KR20210015287A - Solar waste module separation device and separation method thereof - Google Patents

Abstract

The present invention relates to a device and method for separating a solar waste module and, more specifically, to a device and method for separating a solar waste module by applying the heat locally to an encapsulant (EVA) part in a solar waste module through a heated jig and selectively melting an EVA. The device comprises: a fixing unit; a transport unit; and a blade.

Description

Solar waste module separation device and separation method thereof TECHNICAL FIELD

The present invention relates to an apparatus and method for separating a solar waste module, and more particularly, by locally applying heat to an encapsulant (EVA) part in a solar waste module through a heated jig and selectively melting the solar waste module. It is an invention related to an apparatus and method for separating.

Since the domestic supply of solar power generation facilities in 2003, the supply volume of solar power generation facilities has increased rapidly every year. Solar modules used in solar power facilities have a usage period of 15 to 20 years, and taking this into account, it is expected that a large number of solar PV modules will occur in the near future.

A typical solar module consists of a junction box, an aluminum frame, and a solar cell. Since solar modules contain several heavy metals among their constituents, it is believed that if the solar modules are disposed of without separate treatment, it will have a negative impact on the environment such as soil and water quality.

In addition, the development of a recovery technology for solar modules is very important because rare metals that depend on imports are used during manufacturing.

In general, a solar waste module is first separated into a junction box, an aluminum frame, and a solar cell, and the solar cell is secondarily separated into a tempered glass, an encapsulant, a solar cell, and a back sheet.

In the prior art, a physical force is applied during the first separation of the solar waste module, and heat treatment and chemical treatment are common during the second separation. The secondary separation is a layer-by-layer separation of a structure in which tempered glass, encapsulant, solar cell, encapsulant, and back sheet are integrated, and requires advanced technology. As a technology for this, pyrolysis method, organic solvent method, nitric acid needle Local laws and the like are known.

Such a conventional method has difficulty in securing the economic efficiency of the output because a large amount of inert gas is used during the process and the burden of manufacturing equipment for performing the process.

In addition, since the starting material input in the process is a solar cell in which the aluminum frame and junction box have been removed from the waste solar module, it has little flexibility due to the presence of tempered glass in the starting material. There is a problem that large equipment is needed as possible.

Korean Patent Application Publication No. 10-2013-0011249

The present invention was invented to solve the above problems, and by applying a single process for recycling or reuse of the solar energy waste module, the tempered glass, solar cell, and back sheet ) To separate.

In the solar waste module separation apparatus of the present invention for achieving the above object, the solar cell is fixed to the fixing portion; A transfer unit for transferring the fixed unit; It includes a blade for separating the solar cell by layer, and when the solar cell is transferred by the transfer unit, the blade heated to a certain temperature or higher melts the first and second encapsulant to separate the solar cell by layer. It is characterized.

The blade is characterized in that it is composed of a first blade that melts the first encapsulant and a second blade that melts the second encapsulant.

One end of the first blade and the second blade is fixed to the blade fixing plate, and the other ends of the first and second blades protrude outside the blade fixing plate for a predetermined length.

It is characterized in that the other end of the first blade is positioned lower than the other end of the second blade.

The first blade and the second blade are positioned at a predetermined distance apart from each other in the transport direction of the solar cell, and the first blade is positioned at a front end than the second blade.

In the blade fixing plate, a first heating unit for heating the first blade is formed at a front end of the first blade, and a second heating unit for heating the second blade is formed at a front end of the second blade.

The other end of the first blade is characterized in that it abuts against the front end of the first encapsulant when the solar cell is transferred by the transfer unit.

The other end of the second blade is characterized in that it abuts against the front end of the second encapsulant when the solar cell is transferred by the transfer unit.

A first collecting box is provided at the lower end of the first blade to collect the back sheet separated from the solar cell.

A second collecting box is provided at the lower end of the second blade for collecting the solar cell separated from the solar cell.

In the solar waste module separation method of the present invention for achieving the above object, the step of fixing the solar cell to the fixing unit; Transferring the solar cell by the transfer unit; A step in which the other end of the first blade abuts against the shear surface of the first encapsulant; Melting the first encapsulant by the first blade; A step in which the other end of the second blade abuts against the shear surface of the second encapsulant; It characterized in that it comprises a; step of melting the second encapsulant by the second blade.

In the step of fixing the solar cell to the fixing part, the tempered glass is characterized in that it abuts the fixing part.

Before the step of transferring the solar cell by the transfer unit, the first blade is heated to a certain temperature or higher by a first heating unit located at the front end of the first blade in the blade fixing plate, and the second blade is heated from the blade fixing plate to the second blade. It is characterized in that it is heated to a certain temperature or more by a second heating unit located at the front end.

The step of melting the first encapsulant by the first blade may include: gradually melting the first encapsulant according to the transfer direction of the solar cell; And separating the back sheet from the solar cell by the area in which the first encapsulant is melted.

The back sheet separated from the solar cell is characterized in that it is collected in the first collecting box.

The step of melting the second encapsulant by the second blade may include: gradually melting the second encapsulant according to the transfer direction of the solar cell; And separating the solar cell from the tempered glass by an area in which the second encapsulant is melted.

The solar cell separated from the tempered glass is characterized in that it is collected in a second collection box.

After the step of separating the solar cell from the tempered glass by an area where the second encapsulant is melted, the step of collecting the tempered glass by removing the tempered glass from the fixing portion is performed.

According to the present invention, there is an effect that high economic efficiency can be secured because a facility configuration and a method of performing a process for separating a solar waste module are simple.

In addition, there is an effect of providing an eco-friendly method in which fine dust, waste solvent, and the like are not generated during the separation process.

In addition, it is possible to separate the tempered glass without damage, and there is an effect of simultaneously separating the solar cell containing the migratory metal.

1 is a first step of separation of the solar waste module according to the present invention.
Figure 2 is a second step of separation of the solar waste module according to the present invention.
Figure 3 is a third step of separation of the solar waste module according to the present invention.
Figure 4 is a fourth step of separating the solar waste module according to the present invention.
Figure 5 is a cross-sectional shape of a blade for separating the solar waste module according to the present invention.

In order to fully understand the present invention, preferred embodiments of the present invention will be described with reference to the accompanying drawings. The embodiments of the present invention may be modified in various forms, and the scope of the present invention should not be construed as being limited to the embodiments described in detail below. This embodiment is provided to more completely describe the present invention to those with average knowledge in the industry. Therefore, the shape of the element in the drawings may be exaggerated to emphasize a clearer description. It should be noted that in each drawing, the same configuration may be indicated by the same reference numeral. Detailed descriptions of known functions and configurations that are determined to unnecessarily obscure the subject matter of the present invention will be omitted.

The present invention relates to an apparatus and method for separating a solar waste module, and more particularly, by locally applying heat to an encapsulant (EVA) part in a solar waste module through a heated jig and selectively melting the solar waste module. The invention relates to a separating apparatus and method for separating.

In general, a solar module is composed of a junction box, an aluminum frame, and a solar cell 2, and the solar cell 2 is a back sheet 4, a first encapsulant (EVA). ), a solar cell (6), a second encapsulant (EVA), and a tempered glass (8) are sequentially stacked.

The apparatus and method for separating solar waste modules of the present invention relates to an apparatus and method for separating the junction box and the solar cell 2 from which the aluminum frame has been removed for each layer.

FIG. 1 shows a first step of separating the waste solar module according to the present invention, FIG. 2 shows a second step of separating the waste photovoltaic module according to the present invention, and FIG. 3 shows the solar cell according to the present invention. The third step of separating the waste photovoltaic module is shown, and FIG. 4 shows the fourth step of separating the photovoltaic waste module according to the present invention.

The solar waste module separating apparatus of the present invention includes a fixing part 10 to which the solar cell 2 is fixed, a transfer part for transferring the fixing part 10, and separating the solar cell 2 by layers. It is configured to include a blade for and a blade fixing plate 16 to which the blade is fixed.

When the solar cell 2 is fixed to the fixing part 10, the solar cell 2 is positioned at a certain distance from the upper end of the blade fixing plate 16, and the solar cell by the transfer part During the transfer of (2), the solar cell 2 is transferred from the front end to the rear end of the blade fixing plate 16.

In an embodiment of the present invention, a plurality of blades are provided, and include a first blade 12 for melting the first encapsulant and a second blade 14 for melting the second encapsulant. .

When the first blade 12 and the second blade 14 are provided on the blade fixing plate 16, the first blade 12 and the second blade 14 are formed of the solar cell 2 They are located at a certain distance apart from each other in the conveying direction, and the first blade 12 is located at a front end than the second blade 14.

The lower ends of the first and second blades 12 and 14 are fixed to the blade fixing plate 16, and the upper ends of the first and second blades 12 and 14 are fixed to the fixing part 10 A predetermined length protrudes outward of the blade fixing plate 16 toward the solar cell 2 fixed to ).

That is, the first blade 12 and the second blade 14 are the blade fixing plate so that the upper end is inclined at a certain angle toward the front end of the solar cell 2 in the initial state fixed to the fixing part 10. It is fixed at (16).

At this time, the lengths at which the upper ends of the first blade 12 and the second blade 14 protrude from the blade fixing plate 16 are different, and the upper end of the first blade 12 is the second blade It is located lower than the top of (14).

This is because the first blade 12 melts the first encapsulant and then the second blade 14 melts the second encapsulant. In this case, the first encapsulant and the second encapsulant are stacked. Because the height is different.

That is, the inclination angle of the first blade 12 is the angle at which the upper end of the first blade 12 contacts the front end surface of the first encapsulant when the solar cell 2 is transferred by the transfer unit. The inclination angle of the second blade 14 is the angle at which the upper end of the second blade 14 contacts the front end of the second encapsulant when the solar cell 2 is transferred by the transfer unit. Should be.

In the blade fixing plate 16, a first heating part 18 for heating the first blade 12 is formed at a front end of the first blade 12, and at a front end of the second blade 14, the A second heating unit 20 for heating the second blade 14 is formed.

The first blade 12 is heated to a certain temperature or higher by the first heating unit 18 to melt the first encapsulant when the solar cell 2 is transferred by the transfer unit, thereby melting the solar cell ( The back sheet 4 is separated from 6).

The back sheet 4 separated from the solar cell 6 by the first blade 12 descends into the first collecting box 22 provided at the lower end of the first blade 12 and is collected. do.

The second blade 14 is heated by the second heating unit 20 to a predetermined temperature or higher to melt the second encapsulant when the solar cell 2 is transferred by the transfer unit, thereby melting the solar cell ( The back sheet 4 is separated from 6).

The back sheet 4 separated from the solar cell 6 by the second blade 14 descends into the second collection box 24 provided at the lower end of the second blade 14 and is collected. do.

The cross-sectional shape of the blade is not limited, and may preferably be formed as shown in FIG. 5, and the first blade () in order to smoothly melt the first encapsulant and the second encapsulant. 12) and the width of the upper end of the second blade 14 is preferably formed equal to the width of the solar cell 2.

In the following, a separation method using the solar module separation device described above will be described.

The separation method of the present invention,

Fixing the solar cell (2) to the fixing part (10);

Transferring the solar cell 2 by the transfer unit;

Bringing the other end of the first blade 12 into contact with the front end surface of the first encapsulant;

Melting the first encapsulant by the first blade 12;

Bringing the other end of the second blade 14 into contact with the front end surface of the second encapsulant;

The process includes a step of melting the second encapsulant by the second blade 14.

First, in the step of fixing the solar cell 2 to the fixing part 10, the solar cell 2 is fixed so that the upper surface of the tempered glass 8 abuts the lower surface of the fixing part 10. .

At this time, as a fixing method of the solar cell 2, a mechanical fixing, vacuum transfer fixing, compression transfer fixing method, etc. may be applied. The solar cell 2 is not separated from the fixing part 10 until the separation is completed.

When the solar cell 2 is fixed to the fixing part 10, the first blade 12 is attached to the first heating part 18 before the step of transferring the solar cell 2 by the transfer part. Thus, the second blade 14 is heated to a predetermined temperature or higher by the second heating unit 20.

At this time, the first blade 12 and the second blade 14 are heated to a temperature of 250°C to 400°C.

The solar cell 2 fixed to the fixing part 10 is transferred by the transfer part, and transferred at a rate of 0.5 cm/sec to 30 cm/sec from the beginning of transfer to completion of transfer.

The solar cell (2) transferred by the transfer unit, the front end of the first encapsulant is brought into contact with the upper end of the first blade (12), and by the first blade (12) heated to a certain temperature or higher. The first encapsulant starts to melt.

The first encapsulant is gradually melted from the front end to the rear end according to the transport direction of the solar cell 2, and the back sheet 4 is separated from the solar cell 6 by an area where the first encapsulant is melted. do.

The back sheet 4 separated from the solar cell 6 is collected in the first collecting box 22.

As the transfer of the solar cell 2 continues, the front end of the second encapsulant of the solar cell 2 abuts the upper end of the second blade 14, and the second heated to a predetermined temperature or higher. The second encapsulant starts to melt by the blade 14.

The second encapsulant is gradually melted from the front end to the rear end according to the transport direction of the solar cell 2, and the solar cell 6 is separated from the tempered glass 8 by an area where the second encapsulant is melted. do.

The solar cell 6 separated from the tempered glass 8 is collected in the second collection box 24.

The first blade 12 and the second blade 14 can be positioned according to the shape and standard of the solar cell 2 fixed to the fixing part 10, and the first blade 12 In the step in which the other end of the first encapsulant is in contact with the shear surface of the first encapsulant, when the upper end of the first blade 12 is located at a position not contacting the shear surface of the first encapsulant, the inclination angle of the first blade 12 Also, it is possible to adjust the protruding length of the blade fixing plate 16 so that the upper end of the first blade 12 may contact the front end of the first encapsulant.

Similarly, in the step in which the other end of the second blade 14 abuts against the front end of the second encapsulant, when the upper end of the second blade 14 is located at a position that does not contact the front end of the second encapsulant, It is possible to adjust the inclination angle of the second blade 14 and the protruding length of the blade fixing plate 16 so that the upper end of the second blade 14 may contact the front end of the second encapsulant.

When the transfer of the solar cell 2 is completed and the melting of the second encapsulant by the second blade 14 is completed, the tempered glass 8 is removed from the fixing part 10 to remove the tempered glass ( 8) will be collected.

By separating the solar cell 2 by layer using the separation device and separation method as described above, high economic efficiency can be secured, and an eco-friendly method that does not generate fine dust or waste solvent during the separation process is provided. There is an effect that can be done.

In addition, it is possible to separate the tempered glass 8 without damage, and there is an effect of simultaneously separating the solar cell 6 containing an oily metal.

The embodiments of the solar waste module separation apparatus and method of the present invention described above are only exemplary, and various modifications and other equivalent embodiments are possible from those of ordinary skill in the art to which the present invention belongs. You can see that it does. Therefore, it can be understood that the present invention is not limited to the form mentioned in the detailed description above. Therefore, the true technical protection scope of the present invention should be determined by the technical spirit of the appended claims. In addition, the present invention is to be understood as including the spirit of the present invention as defined by the appended claims and all modifications, equivalents and substitutes within the scope thereof.

2: solar cell 4: back sheet
6: solar cell 8: tempered glass
10: fixed part 12: first blade
14: second blade 16: blade fixing plate
18: first heating unit 20: second heating unit
22: first collection box 24: second collection box

Claims (18)

In a separating device for separating a solar cell comprising a back sheet, a first encapsulant (EVA), a solar cell, a second encapsulant (EVA), and a tempered glass sequentially stacked ,
A fixing part to which the solar cell is fixed;
A transfer unit for transferring the fixing unit;
Includes; blades for separating the solar cell by layer,
When the solar cell is transferred by the transfer unit, the blade heated to a certain temperature or higher melts the first and second encapsulants to separate the solar cells by layer
Solar waste module separation device, characterized in that.
The method of claim 1,
The blade,
A first blade that melts the first encapsulant,
Consisting of a second blade for melting the second encapsulant
Solar waste module separation device, characterized in that.
The method of claim 2,
One end of the first blade and the second blade is fixed to a blade fixing plate, and the other ends of the first and second blades protrude outside the blade fixing plate for a predetermined length. .
The method of claim 3,
Solar waste module separation device, characterized in that the other end of the first blade is located lower than the other end of the second blade.
The method of claim 2,
The first blade and the second blade are positioned at a predetermined distance apart from each other in the transport direction of the solar cell,
The solar waste module separation device, characterized in that the first blade is located in front of the second blade.
The method of claim 5,
In the blade fixing plate,
A first heating part for heating the first blade is formed at a front end or a rear end of the first blade,
A second heating unit for heating the second blade is formed at the front end or the rear end of the second blade
Solar waste module separation device, characterized in that.
The method of claim 4,
The other end of the first blade is a solar waste module separation device, characterized in that a contact with the front end surface of the first encapsulant when the solar cell is transferred by the transfer unit.
The method of claim 4,
The other end of the second blade is a solar waste module separation device, characterized in that a contact with the front end surface of the second encapsulant when the solar cell is transferred by the transfer unit.
The method of claim 3,
Solar waste module separation device, characterized in that the lower end of the first blade is provided with a first collecting box for collecting the back sheet separated from the solar cell.
The method of claim 3,
A solar waste module separation device, characterized in that a second collecting box for collecting the solar cell separated from the solar cell is provided at a lower end of the second blade.
A fixing portion to which a solar cell in which a back sheet, a first encapsulant (EVA), a solar cell, a second encapsulant (EVA), and a tempered glass are sequentially stacked is fixed;
A transfer unit for transferring the fixing unit;
In the solar waste module separation method using a solar waste module separation device fixed to the blade fixing plate and comprising a first blade and a second blade for separating the solar cell by layer,
Fixing the solar cell to the fixing unit;
Transferring the solar cell by the transfer unit;
Contacting the other end of the first blade with the front end surface of the first encapsulant;
Melting the first encapsulant by the first blade;
Contacting the other end of the second blade with the front end of the second encapsulant;
Including; melting the second encapsulant by the second blade
Solar waste module separation method, characterized in that.
The method of claim 11,
In the step of fixing the solar cell to the fixing unit, the tempered glass is in contact with the fixing unit.
The method of claim 11,
Before the step of transferring the solar cell by the transfer unit,
The first blade is heated to a predetermined temperature or higher by a first heating unit located at a front end of the first blade in the blade fixing plate,
The second blade is heated to a predetermined temperature or higher by a second heating unit located at a front end of the second blade in the blade fixing plate.
Solar waste module separation method, characterized in that.
The method of claim 11,
The step of melting the first encapsulant by the first blade,
Gradually melting the first encapsulant according to the transfer direction of the solar cell;
Including; separating the back sheet from the solar cell by the area in which the first encapsulant is melted
Solar waste module separation method, characterized in that.
The method of claim 14,
The solar waste module separation method, characterized in that the back sheet separated from the solar cell is collected in a first collecting box.
The method of claim 11,
The step of melting the second encapsulant by the second blade,
Gradually melting the second encapsulant according to the transfer direction of the solar cell;
Including; separating the solar cell from the tempered glass by the area in which the second encapsulant is melted
Solar waste module separation method, characterized in that.
The method of claim 16,
The solar cell separation method, characterized in that the solar cell separated from the tempered glass is collected in a second collection box.
The method of claim 16,
After the step of separating the solar cell from the tempered glass by an area where the second encapsulant is melted,
Separating method of solar waste module, characterized in that the step of collecting the tempered glass by removing the tempered glass from the fixing part proceeds.

Images