KR102329327B1 - Frame separation device of solar cell module - Google Patents

Abstract

A purpose of the present invention is to provide a frame separation device of a solar cell module in which throughput per hour is greatly improved. The present invention relates to the frame separation device of a solar cell module mainly comprising: a sloped ejector tool (300); forward and reverse pressure blocks (200, 200'); and a transport conveyor (100), thereby greatly improving throughput per hour by continuously performing a process of separating a vertical frame while expanding and pressing in the opposite direction by a pair of sloped ejector tools, after one pair of horizontal frames are removed by the forward and reverse pressure blocks (200, 200') while the solar cell module is moved on the transport conveyor (100).

Description

Frame separation device of solar cell module

The present invention relates to a frame separation device for a solar cell module, and more particularly, a pair of horizontal frames are removed by forward and reverse pressing blocks while the solar cell module is moved on a transport conveyor, and then a pair of inclined It relates to a frame separation device for a solar cell module in which the throughput per hour is greatly improved by continuously performing a process in which vertical frames are separated while being expanded and pressed in opposite directions by a push piece.

In general, a particular consideration in a solar cell module is to minimize the strain from external stress, and more precisely, it can be said that a frame is installed to prevent brittle fracture of glass. That is, if the module becomes larger and exceeds the mechanical strength load, the module sag increases and it becomes difficult to restore the original state. Accordingly, brittle fracture of the glass and cell will occur.

In order to minimize this phenomenon, a solar cell module frame is used, and most representatively, a frame structure of a form that maintains the four sides firmly with an aluminum frame is generalized, but the number of solar cell modules installed increases and the installation Since then, as the operating period of the solar cell module has elapsed, it is difficult to collect and dismantle the installed solar cell module.

KR 10-1622345 B1 (2016.05.12.)

Accordingly, the present invention was conceived to solve the above problems, and while the photovoltaic cell module is moved on a transport conveyor, a pair of horizontal frames are removed by forward and reverse pressing blocks, and then a pair of inclined mill pieces An object of the present invention is to provide an apparatus for separating a frame of a solar cell module in which the throughput per hour is greatly improved by continuously performing the process of separating the vertical frames while expanding and pressing in the opposite direction.

In order to achieve this object, a feature of the present invention is a plurality of adsorption pads 110 for adsorbing and fixing the photovoltaic panel 11 of the photovoltaic cell module 10, and a belt provided to orbit the adsorption pad 110. Transfer conveyor 100 consisting of (120); The transport conveyor 100 is moved in the longitudinal direction by the operation of the first and second cylinders 210 and 210 ′ installed in the forward and reverse directions at the front end of the transport conveyor 100, and the solar cell module 10 is located on both sides in the longitudinal direction. Forward and reverse pressing blocks 200 and 200 ′ which are provided to separate a pair of horizontal frames 12 arranged by pressing in opposite directions to each other; And installed in a pair so as to face each other at the rear end of the transport conveyor 100, one end is arranged narrower than the distance of a pair of vertical frames 13 disposed on both sides in the width direction of the photovoltaic cell module 10, the other end is The vertical frame 13 is characterized in that it comprises a; inclined mill piece 300 is installed at an inclination angle so as to expand compared to the distance.

At this time, a shuttle block 220 that is connected to the first and second cylinders 210 and 210 ′ and moves in the longitudinal direction of the transport conveyor 100 is provided, and is inserted into the shuttle block 220 in the longitudinal direction to move the upper , a rod rod 230 moving downward is installed, installed at the lower end of the rod rod 230 , and installed to move in the longitudinal direction together with the rod rod 230 to form a pair of horizontal frames 12 with each other. Forward and reverse pressing blocks 200 and 200 ′ for pressing in the reverse direction are provided, and are installed on the rod rod 230 and a compression spring 240 provided to protrude the rod rod 230 upward. And, a cam roller 250 installed at the upper end of the rod rod 230, and a cam disposed spaced apart from the upper portion of the conveying conveyor 100, and controlling the vertical movement of the rod rod by sliding with the cam roller 250 It is characterized in that the rail 260 is provided.

In addition, when the shuttle block 220 protrudes by the first and second cylinders 210 and 210 ′, the cam rail 260 moves downward with the rod rod 230 by sliding with the cam roller 250 . A downward slope section 262 is formed, and it is connected to the downward slope section 262 and consists of a straight section 264 guiding the rod rod 230 to move in a straight line in a downwardly moved state, and the downward slope section. A pair by a straight section 264 in a state where the lower end of the forward and reverse pressing blocks 200 and 200 ′ are moved to a position higher than the solar panel 11 and lower than the surface of the horizontal frame 12 by 262 It is characterized in that it is provided to separate the horizontal frame 12 by pressing in opposite directions to each other.

In addition, a rod hole 270 is formed in the upper portion of the forward and reverse pressing blocks 200 and 200 ′, and the lower end of the rod rod 230 is inserted into the rod hole 270 and is installed to be movable in the vertical direction. , an elastic body 272 is installed inside the rod hole 270 to protrude the forward and reverse pressing blocks 200 and 200 ′ downward, and the solar panel 11 of the photovoltaic cell module 10 . As the rod rod 230 is drawn into the rod hole 270 according to the height position, the lower end of the forward and reverse pressing blocks 200 and 200 ′ are position corrected to match the surface of the solar panel 11 . .

According to the above configuration and action, in the present invention, a pair of horizontal frames are removed by a forward and reverse pressing block while the photovoltaic cell module is moved on a transport conveyor, and then the vertical frames are mutually reversed by a pair of inclined mill pieces. It has the effect of greatly improving the throughput per hour by continuously performing the separation process while being expanded and pressurized.

1 is a block diagram showing the overall frame separation device of a solar cell module in a plan view according to an embodiment of the present invention.
2 is a configuration diagram showing the overall frame separation device of the solar cell module from the side according to an embodiment of the present invention.
Figure 3 is a block diagram showing a horizontal frame removal step of the frame separation device of the solar cell module according to an embodiment of the present invention.
Figure 4 is a configuration diagram showing the correction state of the forward and reverse pressing block position of the frame separating device of the solar cell module according to an embodiment of the present invention.
5 is a block diagram showing a vertical frame removal step of the frame separating device of the solar cell module according to an embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a block diagram showing the overall device for separating a frame for a solar cell module in a plan view according to an embodiment of the present invention, and FIG. is a configuration diagram.

The present invention relates to a frame separating device for a solar cell module, which is removed by a pair of horizontal frames by forward and reverse pressing blocks while the solar cell module is moved on a transport conveyor, and then by a pair of inclined mill pieces The main components of the vertical frame are the conveying conveyor 100, the forward and reverse pressing blocks 200, 200', and the inclined mill piece 300 to greatly improve the throughput per hour by continuously performing the process of separating the vertical frames while expanding and pressing in the reverse direction. is made of

The transport conveyor 100 according to the present invention includes a plurality of adsorption pads 110 for adsorbing and fixing the photovoltaic panel 11 of the photovoltaic cell module 10, and a belt 120 provided to orbit the adsorption pad 110. ) is made of The belt 120 is provided as a pair in the upper and lower portions, respectively, and the upper and lower belts 120 are rotated in opposite directions to each other to transport the solar cell module 10 .

In addition, the forward and reverse pressure blocks 200 and 200 ′ according to the present invention are transferred by the operation of the first and second cylinders 210 and 210 ′ installed in the forward and reverse directions at the front end of the transfer conveyor 100 . (100) is moved in the longitudinal direction, the photovoltaic cell module 10 is provided to separate by pressing a pair of horizontal frames 12 disposed on both sides in the longitudinal direction in opposite directions to each other.

At this time, a shuttle block 220 that is connected to the first and second cylinders 210 and 210 ′ and moves in the longitudinal direction of the transport conveyor 100 is provided, and is inserted into the shuttle block 220 in the longitudinal direction to move the upper , a rod rod 230 moving downward is installed, installed at the lower end of the rod rod 230 , and installed to move in the longitudinal direction together with the rod rod 230 to form a pair of horizontal frames 12 with each other. Forward and reverse pressing blocks 200 and 200 ′ for pressing in the reverse direction are provided, and are installed on the rod rod 230 and a compression spring 240 provided to protrude the rod rod 230 upward. And, a cam roller 250 installed at the upper end of the rod rod 230, and a cam disposed spaced apart from the upper portion of the conveying conveyor 100, and controlling the vertical movement of the rod rod by sliding with the cam roller 250 A rail 260 is provided.

In FIG. 3, the cam rail 260 moves the rod rod 230 by sliding motion with the cam roller 250 when the shuttle block 220 protrudes by the first and second cylinders 210 and 210'. A downward inclined section 262 for moving downward is formed, and it is connected to the downward inclined section 262 and includes a straight section 264 for guiding the rod rod 230 to move in a straight line in a downwardly moved state.

Accordingly, by the downward inclination section 262, the lower end of the forward and reverse pressing blocks 200 and 200 ′ are higher than the solar panel 11 and are moved to a lower position than the horizontal frame 12 surface in a straight section 264 . ) by pressing the pair of horizontal frames 12 in opposite directions to each other to separate them.

In this way, the linear motion force of the forward and reverse pressing blocks 200 and 200' by the operation of the first and second cylinders 210 and 210' is generated by the cam roller 250 and the cam rail 260. While additionally occurring, the forward and reverse pressing blocks 200, 200' move downward while moving in the lateral direction to press and separate the horizontal frame 12, so the structure is simple and the horizontal frame 12 separation operation is quick. In particular, continuous operation is possible without interference with the horizontal frame 12 of the solar photovoltaic module 10 that is continuously transported on the transfer conveyor 100 .

In FIG. 4 , a rod hole 270 is formed in the upper portion of the forward and reverse pressing blocks 200 and 200 ′, and the lower end of the rod rod 230 is inserted into the rod hole 270 to enable flow in the vertical direction. installed, and an elastic body 272 is installed inside the rod hole 270 to protrude the forward and reverse pressing blocks 200 and 200' downward.

Accordingly, according to the height position of the solar panel 11 of the photovoltaic cell module 10, the rod rod 230 is drawn into the rod hole 270, and the lower end of the forward and reverse pressing blocks 200 and 200 ′ receive sunlight. Since the position is corrected to match the surface of the panel 11, there is an advantage of being universally applicable without structural change in response to the photovoltaic panel 11 of various standards.

In addition, the inclined mill piece 300 according to the present invention is installed in a pair so as to face each other at the rear end of the transport conveyor 100, one end of which is disposed on both sides in the width direction of the photovoltaic cell module 10. A pair of vertical frames ( 13) It is arranged narrowly compared to the distance, and the other end is installed at an inclination angle to expand compared to the vertical frame 13 distance.

Accordingly, as shown in FIG. 5 , the horizontal frame 12 is separated by the forward and reverse pressing blocks 200 and 200 ′ while the solar panel 11 is moved on the transport conveyor 100 , and a pair through the end. When the inclined mill piece 300 of the enters between the vertical frame 13, the vertical frame 13 is removed by pressing outward by the inclined motion of the inclined mill piece 300 and the vertical frame 13.

As such, a pair of horizontal frames 12 are removed by the forward and reverse pressing blocks 200 and 200 ′ while the photovoltaic module 10 is moved on the transfer conveyor 100 , and then a pair of inclination There is an advantage in that the solar cell module separation throughput per hour is greatly improved by continuously performing the separation process while the vertical frame 13 is expanded and pressed in the opposite direction by the mill piece 300 .

100: transfer conveyor 200, 200': forward and reverse pressure block
300: inclined mill piece

Claims (4)

A transport conveyor 100 comprising a plurality of adsorption pads 110 for adsorbing and fixing the photovoltaic panel 11 of the photovoltaic cell module 10, and a belt 120 provided to orbit the adsorption pad 110;
The transport conveyor 100 is moved in the longitudinal direction by the operation of the first and second cylinders 210 and 210 ′ installed in the forward and reverse directions at the front end of the transport conveyor 100, and the solar cell module 10 is located on both sides in the longitudinal direction. Forward and reverse pressing blocks 200 and 200 ′ which are provided to separate a pair of horizontal frames 12 arranged by pressing in opposite directions to each other; and
The transport conveyor 100 is installed in a pair so as to face each other at the rear end, one end is arranged narrower than the distance of a pair of vertical frames 13 disposed on both sides in the width direction of the photovoltaic cell module 10, the other end is vertical Including;;
A shuttle block 220 that is connected to the first and second cylinders 210 and 210 ′ and moves in the longitudinal direction of the transport conveyor 100 is provided, and is inserted into the shuttle block 220 in the longitudinal direction to move up and down A rod rod 230 that moves in the direction is installed, and is installed at the lower end of the rod rod 230 and is installed to move in the longitudinal direction together with the rod rod 230 so as to move a pair of horizontal frames 12 in the opposite direction to each other. A compression spring 240 provided with forward and reverse pressing blocks 200 and 200' for pressing, installed on the rod rod 230 and protruding upwardly, the rod rod 230, A cam roller 250 installed on the upper end of the rod rod 230, and a cam rail that are spaced apart from each other on the transfer conveyor 100 and control the vertical movement of the rod rod by sliding with the cam roller 250 ( 260), a frame separation device for a solar cell module, characterized in that it is provided. delete The method of claim 1,
When the shuttle block 220 protrudes by the first and second cylinders 210 and 210', the cam rail 260 moves the rod rod 230 downward by sliding with the cam roller 250. A slope section 262 is formed, and it is connected to the downward slope section 262 and consists of a straight section 264 guiding the rod rod 230 to move in a straight line in a downwardly moved state, and the downward slope section 262 ), the lower end of the forward and reverse pressing blocks 200, 200 ′ is moved to a position higher than the solar panel 11 and lower than the surface of the horizontal frame 12, and a pair of horizontal A frame separating device for a solar cell module, characterized in that it is provided to separate by pressing the frame 12 in opposite directions. The method of claim 1,
A rod hole 270 is formed in the upper portion of the forward and reverse pressing blocks 200 and 200 ′, and the lower end of the rod rod 230 is inserted into the rod hole 270 to be installed movably in the vertical direction, and the The elastic body 272 is installed inside the load hole 270 to protrude the forward and reverse pressing blocks 200 and 200 ′ downward, and the solar panel 11 of the photovoltaic cell module 10 is positioned at a height. As the rod rod 230 is drawn into the rod hole 270, the lower end of the forward and reverse pressure blocks 200, 200 ′ are positioned so that the lower end of the solar panel 11 is aligned with the solar cell. The frame separator of the module.

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