CN115230291B - Laminating device for processing photovoltaic inverter power supply multilayer board - Google Patents

Abstract

The invention provides a laminating device for processing a photovoltaic inverter power supply multilayer board, which belongs to the field of processing of power supply multilayer boards and comprises a horizontal control platform, an upper pressing platform and a lower pressing platform, wherein the lower pressing platform is arranged on the horizontal control platform, the upper pressing platform is arranged on the lower pressing platform, and the horizontal control platform can control the upper pressing platform and the lower pressing platform to incline synchronously; the upper end of the pressing table is arranged in a die-combining groove for pressing the multi-layer board, the top of the pressing table penetrates through the die-combining groove and can slide in the die-combining groove, a first conveying mechanism is arranged on the side edge of the pressing table, and the pressed multi-layer board can slide into the first conveying mechanism from the pressing table; the second conveying mechanism flush with the die closing groove is arranged on the side edge of the upper pressing table, and the multilayer board is sequentially sent into the die closing groove for pressing through the second conveying mechanism. The invention controls the lower stamping seat 302 for placing the plates for lamination to incline at two sides before lamination, so that the plates can be automatically stacked and aligned, and the lamination efficiency is improved.

Description

Laminating device for processing photovoltaic inverter power supply multilayer board

Technical Field

The invention relates to the field of processing of power supply multilayer boards, in particular to a laminating device for processing of a photovoltaic inverter power supply multilayer board.

Background

In the processing process of the power supply multilayer board, the multilayer board is obtained after the single-layer board is laminated, and the photovoltaic inverter is used as important conversion equipment of a photovoltaic power station, and the direct current generated by a photovoltaic module is required to be converted into sine wave current and then connected into a load or integrated into a power grid. Therefore, the photovoltaic inverter has the special function of matching with the photovoltaic array, and also has the function of developing the solar battery function and the system fault maintenance function to the greatest extent, and a special multilayer circuit board is required to be installed.

The patent document with the prior publication number of CN112677622A discloses a lamination device for processing a photovoltaic inverter power supply multi-layer board, wherein auxiliary devices are arranged on the left side and the right side of a base, and a supporting mechanism is arranged in the auxiliary devices, so that the board side board can be stably supported by the supporting mechanism, and the board side board is prevented from being deviated. The patent provides not only the fixture but also a jacking mechanism, so that the plate can be righted, and the die is quickly removed after bearing pressure. But here mechanical control's centre gripping and jack-up, the dynamics of easily being too big influences product quality, because monolithic panel is thinner, very easily appears crookedly when the centre gripping, laminate at this moment and appear panel deformation easily, and the circuit is inaccurate, removes external force after the centre gripping, also can the panel rebound shake earlier. Therefore, the mechanical clamping and aligning mode still has more beneficial effects, but the yield is still difficult to further improve.

Disclosure of Invention

Aiming at the defects in the prior art, the invention provides the laminating device for processing the photovoltaic inverter power supply multi-layer board, which enables the multi-layer board to be stacked and aligned in an inclined mode by changing the alignment posture, avoids additional clamping and fixing, can rapidly perform lamination, improves the efficiency and improves the yield.

In order to solve the technical problems, the invention solves the problems of laminated board deformation and inaccurate circuit butt joint caused by board bending easily due to mechanical clamping through the following technical scheme.

In order to achieve the above purpose, the present invention adopts the following technical scheme:

the laminating device for processing the photovoltaic inverter power supply multilayer board comprises a horizontal control platform, an upper pressing platform and a lower pressing platform, wherein the lower pressing platform is arranged on the horizontal control platform, the upper pressing platform is arranged on the lower pressing platform, and the horizontal control platform can control the upper pressing platform and the lower pressing platform to incline synchronously; the upper end of the pressing table is arranged in a die-combining groove for pressing the multi-layer board, the top of the pressing table penetrates through the die-combining groove and can slide in the die-combining groove, a first conveying mechanism is arranged on the side edge of the pressing table, and the pressed multi-layer board can slide into the first conveying mechanism from the pressing table; the second conveying mechanism flush with the die closing groove is arranged on the side edge of the upper pressing table, and the multilayer board is sequentially sent into the die closing groove for pressing through the second conveying mechanism.

Preferably, the top of the mold clamping groove is in an inclined structure, a blocking piece is arranged on the side edge of the top of the mold clamping groove, and the inclination angle of the second conveying mechanism is the same as that of the top of the mold clamping groove.

Preferably, the lower pressing table comprises a first hydraulic machine and a lower pressing seat, the first hydraulic mechanism is fixed on the horizontal control table, the top of a piston rod of the first hydraulic machine is connected with the lower pressing seat, and the upper movement of the piston rod of the first hydraulic machine is controlled to be close to the top end of the die-combining groove.

Preferably, the top of the first hydraulic press is provided with an installing support frame, a chute is formed in the support frame, the upper pressing table and the die closing groove are both installed on the support frame, and the side edge of the chute faces the first conveying mechanism and the top is communicated with the die closing groove.

Preferably, the piston rod of the first hydraulic machine penetrates through or supports the support frame and is in sliding fit with the support frame.

Preferably, the upper pressing table comprises a second hydraulic machine which is erected by a bracket, an upper punching seat is arranged at the bottom of the second hydraulic machine, and the upper punching seat can penetrate into the die-combining groove to press the multi-layer board falling onto the lower punching seat.

Preferably, the top surface of the lower punching seat is obliquely arranged towards the direction of the first conveying mechanism, and the bottom surface of the upper punching seat is obliquely arranged at the same inclination angle as the top surface of the lower punching seat.

Preferably, the horizontal control platform comprises a base and a horizontal platform, wherein the top of the base is arc-shaped, the side edge of the bottom of the horizontal platform is arranged on the base in an arc-shaped manner in a sliding manner, and the inclined angle of the horizontal platform is changed by moving on the base.

Preferably, the middle part of the horizontal table is spaced from the base, the base is connected with a worm through a bearing support, the bottom surface of the horizontal table is fixed with an arc-shaped worm wheel, and the worm is meshed with the worm wheel.

Preferably, the horizontal table is inclined by worm drive, and the upper pressing table and the lower pressing table are controlled to incline away from the first conveying mechanism or the second conveying mechanism.

Compared with the prior art, the invention has the following beneficial effects:

the invention provides a lamination device for processing a multilayer board of a photovoltaic inverter power supply, which is provided with a movable lower stamping seat and a die-closing groove with an inclined opening. In addition, before the pressure combination, the lower stamping seat, the upper stamping seat and the die clamping groove are subjected to inclination adjustment, and the gathered plate is close to one side of the die clamping groove through an inclination structure of the top surface of the lower stamping seat, so that the first centering is performed; controlling the whole inclination adjustment of the lower stamping seat, the upper stamping seat and the die closing groove, and adjusting the gathering direction of the plates again to perform second centering; through letting panel pile up to compound die groove one corner realization automatic to the adjustment of adjusting of panel, the quick accurate lamination processing of being convenient for.

According to the invention, the first conveying mechanism is arranged at one side below the die clamping groove, and the top surface of the lower stamping seat is obliquely arranged, so that the lower stamping seat can automatically slide into the first conveying mechanism for automatic recovery after being moved downwards and separated from the die clamping groove.

In the invention, the upper pressing table, the lower pressing table and the die clamping groove are taken as a whole, the one-way inclination is controlled, and the upper pressing seat is kept to move along the direction parallel to the die clamping groove all the time and penetrate into the die clamping groove for lamination.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings that are needed in the embodiments will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

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

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

FIG. 3 is a schematic view showing the overall inclination structure of the upper platen, lower platen and mold clamping groove of the present invention;

FIG. 4 is a schematic diagram of a mold clamping groove structure of the present invention;

FIG. 5 is a schematic view showing a structure of a support frame with a rear pressing table separated from a mold clamping groove;

FIG. 6 is a schematic view of the structure of the upper platen of the present invention;

fig. 7 is a schematic diagram of a horizontal control splitting structure of the present invention.

Description of the figure: 100. a horizontal console; 101. a base; 102. a horizontal stand; 103. a worm; 104. a worm wheel; 200. a pressing table; 201. a second hydraulic press; 202. an upper stamping seat; 300. a pressing table; 301. a first hydraulic press; 302. a lower stamping seat; 303. a support frame; 304. a chute; 400. a die-closing groove; 401. a blocking member; 500. a first conveying mechanism; 600. a second conveying mechanism.

Detailed Description

The present invention is described in further detail below with reference to the accompanying drawings.

The following description is presented to enable one of ordinary skill in the art to practice the invention. The preferred embodiments in the following description are by way of example only and other obvious variations will occur to those skilled in the art. The basic principles of the invention defined in the following description may be applied to other embodiments, variations, modifications, equivalents, and other technical solutions without departing from the spirit and scope of the invention.

It will be appreciated by those skilled in the art that in the present disclosure, the terms "longitudinal," "transverse," "upper," "lower," "left," "right," "front," "rear," "vertical," "horizontal," "top," "bottom," "inner," "outer," etc. indicate orientations or positions based on the orientation or positional relationship shown in the drawings, which are merely for convenience in describing the present simplified description, and do not indicate or imply that the device or element being referred to must have a specific orientation, be configured and operated in a specific orientation, and thus the above terms are not to be construed as limiting the present invention.

It will be understood that the terms "a" and "an" should be interpreted as referring to "at least one" or "one or more," i.e., in one embodiment, the number of elements may be one, while in another embodiment, the number of elements may be plural, and the term "a" should not be interpreted as limiting the number.

Examples:

referring to fig. 1-7, a lamination device for processing a photovoltaic inverter power supply multilayer board includes a horizontal control console 100, an upper press bench 200, and a lower press bench 300, wherein the lower press bench 300 is mounted on the horizontal control console 100, the upper press bench 200 is mounted on the lower press bench 300, and the horizontal control console 100 can control the upper press bench 200 and the lower press bench 300 to incline synchronously;

the upper end of the lower pressing table 300 is arranged in a die clamping groove 400 for laminating the multi-layer board, the top of the lower pressing table 300 penetrates into the die clamping groove 400 and can slide in the die clamping groove, a first conveying mechanism 500 is arranged on the side edge of the lower pressing table 300, and the laminated multi-layer board can slide into the first conveying mechanism 500 from the lower pressing table 300;

the second conveying mechanism 600 flush with the die clamping groove 400 is arranged on the side edge of the upper pressing table 200, and the multi-layer boards are sequentially sent into the die clamping groove 400 for pressing through the second conveying mechanism 600.

The following describes its own embodiment in detail with reference to the drawings:

in the present application, the lamination device for processing the photovoltaic inverter power supply multilayer board includes a horizontal control table 100, an upper press table 200, a lower press table 300, a mold clamping groove 400, a first conveying mechanism 500, and a second conveying mechanism 600. The lower press table 300 is mounted on the horizontal control table 100, the upper press table 200 is mounted on the lower press table 300, the die-closing groove 400 is arranged between the upper press table 200 and the lower press table 300, and the upper press table 200 and the lower press table 300 finish the press-closing between the plates in the die-closing groove 400. The second conveying mechanism 600 is disposed at a top side of the mold clamping groove 400 and is used for conveying a plurality of boards into the mold clamping groove 400, the first conveying mechanism 500 is disposed at a bottom side of the mold clamping groove 400, and the laminated multi-layer board slides into the first conveying mechanism 500 from the bottom of the mold clamping groove 400 and is conveyed away.

In this application, pile up each other between a plurality of planks and put forward automatically, avoid pressfitting dislocation.

Specifically, the top of the mold clamping groove 400 is set in an inclined structure, the second conveying mechanism 600 is set in an inclined structure with the same inclination angle as the top of the mold clamping groove 400, and the blocking pieces 401 are arranged on three sides of the mold clamping groove 400, so that the plates incline from the second conveying mechanism 600 to enter the mold clamping groove 400, and a plurality of plates are sequentially grabbed and placed in the second conveying mechanism 600 through the mechanical arm and stacked in the mold clamping groove 400 to realize preliminary alignment.

The first transfer mechanism 500 is disposed at a position where the second transfer mechanism 600 is inclined to the lower end side of one side of the pressing stage 300.

The lower pressing table 300 is composed of a first hydraulic machine 301, a lower punching seat 302, a supporting frame 303 and the like, the supporting frame 303 is in an inverted U-shaped structure and is fixed on the horizontal control table 100, the first hydraulic machine 301 is positioned in the middle of the supporting frame 303 and is fixedly connected with the horizontal control table 100, a piston rod of the first hydraulic machine 301 penetrates through the supporting frame 303 to be connected with the lower punching seat 302, and the lower punching seat 302 is supported in the die-combining groove 400 and is close to the top surface of the die-combining groove 400. The support 303 is internally provided with a chute 304, the top of the chute 304 is communicated with the outside through a side face, wherein the side face faces the first conveying mechanism 500, and the top is communicated with the mold clamping groove 400.

In operation, the lower stamping seat 302 is located at a position close to the top surface of the die-locking groove 400, and a plurality of plates sequentially enter the die-locking groove 400 and are stacked on one side of the lower stamping seat 302, and in pressing, the upper stamping seat 202 of the upper pressing table 200 is pressed into the die-locking groove 400 to be locked with the lower stamping seat 302. After the press-fit, the upper punching seat 202 returns, and the lower punching seat 302 is controlled by the first hydraulic press 301 to return to the inside of the sliding groove 304, so that the multi-layer board slides onto the first conveying mechanism 500 from one side.

It should be noted that, the top surface of the lower stamping seat 302 is inclined, so that the inclination angle is the same as the inclination angle of the top surface of the mold clamping groove 400 for convenience, and when the plate falls onto the lower stamping seat 302, the plate approaches to one side, so as to complete the first alignment.

And the inclined lower punch shoe 302 can automatically slide into the first conveying mechanism 500 along the inclined plane after being separated from the die clamping groove 400.

In this application, the upper pressing table 200 is composed of a second hydraulic press 201, an upper pressing seat 202, etc., the second hydraulic press 201 has four supports, the bottom ends of the four supports are all fixed on a supporting frame 303, the upper pressing seat 202 is installed at the bottom of the second hydraulic press 201, the bottom surface of the upper pressing seat 202 is inclined to have the same inclination angle as the top surface of the lower pressing seat 302, the upper pressing seat 202 and the lower pressing seat 302 can be assembled to form a rectangular structure, and when the upper pressing seat 202 can penetrate into the die-assembling groove 400 to press the multi-layer board falling onto the lower pressing seat 302.

In the present application, the upper platen 200, the lower platen 300, and the mold clamping groove 400 are integrally mounted on the horizontal console 100, and the upper platen 200, the lower platen 300, and the mold clamping groove 400 can be simultaneously tilted in the reverse direction by controlling the tilt of the horizontal console 100.

Specifically, the horizontal console 100 is composed of a base 101, a horizontal platform 102, worms 103, worm wheels 104 and the like, the top surface of the side edge of the base 101 is a concave cambered surface, the side edge of the bottom of the horizontal platform 102 is symmetrically provided with a convex cambered surface and is matched with the top surface of the base 101 in a sliding manner, the middle of the horizontal platform 102 is spaced from the base 101, the base 101 is connected with the two worms 103 through a bearing support, the bottom surface of the horizontal platform 102 is fixedly provided with the two arc-shaped worm wheels 104, the worms 103 are meshed with the worm wheels 104, the two worms 103 are synchronously led to rotate through tooth transmission fit, and an external motor is used for driving the two worms 103 to rotate simultaneously, so that the horizontal platform 102 is inclined.

Before the plates are pressed, the horizontal table 102 is positioned on the horizontal turntable, when the plates are needed to be pressed, the horizontal table 102 is controlled to incline, so that a plurality of targets synchronously move to the other side face of the die clamping groove 400 to finish the second alignment of the plates.

In the present application, the inclination of the top surfaces of the second conveying mechanism 600 and the mold clamping groove 400 is adjusted for the first time, so that a plurality of plates are stacked on one side of the lower stamping seat 302, and the second inclination is controlled for the whole on the basis of the second time, so that the plates are placed with one corner of the mold clamping groove 400 as the center.

The upper platen 200, the lower platen 300, and the die clamping groove 400 are disposed at the same inclination, and the upper press base 202 is always movable in a direction parallel to the die clamping groove 400 and penetrates into the die clamping groove 400.

In addition, the horizontal table 102 is inclined, and the die-closing groove 400 is separated from the second conveying mechanism 600 and is located at the same position when the horizontal table is inclined, so that the upper platen 200, the lower platen 300, and the die-closing groove 400 always maintain the same effective distance therebetween along the direction perpendicular to the first hydraulic machine 301. After horizontal stage 102 is aligned, second transfer mechanism 600 is again brought into close proximity with die cavity 400.

In some embodiments, the second conveying mechanism 600 may be removed, and a plurality of boards may be sequentially placed on the lower stamping base 302 by a mechanical arm, and the boards may be aligned to one side by using the inclined top surface of the lower stamping base 302, and the secondary adjustment may be performed on the control horizontal table 102.

It will be appreciated by persons skilled in the art that the embodiments of the invention described above and shown in the drawings are by way of example only and are not limiting. The objects of the present invention have been fully and effectively achieved. The functional and structural principles of the present invention have been shown and described in the examples and embodiments of the invention may be modified or practiced without departing from the principles described.

Claims (7)

1. The utility model provides a lamination device of photovoltaic inverter power multiply wood processing which characterized in that: the automatic control device comprises a horizontal control platform (100), an upper pressing platform (200) and a lower pressing platform (300), wherein the lower pressing platform (300) is arranged on the horizontal control platform (100), the upper pressing platform (200) is arranged on the lower pressing platform (300), and the horizontal control platform (100) can control the upper pressing platform (200) and the lower pressing platform (300) to incline synchronously;

the upper end of the lower pressing table (300) is provided with a die clamping groove (400) for pressing the multi-layer board, the top of the lower pressing table (300) penetrates into the die clamping groove (400) and can slide in the die clamping groove, the side edge of the lower pressing table (300) is provided with a first conveying mechanism (500), and the pressed multi-layer board can slide into the first conveying mechanism (500) from the lower pressing table (300);

a second conveying mechanism (600) flush with the die closing groove (400) is arranged on the side edge of the upper pressing table (200), and the multilayer boards are sequentially sent into the die closing groove (400) for pressing through the second conveying mechanism (600);

the top of the die clamping groove (400) is arranged in an inclined structure, a blocking piece (401) is arranged on the side edge of the top of the die clamping groove (400), and the second conveying mechanism (600) is arranged in an inclined structure, and the inclination angle of the second conveying mechanism is the same as that of the top of the die clamping groove (400);

the lower pressing table (300) comprises a first hydraulic machine (301) and a lower pressing seat (302), the first hydraulic machine (301) is fixed on the horizontal control table (100), the top of a piston rod of the first hydraulic machine (301) is connected with the lower pressing seat (302), and the upper movement of the piston rod is controlled to be close to the top end of the die-combining groove (400);

the horizontal control console (100) comprises a base (101) and a horizontal table (102), wherein the top of the base is arc-shaped, the side edge of the bottom of the horizontal table (102) is arranged on the base (101) in an arc-shaped manner in a sliding manner, and the horizontal table (102) moves on the base (101) to change the inclination angle of the horizontal table.

2. The lamination device for processing the photovoltaic inverter power supply multilayer board according to claim 1, wherein: the hydraulic press is characterized in that a supporting frame (303) is arranged at the top of the first hydraulic press (301), a sliding groove (304) is formed in the supporting frame (303), the upper pressing table (200) and the die clamping groove (400) are arranged on the supporting frame (303), the side edge of the sliding groove (304) faces the first conveying mechanism (500), and the top of the sliding groove (304) is communicated with the die clamping groove (400).

3. The lamination device for processing the photovoltaic inverter power supply multilayer board according to claim 2, wherein: a piston rod of the first hydraulic machine (301) penetrates through the supporting frame (303) and is in sliding fit with the supporting frame.

4. A lamination device for processing a photovoltaic inverter power supply multilayer board according to claim 3, wherein: the upper pressing table (200) comprises a second hydraulic machine (201) which is erected by a support, an upper pressing seat (202) is arranged at the bottom of the second hydraulic machine (201), and the upper pressing seat (202) can penetrate into a die-combining groove (400) to press the multi-layer board falling onto the lower pressing seat (302).

5. The lamination device for processing the photovoltaic inverter power supply multilayer board according to claim 4, wherein: the top surface of the lower stamping seat (302) is obliquely arranged towards the direction of the first conveying mechanism (500), and the bottom surface of the upper stamping seat (202) is obliquely arranged and has the same inclination angle with the top surface of the lower stamping seat (302).

6. The lamination device for processing the photovoltaic inverter power supply multilayer board according to claim 5, wherein: the middle part of the horizontal table (102) is spaced from the base (101), a worm (103) is connected to the base (101) through a bearing support, an arc-shaped worm wheel (104) is fixed on the bottom surface of the horizontal table (102), and the worm (103) is meshed with the worm wheel (104).

7. The lamination device for processing the photovoltaic inverter power supply multilayer board according to claim 6, wherein: the horizontal table (102) is driven by the worm (103) to incline, and the upper pressing table (200) and the lower pressing table (300) are controlled to incline away from the first conveying mechanism (500) or the second conveying mechanism (600).