JP2007180063A - Disassembling method of solar cell module - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a disassembling method of a solar cell module with which cracking and chipping of the solar cell element are suppressed when collecting the solar cell element from the solar cell module, so as to improve a collection rate of the solar cell element. <P>SOLUTION: The solar cell module comprises the solar cell element, a buffer material which is brought into contact with the solar cell element in at least a part, and a sealing material comprising the buffer material and the solar cell element. The disassembling method thereof includes a heating process for thermally decomposing the buffer material, and a swelling process for swelling the sealing material. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a method for dismantling a solar cell module.

  In recent years, attention has been paid to new energy technology using natural energy as global environmental problems and energy conservation have increased. As one of them, there is a high interest in systems using solar energy, and in particular, the spread of solar power generation systems to houses has been accelerated.

  On the other hand, from the viewpoints of effective utilization of resources and environmental protection, there is an increasing need for disassembly of solar cell modules and recycling of usable members. Conventional solar cell modules include many reusable components among the components discarded as industrial waste, but have not been fully recycled. In this context, in order to promote the reuse of useful resources and reduce waste, the need to establish solar cell module manufacturing technology with a high ratio of recyclable components and processing technology after use has increased. ing.

  A general solar cell module has a structure in which a plurality of solar cell elements are connected in series and parallel, laminated with a light transmission plate, an encapsulating resin, and a weather resistant film, and the solar cell elements are sandwiched by heating.

  FIG. 5 is a structural diagram showing a cross section of a general solar cell module according to the photovoltaic power generation system. In the figure, 10a and 10b are solar cell elements, 11 is a light transmission plate, 12 is a weather resistant film, 14 is a solar cell module, 15 is a frame, 16 is a sealing material, 17 is a terminal box, and 18 is a conductive material. is there.

  As shown in FIG. 5, the solar cell module 14 is electrically connected in series and in parallel with a plurality of solar cell elements 10 (10a, 10b) that generate electric power by utilizing the photoelectric conversion effect of a semiconductor made of, for example, silicon. Then, it is covered with a weather-resistant material to obtain the required output voltage and output current.

  A light transmissive plate 11 such as a glass plate or a synthetic resin plate is disposed on the light receiving surface of the solar cell element 10, and a Teflon (registered trademark) film, PVF (polyvinyl fluoride), or PET (PET) is disposed on the non-light receiving surface as the back surface. A weather-resistant film 12 (polyethylene terephthalate) or the like is attached, and a transparent synthetic resin such as EVA (ethylene-vinyl acetate copolymer resin) is interposed between the light transmission plate 11 and the weather-resistant film 12. Thus, the sealing material 16 can be obtained.

  And with respect to the rectangular main body of the laminated structure of the light transmission plate 11, the solar cell element 10 and the weather resistant film 12, the periphery of each side is mounted so as to sandwich the frame 15 made of aluminum metal, SUS, or the like, The strength of the solar cell module 14 is increased.

  Further, a terminal box 17 made of synthetic resin such as ABS resin or aluminum metal is adhered to the back surface of the solar cell module 14, that is, the weather resistant film 12, and a terminal for taking out the output power of the solar cell module 14 is formed. is doing.

  Although the solar cell module 14 is manufactured as described above, the solar cell element 10 hermetically sealed in the solar cell module 14 filled with the sealing material 16 is used even after long-term use. It has the property that power generation efficiency is less degraded. Thus, it is proposed that the solar cell element 10 is taken out and reused as the solar cell element 10 of a new solar cell module 14 even if the sealing material 16 or other members are deteriorated. Yes.

  Conventionally, as a method for dismantling such a solar cell module, the following dismantling methods have been proposed.

For example, by providing a release layer that is a thermoplastic resin between members of a solar cell module, heating this, and applying an external release force to separate the members that are in contact with the release layer, sealing There is disclosed a method of removing a material resin with heated nitric acid, alkali, organic solvent, or the like (see, for example, Patent Document 1).
Japanese Patent Laid-Open No. 11-289103

  However, the solar cell module disassembling method described above has a problem that when the solar cell element is recovered, the solar cell element is cracked or chipped, resulting in a decrease in the recovery rate of the solar cell element.

  The present invention has been made in view of such problems of the prior art, and an object of the present invention is to suppress cracking and chipping of the solar cell element when the solar cell element is recovered from the solar cell module. Another object of the present invention is to provide a method for disassembling a solar cell module in which the solar cell element recovery rate is improved.

  In order to achieve the above object, the inventor has intensively studied and as a result, has found the following facts.

  Conventionally, in many methods for disassembling a solar cell module, when the solar cell element is taken out from the solar cell module, a sealing material that holds the solar cell element in an airtight state is immersed in nitric acid or the like, so that The battery element can be taken out. However, as a result of immersing the sealing material in the liquid, a phenomenon occurs in which the sealing material absorbs the liquid and increases its volume. Although this phenomenon is generally called swelling, the sealing material may give stress to the solar cell element due to swelling of the sealing material when the solar cell module is disassembled.

  Therefore, a method for disassembling a solar cell module according to claim 1 of the present invention includes a solar cell element, a buffer material that contacts at least part of the solar cell element, and a sealing material that includes the buffer material and the solar cell element. A solar cell module disassembling method comprising: a heating step for thermally decomposing the buffer material; and a swelling step for swelling the sealing material.

  Moreover, the disassembly method of the solar cell module according to claim 2 of the present invention is the disassembly method of the solar cell module according to claim 1, wherein the swelling step is performed in a state where the buffer material is thermally decomposed. It was made to immerse in the liquid which decomposes | disassembles a stop material.

  Moreover, the disassembly method of the solar cell module which concerns on Claim 3 of this invention is a disassembly method of the solar cell module of Claim 1 or Claim 2, Comprising: The said buffer material heats more than the said sealing material. It was made to be a material having a low decomposition temperature.

  Moreover, the disassembly method of the solar cell module which concerns on Claim 4 of this invention is a disassembly method of the solar cell module as described in any one of Claims 1-3, Comprising: The said buffer material is thermosetting. It was made to contain a functional resin.

  Moreover, the disassembly method of the solar cell module which concerns on Claim 5 of this invention is a solar cell module as described in any one of Claims 1-4, Comprising: The said buffer material is the said solar cell element. The entire surface was covered.

  Moreover, the disassembly method of the solar cell module which concerns on Claim 6 of this invention is a disassembly method of the solar cell module as described in any one of Claim 2-5, Comprising: The said heating process is the said solar The whole battery module was heated.

  Moreover, the disassembly method of the solar cell module which concerns on Claim 7 of this invention is a disassembly method of the solar cell module of Claim 2-6, Comprising: The said liquid contains an organic solvent. did.

  Moreover, the disassembly method of the solar cell module according to claim 8 of the present invention is the disassembly method of the solar cell module according to claims 2 to 7, wherein the liquid is d-limonene, xylene, or toluene. At least one of them was included.

  Moreover, the disassembly method of the solar cell module which concerns on Claim 9 of this invention is a disassembly method of the solar cell module of Claims 1-8, Comprising: Before the said swelling process, the said sealing material The method includes a step of cutting at least a part.

  A method for disassembling a solar cell module, comprising: a solar cell element; a buffer material contacting at least part of the solar cell element; and a sealing material containing the buffer material and the solar cell element. And a swelling step for swelling the sealing material.

  According to the present invention, by thermally decomposing the buffer material by the heating step, the solid state atomic arrangement constituting the buffer material changes at the temperature (transition point) at which the buffer material is decomposed, and the gel state or Increases fluidity.

  And, for example, even when the buffer material in a gel state is present in at least a part of the solar cell element, for example, when the sealing material enclosing the solar cell element swells, the gelled buffer material Is deformed, and the stress applied to the solar cell element by the sealing material can be relaxed.

  Moreover, the sealing material which infiltrated the inside of the uneven | corrugated | grooved part which exists in the surface of a buffer material among sealing materials is returned to the surface vicinity of a buffer material by a swelling process. And also about a solar cell element, since the buffer material which penetrate | invaded to the inside of the uneven | corrugated | grooved part which exists in the surface of a solar cell element among the buffer materials is a gel state by a heating process, it is a solar cell easily. The element and the buffer material can be separated.

  Therefore, it becomes possible to take out the solar cell element from the encapsulant while relaxing the stress applied to the solar cell element by the encapsulant, and as a result, dismantling of the solar cell module in which the solar cell element is hardly cracked or chipped. A method can be provided.

  The solar cell module according to the present invention will be described with reference to the drawings.

  FIG. 1 is a structural view showing a cross section of the solar cell module of the present invention. In FIG. 1, 1 is a buffer material, 2 is a solar cell element, 3, 3 a and 3 b are sealing materials, 4 is a front cover, 5 is a back cover, 6 is a terminal box, 7 is a wiring, 8 is a frame, 20 Is a solar cell module, and 21 is an inner lead.

  As shown in FIG. 1, the solar cell module 20 main body of the present invention seals a solar cell element 2 at least partially covered with a buffer material 1 with a sealing material 3 having excellent weather resistance, The structure is sandwiched between the front cover 4 on the light receiving surface side and the back cover 5 on the back surface. A terminal box 6 for taking out electrical output is provided on the back surface of the solar cell module 20 body, the electrical wiring 7 is drawn out, and a frame 8 is provided around the side surface. Here, for example, EVA (ethylene-vinyl acetate copolymer resin) may be used as the sealing material 3, glass may be used as the front cover 4, and PET may be used as the back cover 5.

  The buffer material 1 can be a thermosetting resin such as Si resin or fluororesin, and the buffer material 1 is spray coated, dip coated or brushed so as to be in contact with at least a part of the solar cell element 2. It can be formed on the solar cell element 2 by, for example.

  Moreover, it is preferable that the sealing material covers the entire surface of the solar cell element 2.

  Further, a buffer material may be formed in a string state by connecting a plurality of solar cell elements 2 with the inner leads 21, or the buffer material 1 may be formed on each individual solar cell element 2. Good.

  In particular, in the electrode portion provided on one main surface of the solar cell element 2, the buffer material containing the thermosetting resin is present, so that the buffer material is thermoset when heated in the subsequent laminating process. Therefore, the positioning of the electrode can be prevented.

  And it can be set as the solar cell module 20 by passing through the lamination process which superimposes and heats these members.

  For example, the light receiving surface side sealing material 3a and the solar cell element 2 connected by the inner leads 21 are stacked on the front cover 1, and the back surface side sealing material 3b and the back cover 5 are sequentially stacked thereon. Thus, each member is laminated, set in a laminator, and heated at a temperature of 100 ° C. to 200 ° C. for about 15 to 60 minutes while being pressurized under a reduced pressure of 50 to 150 Pa, thereby sealing the light receiving surface side. The material 3 a and the back surface side sealing material 3 b are melt-bridged, and the solar cell element 2 and the buffer material 1 are encapsulated by the sealing material 3, and these can be integrated into the solar cell module 20.

  Thus, the solar cell including the solar cell element 2, the buffer material 1 in contact with at least a part of the solar cell element 2, and the sealing material 3 enclosing the buffer material 1 and the solar cell element 2. Module 20 may be used.

  Moreover, the solar cell module 20 according to the present invention can obtain long-term reliability.

  Normally, when a general solar cell module 14 is used for a long period of time, acetic acid may be generated in the sealing material 16 that hermetically holds the solar cell element 10 due to rain, humidity, or the like. When reaching 10, the corrosion of the electrode provided in the solar cell element 10 may be caused and the long-term reliability of the solar cell module 14 may be impaired.

  However, according to the present invention, acetic acid is generated inside the sealing material 3, and even when this acetic acid reaches the solar cell element 2, the buffer material 1 has a composition different from that of the sealing material 3. The acetic acid described above can be prevented from reaching the solar cell element 2. As a result, the lifetime of the solar cell element 2 can be extended.

  Further, if the buffer material 1 is a thermosetting resin, the buffer material 1 is thermoset by the heating temperature (100 ° C. to 200 ° C.) during the lamination process, and the bonds between the molecules constituting the buffer material 1 are strong. It will be a thing. As described above, since the buffer material 1 is thermoset and the binding energy between molecules becomes high, even if the buffer material 1 is formed at the electrode portion of the solar cell element 2 even when the temperature is returned to room temperature, the solar cell. The electrode part of the element 2 can be firmly held.

  Thus, since the solar cell element 2 is firmly held in the sealing material 3, even when an external force such as wind is applied when the solar cell module 20 is installed or after the solar cell module 20 is installed. Further, it is possible to prevent stress from being applied to the soldered portion between the electrode of the solar cell element 2 and the inner lead 21. As a result, it is possible to reduce the possibility that the electrical continuity of the electrode portion is hindered by an external force, and thus long-term reliability of the solar cell module 20 can be obtained.

  Further, if the buffer material 1 is a thin film, the time required for thermosetting the thermosetting resin is shortened, and the thermal history for the solar cell element 2 can be reduced, so that long-term reliability can be obtained. . Moreover, it leads also to the tact improvement at the time of manufacturing the solar cell module 20. FIG.

  A well-known technique can be used for the method of forming the thin-film buffer material 1, and the buffer material 1 can be formed on the solar cell element 2 by spray coating or the like.

  Hereinafter, the disassembly method of the solar cell module according to the present invention will be described in detail.

  The flowchart of FIG. 2 shows a procedure for disassembling the solar cell module 20 shown in FIG. In order to disassemble the solar cell module 20 as shown in FIG. 2, it is disassembled according to the following procedure.

(1) Remove the frame 8, the terminal box 6, and the electrical wiring 7 from the solar cell module 20. (2) Heat the solar cell module 20 to thermally decompose the buffer material 1 (heating step).
(3) Immerse in the solution 9 to swell the sealing material 3 (swelling step)
(4) Recovering the members constituting the solar cell module 20 Hereinafter, the above-described procedure will be described in detail with reference to FIG.

  First, the frame 8 of the solar cell module 20 is removed. For example, the screws fixing the frames 8 can be removed, peeled off, the frame 8 can be removed from the solar cell module 20 by a physical method, and the electrical wiring 7 can also be removed by cutting or the like. .

  The terminal box 6 is also removed by a physical method such as peeling off. In addition, when the frame 8 and the terminal box 6 are attached with an adhesive such as butyl or silicon, heating may be appropriately performed to weaken the adhesive force.

  As this heating method, a well-known technique can be used. For example, the adhesive part is partially heated with a spot dryer, a condensing heater, a hot air heater, etc., and the adhesive temperature is increased. It may be removed mechanically while weakening. Further, the entire solar cell module may be heated with an electric furnace or a continuous furnace.

  [Heating Step] In addition, the method for disassembling the solar cell module 20 according to the present invention includes a heating step for thermally decomposing the buffer material 1.

  By doing so, the buffer material 1 is thermally decomposed to change the atomic arrangement of the solid state constituting the buffer material 1 with the temperature (transition point) at which the buffer material 1 is thermally decomposed as a boundary, and can improve the gel state or fluidity. .

  Specifically, the cushioning material 1 is preferably a material having a lower temperature for thermal decomposition than the sealing material 3. By selecting such a material, when the solar cell module 20 is heated at a uniform temperature, the buffer material 1 is thermally decomposed first, so that the buffer material 1 is heated while maintaining the form of the solar cell module 20. Since it can decompose | disassemble, the stress added to the solar cell element 2 can be relieved.

  As such a combination of the buffer material 1 and the sealing material 3, it is preferable to use, for example, a silicon resin or a fluororesin that is a thermosetting resin as the buffer material 1, and EVA as the sealing material 3.

  For example, when silicon resin is used as the buffer material 1 and EVA is used as the sealing material 3, only the buffer material 1 is obtained by heating the solar cell module 20 at 200 ° C. to 300 ° C., more preferably 230 ° C. to 270 ° C. It can be pyrolyzed.

  As a result, the buffer material 1 can maintain a gel state even when the main chain of the polymer is cut by thermal decomposition and returned to room temperature.

  At this time, it is easy to heat the solar cell module 2 using an electric furnace or continuous furnace with the front cover 4 of the solar cell module 20 facing down so that a load is not applied to the solar cell element 2 as much as possible. Therefore, it is preferable.

  Moreover, it is preferable that this heating process heats the whole surface of the solar cell module 20.

  If the temperature applied to the solar cell element 2 becomes uniform, the thermal history of the solar cell element 2 is relaxed, and cracking of the solar cell element 2 due to the thermal history can be suppressed. Moreover, since it becomes difficult to apply a thermal stress to the front cover 4 which is a collection member, it can be suitably reused as one of the recycling members.

  [Swelling Step] The method for disassembling the solar cell module 20 according to the present invention includes a swelling step for swelling the sealing material 3.

  Thus, even when the sealing material 3 is swollen by thermally decomposing the buffer material 1 in contact with at least a part of the solar cell element 2 and increasing the gel state or fluidity of the buffer material 1. The buffer material 1 is deformed, and the stress applied to the solar cell element by the sealing material 3 can be relaxed.

  Moreover, the sealing material 3 which has entered the inside of the concavo-convex portion existing on the surface of the buffer material 1 among the sealing material 3 is returned to the vicinity of the surface of the buffer material 1 by the swelling process. And also about the solar cell element 2, since the buffer material 1 which infiltrated into the inside of the uneven | corrugated | grooved part which exists in the surface of the solar cell element 2 among the buffer materials 1 is a gel state by a heating process, The solar cell element 2 and the buffer material 1 can be separated easily.

  FIG. 3 shows a schematic diagram when the sealing material 3 is immersed in a liquid, which is one of the swelling steps described above. 3A is a diagram illustrating a state in which the solar cell module 20 is all immersed in the liquid 9, and FIG. 3B illustrates a state in which the front cover 4 and the member including the solar cell element 2 are separated. FIG. In the figure, 1 is a buffer material, 2 is a solar cell element, 3a and 3b are sealing materials, 4 is a front cover, 5 is a back cover, 9 is liquid, 20 is a solar cell module, and 21 is an inner lead. .

  For example, at least the entire solar cell module 20 is filled with a liquid 9 for decomposing the sealing material 3 in a tank having a size that can be charged in the horizontal direction, and the solar cell module 20 is immersed. The dipping method may be dipping gradually, or all the solar cell modules 20 may be dipped at once. As a function of the tank, it is more preferable to have a transfer function of continuously moving horizontally and throwing it into the tank while supporting the end of the solar cell module 20.

  As shown in FIGS. 3A and 3B, the sealing material 3 swells when the solar cell module 20 is immersed in the liquid 9. As a result, the solar cell module 20 can be separated into the front cover 4, the solar cell element 2, and the back cover 5.

  And since the sealing material 3 swells by immersing the solar cell module 20 in the liquid 9, the sealing which infiltrated the inside of the uneven | corrugated | grooved part which exists in the surface of the buffer material 1 among the sealing materials 3 was carried out. The material 3 is returned to the vicinity of the surface of the cushioning material 1, and as a result, the adhesive force between the sealing material 3 and other members is reduced.

  As described above, according to the present invention, the buffer material 1 is thermally decomposed and is in contact with at least a part of the solar cell element 2 in the above-described gel state or the state in which the fluidity is improved. It is possible to reduce the adhesive force between the sealing material 3 and the buffer material 1 while relaxing the stress applied to the solar cell element 2. As a result, it is possible to provide a method for disassembling the solar cell module 20 in which the solar cell element 2 is hardly cracked or chipped.

  Further, in the swelling step according to the present invention, the liquid 9 may be misted and sprayed on the entire solar cell module 20. When the mist particles having the internal pressure energy come into contact with the sealing material 3, the mist particles penetrate faster and promote delamination between layers, and can be decomposed in a short time.

  Thereafter, the separated member is collected. It is preferable to collect not only the solar cell element 2 and the front cover 4, but also the cut back cover 5, the wiring material connecting the strings, and the like as reusable resources.

  Then, the collected member is cleaned. Here, it is preferable to remove dirt such as the buffer material 1 and the sealing material 3 attached to the solar cell element 2.

  Further, in order to make the surface state of the solar cell element 2 uniform and bring the electromotive force close to the initial state, primary cleaning is performed with a solvent containing toluene or xylene as a main material.

  Furthermore, in order to remove the dirty toluene, xylene, etc. adhering to the surface of the solar cell element 2, it is preferable to perform secondary cleaning with methanol or a solvent mainly composed of ethanol.

  And since it can be used about the solar cell element which the crack and the chip | tip generate | occur | produced by processing small by laser cutting etc., it is preferable to classify separately.

  In addition, regarding the solar cell module 20, it is preferable to cut into at least a part of the sealing material 3. FIG. 4A shows a state before the solar cell module 20 is cut, and FIG. 4B shows a state after the solar cell module 20 is cut. In the figure, 1 is a buffer material, 2 is a solar cell element, 3a and 3b are sealing materials, 4 is a front cover, 5 is a back cover, 20 is a solar cell module, and 21 is an inner lead.

  Since the contact area between the liquid 9 and the sealing material 3 is increased when the sealing material 3 is swollen by making a cut in the solar cell module 20, the sealing material 3 can be swollen in a shorter time. .

  For example, when the solar cell module 20 is immersed in the liquid 9 placed at room temperature, the solar cell element 2 can be taken out from the sealing material 3 after about 24 to 48 hours.

  The cutting into the sealing material 3 may be performed manually using a cutter, a disk-type cutter, a laser cutter, or the like, and more preferably using an automatic machine using a disk-type cutter, a disk-type grindstone, or a laser cutter. You can go.

  By carrying out like this, the collection time of the solar cell element 2 can be shortened, which leads to tact-up, which is preferable.

  Furthermore, in order to shorten the immersion time, it is preferable to heat the liquid 9 in which the solar cell module 20 is immersed. In this case, the sealing material 3 is swollen by heating the liquid temperature to 80 ° C. to 100 ° C., more preferably about 85 ° C. to 95 ° C., and the solar cell element from the sealing material 3 in 1 to 2 hours. 2 can be taken out.

  The liquid 9 preferably contains an organic solvent.

  Conventionally, there is a possibility that the electrode material constituting the solar cell element 2 is oxidized and corroded by acidity such as nitric acid. However, by using the liquid 9 that swells the sealing material 3 as an organic solvent, the solar cell element As 2, it can be reused as it is as a solar cell element without newly forming an electrode part.

  Specifically, the liquid 9 preferably contains at least one of d-limonene, xylene, and toluene.

  These organic solvents are more preferable as the liquid 9 because they suitably swell the sealing material 3 and can also suitably dissolve the buffer material 1.

  In addition, the disassembly method of the solar cell module 20 according to the present invention is not limited to the above-described embodiment, and it is needless to say that various modifications can be made without departing from the gist of the present invention.

  For example, the solar cell element 2 according to the present invention is preferably a crystalline silicon solar cell, but is not limited to this, and may be a compound solar cell or other solar cell element. The effect of the present invention can be achieved as long as the stopper 3 is hermetically filled.

  Moreover, in the disassembly method of the solar cell module 20 according to the present invention, the heating step and the swelling step may be performed in the same manner. In this case, for example, a radiation-decomposable resin may be used for the buffer material 1 and thermal decomposition may be performed by irradiating ionizing radiation while the solar cell module is immersed in the liquid 9.

It is a structural diagram showing a cross section of the solar cell module according to the present invention. It is the figure which showed the procedure at the time of dismantling the solar cell module which concerns on this invention. (A) is a figure which shows the state which immersed all the solar cell modules 20 in the liquid 9, (b) is a figure which shows the state which the front cover 4 and the member containing the solar cell element 2 isolate | separated. . (A) shows the state before making a cut in the solar cell module, and (b) shows the state after making a cut in the solar cell module. It is structural drawing which shows the cross section of a common solar cell module.

Explanation of symbols

1: Buffer material 2: Solar cell elements 3, 3a, 3b: Sealing material 4: Front cover 5: Back cover 6: Terminal box 7: Electrical wiring 8: Frame 9: Liquid 20: Solar cell module 21: Inner lead

Claims (9)

A disassembly method of a solar cell module, comprising: a solar cell element; a buffer material that contacts at least part of the solar cell element; and a sealing material containing the buffer material and the solar cell element,
A heating step for thermally decomposing the buffer material, a swelling step for swelling the sealing material,
Of dismantling a solar cell module. The solar cell module disassembly method according to claim 1, wherein the swelling step is performed by immersing the buffer material in a liquid that decomposes the sealing material in a thermally decomposed state. The method for disassembling a solar cell module according to claim 1 or 2, wherein the buffer material is a material having a lower temperature for thermal decomposition than the sealing material. The said buffer material is a disassembly method of the solar cell module as described in any one of Claims 1-3 which comprises a thermosetting resin. The method for disassembling a solar cell module according to any one of claims 1 to 4, wherein the buffer material covers the entire surface of the solar cell element. The method for disassembling a solar cell module according to any one of claims 1 to 5, wherein the heating step heats the entire solar cell module. The method for disassembling a solar cell module according to any one of claims 2 to 6, wherein the liquid comprises an organic solvent. The method for disassembling a solar cell module according to any one of claims 2 to 7, wherein the liquid includes at least one of d-limonene, xylene, and toluene. The method for disassembling a solar cell module according to any one of claims 1 to 8, further comprising a step of cutting at least part of the sealing material before the swelling step.

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