitoring the temperature of the hot plate 1 in real time.

When the battery pieces 200 are welded, as shown in fig. 1, the two battery pieces 200 are respectively located at the left and right sides of the welding strip 400, the top surface of the left battery piece 200 is welded to the welding strip 400, and the bottom surface of the right battery piece 200 is connected to the welding strip 400. In the assembling process of the two battery pieces 200, since the right battery piece 200 and the welding strip 400 are located on the same plane, in the assembling process, the right battery piece 200 collides with the welding strip 400, so that the right battery piece 200 cannot move to the welding strip 400. Consequently, this embodiment has set up movable assembly 4 at the top of bottom plate 5, has set up jacking subassembly 7 simultaneously on bottom plate 5, fixes the one end of mounting panel 3 on movable assembly 4, upwards lifts by the other end of jacking subassembly 7 drive mounting panel 3 during the assembly, and mounting panel 3 drives the one end of hot plate 1 and upwards lifts, makes the tip of right side battery piece 200 a little more than weld area 400 like this, moves right side battery piece 200 smoothly to weld on taking 400.

As shown in figure 2, a heat insulation bakelite 2 is arranged between the hot plate 1 and the mounting plate 3, and the heat insulation bakelite 2 can insulate between the hot plate 1 and the mounting plate 3 and prevent the components below the hot plate 1 from being damaged due to overhigh temperature.

As shown in fig. 4, the movable assembly 4 of the present embodiment includes a movable plate 41 and a fixed block 42, the fixed block 42 is fixed on the top of the bottom plate 5, a rotating shaft 43 is rotatably connected to the fixed block 42, the movable plate 41 is fixed on the rotating shaft 43, and the bottom surface of the mounting plate 3 is welded and fixed to the movable plate 41.

As shown in fig. 4, the jacking assembly 7 of this embodiment is a jacking cylinder, the jacking cylinder is fixed at the bottom of the bottom plate 5, and a piston rod 71 of the jacking cylinder penetrates through the bottom plate 5 and is located below the other end of the mounting plate 3. When the battery cell is assembled, the piston rod 71 of the jacking cylinder extends upwards to jack up the end part of the mounting plate 3, so that the end part of the right battery cell 200 is lifted.

As shown in fig. 5 and 6, a pair of limiting assemblies 101 is arranged between the bottom plates 5 of every two adjacent platform assemblies 100 in this embodiment, each limiting assembly 101 includes a limiting stud support frame 6, a limiting stud 10 and a locking block 17, the limiting stud support frames 6 are welded and fixed on two side walls of the bottom plate 5 parallel to the guide rail 81, the limiting studs 10 are screwed in the limiting stud support frames 6, the two adjacent limiting studs 10 are oppositely arranged, a mounting groove for placing the locking block 17 is formed in the top of each limiting stud support frame 6, and the locking blocks 17 are mounted in the mounting grooves in the tops of every two adjacent limiting stud support frames 6. When the two platform assemblies 100 move to the assembling position, the two adjacent limiting studs 10 are mutually abutted to limit the movement of the platform assemblies 100; after the welding is finished, the platform assembly 100 returns to the original position, and the two ends of the locking block 17 are clamped on the side walls of the two adjacent limiting stud support frames 6 respectively to limit the resetting movement of the platform assembly 100.

As shown in fig. 2, springs 11 are disposed on two side walls of the bottom plate 5 perpendicular to the guide rails 81, when the two platform assemblies 100 are moved to the assembly position, the springs 11 buffer the assembly, the locking block 17 is removed after the assembly, and the two platform assemblies 100 automatically spring open due to the action force of the springs 11 and return to the initial position.

The above embodiments further describe the technical problems, technical solutions and advantages of the present invention in detail, it should be understood that the above embodiments are only specific embodiments of the present invention, and are not intended to limit the present invention, and any modifications, equivalent substitutions, improvements, etc. made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (10)

1. The utility model provides a novel welded platform of photovoltaic board which characterized in that: the battery cell assembling and welding device comprises a guide rail assembly and a plurality of platform assemblies (100) capable of moving on the guide rail assembly, wherein two ends of the guide rail assembly are respectively provided with a driving assembly (300) for pushing the platform assemblies (100) to move, and the platform assemblies (100) are used for placing battery cells (200) and assembling and welding the battery cells (200);

the guide rail assembly comprises two guide rails (81) which are arranged in parallel;

platform subassembly (100) includes hot plate (1), mounting panel (3), jacking subassembly (7), movable assembly (4) and bottom plate (5), the bottom both ends of bottom plate (5) are provided with respectively and are used for gliding slider (8) on guide rail (81), hot plate (1) sets up on mounting panel (3), movable assembly (4) set up the top at bottom plate (5), jacking subassembly (7) and bottom plate (5) fixed connection, the one end of mounting panel (3) is fixed on movable assembly (4), the other end that jacking subassembly (7) are used for driving mounting panel (3) upwards lifts up.

2. The novel welding platform for photovoltaic panels as claimed in claim 1, wherein: and a heat insulation bakelite (2) is arranged between the hot plate (1) and the mounting plate (3).

3. The novel welding platform for photovoltaic panels as claimed in claim 1, wherein: the movable assembly (4) comprises a movable plate (41) and a fixed block (42), the fixed block (42) is fixed at the top of the bottom plate (5), a rotating shaft (43) is connected in the fixed block (42) in a rotating mode, the movable plate (41) is fixed on the rotating shaft (43), and one end of the mounting plate (3) is fixedly connected with the movable plate (41).

4. The novel welding platform for photovoltaic panels as claimed in claim 3, wherein: jacking subassembly (7) are the jacking cylinder, the jacking cylinder is fixed in the bottom of bottom plate (5), piston rod (71) of jacking cylinder pass bottom plate (5) and are located the below of the other end of mounting panel (3).

5. The novel welding platform for photovoltaic panels as claimed in claim 1, wherein: and springs (11) are arranged on two side walls of the bottom plate (5) which are vertical to the guide rail (81).

6. The novel welding platform for photovoltaic panels as claimed in claim 1, wherein: every two are adjacent be provided with a pair of spacing subassembly (101) between bottom plate (5) of platform subassembly (100), spacing subassembly (101) are including spacing double-screw bolt support frame (6), spacing double-screw bolt (10) and locking block (17), spacing double-screw bolt support frame (6) are fixed on two lateral walls parallel with guide rail (81) of bottom plate (5), spacing double-screw bolt (10) are fixed on spacing double-screw bolt support frame (6), two are adjacent spacing double-screw bolt (10) set up relatively, the mounting groove that is used for placing locking block (17) is seted up at the top of spacing double-screw bolt support frame (6), locking block (17) set up the top at per two adjacent spacing double-screw bolt support frames (6).

7. The novel welding platform for photovoltaic panels as claimed in claim 1, wherein: the top surface of the hot plate (1) is provided with a vacuum adsorption hole (15).

8. The novel welding platform for photovoltaic panels as claimed in claim 1, wherein: the interior of the hot plate (1) is provided with a plurality of heating rods (12).

9. The novel welding platform for photovoltaic panels as claimed in claim 1, wherein: a temperature sensor (13) is arranged in the hot plate (1).

10. The novel welding platform for photovoltaic panels as claimed in claim 1, wherein: the driving assembly (300) is a driving air cylinder, and a piston rod of the driving air cylinder pushes a bottom plate (5) of the platform assembly (100) to move.

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