KR102283519B1 - Crushing and Recovery Unit for Dry Recycling of Solar Waste Module - Google Patents

Abstract

A dry crushing facility supplied with a solar waste module in which a back sheet, EVA layer, solar cell, EVA layer, and tempered glass are laminated from a bottom and an aluminum frame forms an edge, in which a tempered glass removal unit provided for separating the tempered glass comprises: a crushing unit for receiving the tempered glass of the solar waste module from which the aluminum frame is removed to face downward and crushing the solar waste module; a first heater unit for heating a lower surface of the solar waste module that has passed through the crushing unit; a first separation roller and a second separation roller for crushing the tempered glass of the solar waste module that has passed through the first heater unit and separating the same from the EVA layer; a tempered glass collecting unit located at a lower end of the first separating roller and collecting the crushed and scraped tempered glass; a transfer roller unit for transferring the solar waste module into the tempered glass removal unit; and a third separation roller unit for separating the cells after scraping the tempered glass from the separation roller unit.

Description

Crushing and Recovery Unit for Dry Recycling of Solar Waste Module

The present invention relates to a solar waste module dry shredding facility, and more particularly, dry waste solar module dry recycling, which is crushed and separated in a dry manner to recycle discarded solar modules after defective products, other damage during the process, and end of use. It relates to crushing and recovery facilities for

Recently, solar power has been widely adopted as an eco-friendly renewable energy.

The lifespan of the solar module used for solar power generation is about 20 to 25 years, and since the solar module has been commercialized since the early 2000s, the replacement time is coming.

As a result, the number of solar modules to be discarded increases day by day, and it is estimated that 95.1-233 tons of solar modules will be discarded in 2020 and 70-80,000 tons in 2040.

However, there are insufficient facilities or methods for treating or recycling them.

In the solar module 1, as shown in FIG. 1, the tempered glass 10 is attached to the upper side of the solar cell 30 through the EVA layer 20 made of an adhesive, and the lower side is a bag for waterproofing. A sheet (50, Back Sheet) is attached through an EVA layer (40) made of an adhesive, and a junction box (60) is installed on the lower surface of the back sheet (50), and the outside is surrounded by an aluminum frame (70). .

The solar module consists of 70-80 wt% of tempered glass, 10 wt% of aluminum frame, 4% of solar cell, and the remaining plastic and other metals such as silver and copper.

In terms of price ratio, since solar cells occupies about 50%, research to recover them has been mainly made up to now, and Korean Patent Registration No. 10-1207297 can be cited as an example.

The above registered patent uses a wet type treatment method in which the EVA layer is removed by immersing the waste module in an organic solvent to separate the solar cell. In this case, there is a problem in that the environmental pollution load due to the generation of waste water between the waste treatment solution and the process movement increases, and the process treatment time is long, so that a large amount of land and many facilities are required for mass recycling.

On the other hand, since the glass used in the solar module is made of high-purity tempered glass and has high recycling efficiency and is traded at a higher price than general glass, a method for recovering it has recently been developed, and Korean Patent Registration 10-2091346 Ho is an example.

In order to reuse the tempered glass part of the waste module in the above registered patent, the method of scraping the cell from the tempered glass with a blade is adopted. The process cost to increase the metal recycling rate increases, and additional processes such as the additional removal of the EVA layer are required for high-purity recycling of the peeled and collected tempered glass. It was inconvenient to have to continuously check the status of the machine during the work process.

KR 10-2091346 B1, 2020.03.19., claim 1 KR 10-1207297 B1, 2012.12.03., claim 1

The present invention has been devised to solve the problems of the prior art as described above, and it is an object of the present invention to provide a shredding facility capable of dryly crushing and separating each member, particularly tempered glass, from a solar waste module and collecting it.

Another object of the present invention is to recover and recycle valuable resources of the solar waste module, and to prevent wastewater or waste chemicals from being generated.

The crushing and recovery facility for dry recycling of the solar waste module of the present invention for achieving the above object,

In a dry shredding facility for shredding to recover recycled resources from a solar waste module in which a back sheet, an EVA layer, a solar cell, an EVA layer, and tempered glass are laminated from the lower side and an aluminum frame is framed,

The tempered glass removal unit provided to separate the tempered glass,

a shredding unit for receiving the tempered glass of the solar waste module from which the aluminum frame has been removed to face downward and crushing the solar waste module;

a first heater unit for heating the lower surface of the solar waste module that has passed through the crushing unit;

a multi-stage separation roller that crushes the tempered glass of the solar waste module that has passed through the heater and separates it from the EVA layer;

a tempered glass collecting unit located at the lower end of the multi-stage separation roller and collecting the crushed and scratched tempered glass;

It is characterized in that it is provided with a conveying roller so that the solar waste module is conveyed in the tempered glass removal unit.

The multi-stage separation roller includes: a first separation roller for separating from the EVA layer by repeatedly applying an impact to the tempered glass of the solar waste module that has passed through the first heater unit;

After passing through the first separation roller, it is preferable to include a second separation roller that scrapes and separates the tempered glass remaining in the solar waste module.

The conveying roller part is composed of an upper roller part and a lower roller part, and it is preferable that at least one of the upper roller part and the lower roller part can be raised and lowered.

It is preferable to further include a first pressure roller for pressing the solar waste module toward the second separation roller.

Placing a frame removal unit upstream of the tempered glass removal unit to remove the aluminum frame from the solar waste module from which the junction box has been removed,

The frame removal unit,

a frame separation unit for simultaneously pushing or pulling the aluminum frame forming the rim of the solar waste module from which the junction box is removed by means of a frame removal cylinder disposed in front and rear left and right;

a first transfer unit for adsorbing the solar waste module separated from the frame separation unit and moving it to the tempered glass crushing unit;

Preferably, the frame includes an aluminum frame collecting unit that collects the separated aluminum frame from the frame separating unit.

The frame removal unit

A supply box in which the junction box is removed and the solar waste module is stacked;

It is also preferable to further include a second transfer unit for adsorbing the solar tube waste module from the supply box and transferring it to the frame separation unit.

In order to remove the solar cell from the solar waste module from which the tempered glass is removed, a solar cell removal unit is disposed downstream of the tempered glass crushing unit,

The solar cell removal unit,

a third separation roller that separates the solar cell of the solar waste module that has passed through the tempered glass crusher from the back sheet;

a solar cell collecting unit located at the lower end of the third separating roller and collecting the separated solar cells;

It is preferable to consist of a back sheet collecting unit for discharging and collecting the back sheet from which the solar cell is removed.

The present invention has been devised to solve the problems of the prior art as described above, and it is possible to separate and collect each part, particularly tempered glass, from the solar waste module by dry method, and to recover and recycle valuable resources of the solar waste module. It is possible to secure economic feasibility by enabling a large amount of recycling treatment with a small-scale facility configuration by applying a continuous process, and also has the effect of preventing the generation of wastewater or waste chemicals.

1 is a view showing the structure of a solar module.
Figure 2 is a view showing an embodiment of the present invention crushing equipment.
3 and 4 are views showing a frame removing unit according to an embodiment of the present invention.
Figure 5 is a view showing an embodiment of the present invention tempered glass removal unit.
Figure 6 is a view showing an embodiment of the present invention solar cell removal unit.
7 is a view showing first and second separation rollers according to an embodiment of the present invention.

Hereinafter, the present invention will be described in more detail with reference to the drawings according to embodiments thereof.

Solar waste module dry crushing equipment of the present invention,

Frame removal unit 200 for removing the aluminum frame from the solar waste module (hereinafter referred to as 'waste module') from which the junction box has been removed by manual operation, etc., and the tempered glass is removed from the solar waste module from which the frame has been removed. It is largely divided into a tempered glass removal unit 100 for this purpose, and a solar cell removal unit 300 that separates the solar cell and the back sheet from the waste module from which the tempered glass is removed.

The waste module supplied to the frame removal unit 200 has a junction box removed, and the removal of the junction box is performed as follows.

The waste module 1 is fixedly mounted on the waste module holder 410 of the junction separation unit 400 . In the case of a solar module, the junction box is usually located at one end or the center.

In the junction separation unit 400, the hydraulic cylinder 420 for separation is operated to push the junction box to forcibly remove the junction box from the solar module.

The waste module from which the junction box is removed is stacked on the supply box 210 and supplied to the frame removal unit 200 . The waste module is laminated so that the tempered glass faces downward.

The waste module stacked on the supply box 210 is adsorbed by the second transfer unit 220 adsorption module and moved along the rail toward the frame separation unit.

The frame separating unit 230 separates the aluminum frame located at the edge of the waste module by pushing it in each direction at once by the frame removal cylinders 232 arranged in the front and rear left and right directions.

In the present embodiment, the frame removal cylinder 232 has been described as pushing the aluminum frame from the inside to the outside of the waste module, but the cylinder for frame removal may be removed by pulling the aluminum frame from the outside of the waste module.

The frame separating unit 230 shown up and down in FIG. 4 indicates that one frame separating unit 230 is moved up and down.

The removed aluminum frame is collected by a separate aluminum frame collecting unit (not shown).

The waste module from which the aluminum frame is removed is transferred to the tempered glass crusher. Such a transfer is made by the first transfer unit 240 . In this embodiment, the first transfer unit 240 is configured to transfer the waste module transferred to the frame separation unit by the second transfer unit 220 to the frame separation unit 230 .

When the first transfer unit 240 mounts the waste module on the transfer unit 500 , the transfer unit 500 transfers the waste module to the tempered glass removal unit 100 . In this embodiment, the transmission unit 500 is installed between the frame removal unit 200 and the tempered glass removal unit 100, and between the tempered glass removal unit 100 and the solar cell removal unit 300 to be described later. .

The transfer unit 500 is composed of a roller driven in contact with the lower surface of the waste module, and serves to transfer the waste module treated in the previous process to the subsequent process.

However, it may be possible to directly transfer the waste module from the previous process to the subsequent process without such a transfer unit 500 .

The tempered glass removal unit 100 that has received the waste module from the frame removal unit 200 is configured as follows.

The waste module delivered to the tempered glass removal unit 100 is first in contact with the support roller 110 supporting the lower surface of the waste module. The waste module passing through the support roller 100 is moved within the tempered glass removal unit 100 by the transfer roller unit 120 . The conveying roller unit 120 is divided into an upper roller unit 122 and a lower roller unit 124 , and the upper roller unit 122 is capable of elevating and lowering so that waste modules of various thicknesses can be processed.

The lower roller part 124 and the support roller 110 of the conveying roller unit 120 support the waste module, and the input is made in a horizontal or inclined state, and the tempered glass of the waste module that enters the conveying roller unit 120 . is slightly bent due to the downward pressure of the upper cylinder, and it applies an impact to the tempered glass.

As described above, after the separation of the junction box, the waste module is transported so that the tempered glass is located on the lower surface, and cracks are formed in the tempered glass shredded by the crushing unit, and it is still removed from the waste module by the EVA layer 20 of the waste module. not separated

The waste module passing through the crushing unit is heated by the first heater unit located at the lower side. According to such heating, the EVA layer of reference numeral 20 in FIG. 1 is heated first, and the adhesive force of the tempered glass 10 side is lowered. It is preferable to heat the surface temperature of the tempered glass in close contact with the EVA layer to 80 degrees Celsius or less by the first heater unit 250 . When heated to a temperature higher than that, gas is generated from the EVA layer and contaminates the work space.

The waste module that has passed through the first heater unit 250 passes through the first separation roller 260 that is located on the lower surface of the waste module and rotates to hit the tempered glass.

A plurality of soft rollers 262 are assembled and installed in the first separation roller 260 in the circumferential direction as shown in FIG. drop out

The tempered glass is separated from the EVA layer 20 by not only the blow of the soft roller 262 but also by its own weight to be removed.

Accordingly, a space is formed for the second separating roller 280 to scrape the remaining tempered glass.

The tempered glass separated from the waste module is dropped to the tempered glass collecting part 270 at the bottom.

The dropped tempered glass preferably has a cullet shape of a certain size (2-8 mm) that is easy to recycle.

A portion of the EVA layer may remain in the tempered glass falling to the tempered glass collecting unit 270 . The remaining EVA layer is then removed through a separate treatment process and undergoes a screening process of selecting only tempered glass.

The waste module passing through the first separating roller 260 continuously passes through the second separating roller 280 to which the protruding tip 282 is attached in the circumferential direction so as to scratch the cross section of the tempered glass, and is attached to the waste module. The tempered glass is completely removed. A first pressure roller 290 is provided to maintain the waste module in a horizontal state toward the second separation roller 280 side.

The tempered glass separated by the second separating roller 280 also falls to the tempered glass collecting unit 270 to be collected.

The separation roller rotates at a rotation speed different from the conveying speed of the waste module by the conveying roller unit, so that the protrusion of each separation roller scrapes off.

The dropped tempered glass preferably has a cullet shape of a certain size (2-8 mm) that is easy to recycle.

The waste module passing through the tempered glass removal unit 100 is moved to the solar cell removal unit 300 . In this embodiment, such movement is made by the transfer unit 500 as described above.

In the solar waste module that has passed through the tempered glass removal unit 100 , only the EVA layer existing between the solar cell and the back sheet and the solar cell and the back sheet remains.

The solar cell removal unit 300 is provided with a third separation roller 310 for separating the solar cell from the back sheet. Since the waste module in the solar cell removal unit 300 has a very thin thickness, it is provided with a second pressure roller 320 for pressing the waste module toward the third separation roller 310 to increase the separation efficiency.

A second heat unit (not shown) is further provided on the second pressure roller 320 to separate the solar cell by heating the EVA layer 40 between the solar cell 30 and the back sheet 50 . can make it easier.

The waste module from which the tempered glass that has passed through the second separation roller 260 has been removed passes continuously through the third separation roller 310 having a protruding tip attached in the circumferential direction so as to scratch the cross section of the solar cell in a horizontal state, , the solar cell attached to the waste module is removed. A first pressing roller 290 is provided to maintain the waste module in a horizontal state toward the third separating roller 310 .

The solar cells separated by the third separating roller 310 fall to the bottom and are collected in a solar cell collecting unit (not shown), and the back sheet is discharged to the back sheet collecting unit.

Through the above process, the waste module is separated into a junction box, an aluminum frame, tempered glass, a solar cell, and a back sheet, and since no chemicals are used in this separation process, it does not pollute the environment or minimizes the recycling of each part. it becomes possible

1: Solar (waste) module 10: Tempered glass 20, 40: EVA layer 30: Solar cell layer
50: back sheet 60: junction box 70: aluminum frame 100: tempered glass removal part
110: support roller 120: transfer roller part 122: upper roller part 124: lower roller part
200: frame removal unit 210: supply box 220: second transfer unit
230: frame separation unit 232: cylinder for frame removal 240: first transfer unit
250: first heater unit 260: first separation roller 270: tempered glass collecting unit
280: second separation roller 290: first pressure roller
300: solar cell removal unit 310: third separation roller 320: second pressure roller
400: junction box separation unit 410: waste module holder 420: hydraulic cylinder for separation
500: transfer unit

Claims (7)

In a dry shredding facility for shredding to recover recycled resources from a solar waste module in which a back sheet, an EVA layer, a solar cell, an EVA layer, and tempered glass are laminated from the lower side and an aluminum frame is framed,

The tempered glass removal unit provided to separate the tempered glass,
a shredding unit for receiving the tempered glass of the solar waste module from which the aluminum frame is removed and facing the lower side to crush the solar waste module;
a first heater unit for heating the lower surface of the solar waste module that has passed through the crushing unit;
A plurality of soft rollers are assembled and installed in the circumferential direction in order to separate from the EVA layer by applying repeated impact to the tempered glass of the solar waste module that has passed through the first heater unit, and the tempered glass surface on which the crack occurs in the crushing unit is cut into the soft a first separating roller for dropping the tempered glass by beating the roller;
a second separation roller having a plurality of protruding tips attached in the circumferential direction to scrape the tempered glass remaining in the solar waste module that has passed through the first separation roller to separate it from the EVA layer;
a tempered glass collecting unit located at the lower end of the first and second separating rollers and collecting the crushed and dropped tempered glass;
and a conveying roller unit for transferring the solar waste module into the tempered glass removal unit,
The conveying roller part is composed of an upper roller part and a lower roller part, and at least one of the upper roller part and the lower roller part can be raised and lowered,
Further comprising a first pressure roller for pressing the solar waste module toward the second separation roller,
In order to remove the aluminum frame from the solar waste module from which the junction box has been removed, a frame removal unit is disposed upstream of the tempered glass removal unit,
The frame removal unit includes: a frame separation unit for simultaneously pushing or pulling the aluminum frame forming the rim of the solar waste module from which the junction box is removed by pushing or pulling the aluminum frame arranged in front, rear, left and right sides; a first transfer unit for adsorbing the solar waste module separated from the frame separation unit and moving it to the tempered glass removal unit; It consists of an aluminum frame collecting unit that collects the aluminum frame separated from the frame separating unit,
a third separating roller that separates the solar cell of the solar waste module that has passed through the tempered glass removal unit from the back sheet; a solar cell collecting unit located at the lower end of the third separating roller and collecting the separated solar cells; To a backsheet collection unit that discharges and collects the backsheet from which the solar cell has been removed; A solar cell removal unit made up is further provided,
The third separating roller is provided with a protruding tip formed in the circumferential direction to scrape the cross section of the solar cell in a horizontal state from the waste module from which the tempered glass has been removed by the second separating roller, and the upper part of the third separating roller is provided with a second pressure roller for pressing the waste module toward the third separation roller,
A second heater unit is provided on the second pressure roller to heat the EVA layer between the solar cell and the back sheet,
The frame removal unit and the junction box is removed from the stacked supply of solar waste modules; Crushing and recovery facility for dry recycling of solar waste modules, characterized in that it further comprises a second transfer unit for adsorbing the solar tube waste module from the supply box and transferring it to the frame separation unit. delete delete delete delete delete delete

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