CN212011006U

CN212011006U - Spacing control device of laminated assembly for photovoltaic assembly

Info

Publication number: CN212011006U
Application number: CN202020696643.5U
Authority: CN
Inventors: 董帅刚; 朱俊安; 林颖; 徐建
Original assignee: Tianhe Light Energy Suqian Technology Co ltd
Current assignee: Tianhe Light Energy Suqian Technology Co ltd
Priority date: 2020-04-29
Filing date: 2020-04-29
Publication date: 2020-11-24
Anticipated expiration: 2030-04-29

Abstract

An interval control device of a laminated assembly for a photovoltaic assembly comprises a supporting base, wherein a workbench is arranged on the supporting base, a feeding conveying mechanism and a laminated conveying mechanism are arranged in the workbench, rotating speed sensors are arranged on the feeding conveying mechanism and the laminated conveying mechanism, a side baffle and a material arranging push block are arranged above the feeding conveying mechanism, a laminated mechanism is arranged above the laminated conveying mechanism, a lifting baffle is arranged between the feeding conveying mechanism and the laminated conveying mechanism, and a laser sensor is arranged at the lifting baffle of the side baffle; the workbench is arranged on the side of the material arranging push block, a translation mechanism is arranged on the translation mechanism, a sliding block is arranged on the sliding block, a connecting rod and a laser range finder are arranged on the sliding block, and a laser transceiver is arranged at the top end of the connecting rod. The utility model discloses simple structure, convenient operation adjusts the distance between the photovoltaic module through laser sensor, laser transceiver and the cooperation of lifting baffle, adjusts and resumes the rotational speed through the help of speed sensor.

Description

Spacing control device of laminated assembly for photovoltaic assembly

Technical Field

The utility model relates to a lamination technical field especially relates to a photovoltaic module is with interval controlling means of lamination subassembly.

Background

A method of integrating two or more layers of the same or different materials by heating and pressing with or without an adhesive. Also known as lamination. The method is a molding method in which a plurality of layers of the same or different materials are integrally combined under heat and pressure. Is commonly used in plastic processing and also in rubber processing. In plastics processing, for thermoplastics, it is common to produce artificial leather products or composite films; for thermoset plastics, it is an important method of making reinforced plastics and articles. Various laminated products such as laminated sheets are obtained by laminating reinforcing materials such as paper, fabric, glass cloth, specialty fibers, etc. impregnated with a thermosetting resin, and heating and pressing the laminate. The laminated compound and fabric may be laminated into a tape in a rubber process. The lamination press working pressure can be classified into a high pressure method (high pressure lamination) and a low pressure method (low pressure lamination).

Among the prior art, photovoltaic module is through operating personnel manual control at the interval on the laminator, has not only increased operating personnel's intensity of labour, has reduced efficiency moreover. Meanwhile, the distance between the photovoltaic modules cannot be effectively controlled, and lamination errors can occur when the photovoltaic modules are laminated.

SUMMERY OF THE UTILITY MODEL

The utility model aims at solving the defects of the prior art and providing an interval control device of a laminated assembly for a photovoltaic assembly.

The spacing control device of the laminated assemblies for the photovoltaic assemblies is characterized by comprising a supporting base, wherein a workbench is arranged on the supporting base, a feeding conveying mechanism and a laminated conveying mechanism are arranged in the workbench, rotating speed sensors are arranged on the feeding conveying mechanism and the laminated conveying mechanism, a side baffle and a material arranging push block are arranged on the workbench above the feeding conveying mechanism, a laminating mechanism is arranged on the workbench above the laminated conveying mechanism, a lifting baffle is arranged between the feeding conveying mechanism and the laminated conveying mechanism, and a laser sensor is arranged on the side baffle at the lifting baffle;

the feeding mechanism is provided with a feeding conveyor belt, the feeding conveyor belt is sleeved on a roll shaft, the roll shaft is fixed in the workbench through a rotating shaft, the workbench is provided with a first translation mechanism on the material arranging push block side, the first translation mechanism is provided with a first sliding block, the first sliding block is provided with a connecting rod and a first laser range finder, the top end of the connecting rod is provided with a first laser transceiver, and a sliding groove is formed above the first translation mechanism;

the laminating mechanism is provided with a feeding conveyor belt, the laminating conveyor belt is sleeved on a roll shaft, the roll shaft is fixed in the workbench through a rotating shaft, the workbench is provided with a second translation mechanism on the material arranging push block side, the second translation mechanism is provided with a second slide block, the second slide block is provided with a connecting rod and a second laser range finder, the top end of the connecting rod is provided with a second laser transceiver, and a sliding groove is formed above the second translation mechanism.

Preferably, the side baffle plate is of a mirror structure on the side facing the monolith pushing block.

Preferably, the lifting baffle is controlled by a telescopic rod, a protruding block is arranged on one side of the feeding and conveying mechanism of the lifting baffle, the laser sensor is arranged above the protruding block, and a receiver matched with the laser sensor is arranged on the protruding block.

Preferably, the first laser range finder and the second laser range finder face the lifting baffle.

Preferably, the distance between the first laser range finder and the lifting baffle is greater than the distance between the second laser range finder and the lifting baffle.

Preferably, the feeding and conveying mechanism and the laminating and conveying mechanism are controlled to rotate through gears and motors, the gears are connected with the roll shafts, the feeding motors are controlled to operate the feeding and conveying mechanism, the feeding motors are connected with first rotating speed sensors, the laminating motors are controlled to operate the laminating and conveying mechanism, and the feeding motors are connected with second rotating speed sensors.

Preferably, the monolith pusher, the first translation mechanism and the second translation mechanism are all controlled by a threaded rod, a gear and a motor combination.

The utility model has the advantages that:

the photovoltaic modules are positioned on the same straight line and the frames are parallel or collinear through the matching of the material-arranging push block and the side baffle, so that the adjustment of the distance between the photovoltaic modules is facilitated; the distance between the photovoltaic modules is effectively adjusted through the feeding and conveying mechanism, the lifting baffle, the laser sensor and the laser transceiver, so that the distance between the photovoltaic modules reaches the distance required to be controlled; the labor intensity of operators is reduced, the production efficiency is improved, and the lamination error rate is reduced.

Drawings

The accompanying drawings are included to provide a further understanding of the invention, and are incorporated in and constitute a part of this specification, together with the description of embodiments of the invention, and are not intended to limit the invention. In the drawings:

FIG. 1 is a front view of the present invention;

FIG. 2 is a schematic top view of the present invention;

FIG. 3 is an enlarged view of circle A in FIG. 1;

labeled as: 1-supporting base, 2-workbench, 3-side baffle, 4-monolith pusher, 5-rotating shaft, 6-roller shaft, 7-laminating conveyor belt, 8-feeding conveyor belt, 9-first slide block, 10-first laser range finder, 11-connecting rod, 12-first laser transceiver, 13-sliding chute, 14-laser sensor, 15-lifting baffle, 16-second laser transceiver, 17-second laser range finder, 18-second slide block, 19-gear, 20-feeding motor, 21-first rotating speed sensor, 22-laminating motor, 23-second rotating speed sensor, 24-second translation mechanism, 25-first translation mechanism, 26-telescopic rod and 27-laminating mechanism.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments.

According to the drawings 1 to 3, the spacing control device for the laminated assemblies for the photovoltaic assemblies is characterized by comprising a supporting base 1, a workbench 2 is arranged on the supporting base 1, a feeding conveying mechanism and a laminated conveying mechanism are arranged in the workbench 2, rotating speed sensors are arranged on the feeding conveying mechanism and the laminated conveying mechanism, a side baffle 3 and a material arranging push block 4 are arranged above the feeding conveying mechanism of the workbench 2, a laminating mechanism 27 is arranged above the laminated conveying mechanism of the workbench 2, a lifting baffle 15 is arranged between the feeding conveying mechanism and the laminated conveying mechanism, the lifting baffle 15 is controlled by a telescopic rod 26, and a laser sensor 14 is arranged at the lifting baffle 15 of the side baffle 3.

Feeding mechanism is equipped with pay-off conveyer belt 8, and pay-off conveyer belt 8 cup joints on roller 6, and roller 6 is fixed in workstation 2 through the pivot, and workstation 2 is equipped with first translation mechanism 25 in the side of material all in one piece ejector pad 4, is equipped with first slider 9 on the first translation mechanism 25, is equipped with connecting rod 11 and first laser range finder 10 on the first slider 9, and connecting rod 11 top is equipped with first laser transceiver 12, and first translation mechanism 25 top is equipped with spout 13.

Laminating mechanism 27 is equipped with pay-off conveyer belt 8, and laminating conveyer belt 7 cup joints on roller 6, and roller 6 is fixed in workstation 2 through the pivot, and workstation 2 is equipped with second translation mechanism 24 in the side of material all in one piece ejector pad 4, is equipped with second slider 18 on the second translation mechanism 24, is equipped with connecting rod 11 and second laser range finder 17 on the second slider 18, and connecting rod 11 top is equipped with second laser transceiver 16, and second translation mechanism 24 top is equipped with spout 13.

The feeding and conveying mechanism and the laminating conveying mechanism are controlled to rotate through a gear 19 and a motor, the gear 19 is connected with the roller shaft 6, the feeding motor 20 controls the feeding and conveying mechanism to operate, the feeding motor 20 is connected with a first rotating speed sensor 21, the laminating motor 22 controls the laminating conveying mechanism to operate, and the feeding motor 20 is connected with a second rotating speed sensor 23.

Before the device runs, the positions of the first sliding block 9 and the second sliding block 18 are respectively adjusted through the first translation mechanism 25 and the second translation mechanism 24, and the positions of the first sliding block 9 and the second sliding block 18 are specifically adjusted through the first laser range finder 10 and the second laser range finder 17, so that sufficient time is reserved for adjusting the distance between the photovoltaic modules.

When the equipment is initially operated, the lifting baffle 15 is positioned inside the workbench 2. During operation, the photovoltaic module is put into from the end part of the feeding conveyor belt 8 of the workbench 2, and the feeding conveyor belt 8 drives the photovoltaic module to move forward. When the photovoltaic module reaches the position of the material-arranging push block 4, the material-arranging push block 4 pushes the photovoltaic module to be straight against the side baffle 3, so that the photovoltaic modules are in the same straight line.

When the tail end of the previous photovoltaic module leaves the sensing area of the laser sensor 14, the lifting baffle 15 rises. If the first laser transceiver 12 still receives the reflected laser, the feeding conveyor belt 8 accelerates to drive the next photovoltaic module to move forward by increasing the rotating speed of the feeding motor 20 until the next photovoltaic module abuts against the lifting baffle 15 and shields the sensing area of the laser sensor 14.

When the front end of the previous photovoltaic module blocks the second laser transceiver 16, the lifting baffle 15 descends, meanwhile, the next photovoltaic module moves forwards to reach the laminating conveyor belt 7, and the lifting baffle 15 ascends until the tail end leaves the sensing area of the laser sensor 14.

The lifting baffle 15 is controlled to ascend through the second laser transceiver 16 except for the initial operation stage of the equipment, and the lifting baffle 15 needs to descend only when the laser sensor 14 and the second laser transceiver 16 are shielded simultaneously during the operation. When the tail end of the photovoltaic module leaves the sensing area of the laser sensor 14, the lifting baffle 15 rises.

Although the present invention has been described in detail with reference to the foregoing embodiments, it will be apparent to those skilled in the art that modifications may be made to the embodiments described in the foregoing embodiments, or equivalents may be substituted for elements thereof. Any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims

1. The spacing control device of the laminated assemblies for the photovoltaic assemblies is characterized by comprising a supporting base, wherein a workbench is arranged on the supporting base, a feeding conveying mechanism and a laminated conveying mechanism are arranged in the workbench, rotating speed sensors are arranged on the feeding conveying mechanism and the laminated conveying mechanism, a side baffle and a material arranging push block are arranged on the workbench above the feeding conveying mechanism, a laminating mechanism is arranged on the workbench above the laminated conveying mechanism, a lifting baffle is arranged between the feeding conveying mechanism and the laminated conveying mechanism, and a laser sensor is arranged on the side baffle at the lifting baffle;

2. The apparatus of claim 1, wherein the side baffle plate is a mirror structure facing the side of the pushing block.

3. The device for controlling the spacing between the lamination assemblies for the photovoltaic assembly as claimed in claim 1, wherein the lifting baffle is controlled by a telescopic rod, the lifting baffle is provided with a protrusion on one side of the feeding and conveying mechanism, the laser sensor is arranged above the protrusion, and the protrusion is provided with a receiver matched with the laser sensor.

4. The apparatus of claim 1, wherein the first laser range finder and the second laser range finder face the lift stop.

5. The apparatus of claim 4, wherein the distance between the first laser distance meter and the lifting stop is greater than the distance between the second laser distance meter and the lifting stop.

6. The device of claim 1, wherein the feeding conveyor and the laminating conveyor are controlled by a gear and a motor, the gear is connected to the roller, the feeding motor controls the feeding conveyor to operate, the feeding motor is connected to a first rotation speed sensor, the laminating motor controls the laminating conveyor to operate, and the feeding motor is connected to a second rotation speed sensor.

7. The apparatus of claim 1, wherein the monolith pusher, the first translation mechanism and the second translation mechanism are controlled by a threaded rod, a gear and a motor combination.