JP2013055217A - Solar cell module - Google Patents

Abstract

PROBLEM TO BE SOLVED: To further improve waterproofness in a terminal box of a solar cell module.SOLUTION: One end of wiring 22 provided on a light-receiving surface of a solar cell element 14 is passed through a hole 24 provided in the solar cell element 14 and the substrate 18 and is pulled into a terminal box 12a, 12b disposed on a rear surface of the solar cell module 10. The hole 24 is filled with a first sealing material 30 made of a butyl resin or a polyisobutylene resin. A second sealing material 32 made of a silicone resin fills the terminal box 12a, 12b.

Description

  The present invention relates to a solar cell module including a solar cell element.

  The solar cell module is configured by electrically connecting a plurality of solar cell elements arranged in parallel to each other in series. That is, wiring is provided on the light receiving surface of each solar cell element, and the solar cell elements are electrically connected via this wiring.

  Here, from the solar cell elements arranged at both ends, the cathode wiring and the anode wiring are respectively drawn out. One end of these wirings wraps around the surface (back surface) opposite to the light receiving surface of the solar cell element. The one end is further passed through a hole formed in the solar cell element and the substrate disposed adjacent to the back surface of the solar cell element.

  The hole is surrounded by a terminal box bonded to the substrate via an adhesive (see, for example, Patent Document 1). Of course, the one end portion of the wiring is also accommodated in the terminal box, and once locked to a fixing portion provided in the terminal box, it is connected to the connection terminal. Another solar cell module or an external load is electrically connected to the connection terminal.

  The solar cell module configured in this way is usually used outdoors. Therefore, the inside of the terminal box is filled with a sealing material to prevent rainwater from entering the solar cell element from the hole.

  As the sealing material, silicone resins are widely used. The reason for this is that, as described in Patent Document 2, not only is it excellent in waterproofness, but it is easy to fill in the terminal box, and the work efficiency is improved because it cures in a short time. This is because it is inexpensive.

Utility Model Registration No. 3149887 JP 2010-165721 A

  The present invention has been made in connection with the above-described technology, and further improves the waterproofness in the terminal box. For this reason, it provides a solar cell module that can particularly eliminate the concern that the wiring and the solar cell element corrode. For the purpose.

To achieve the above object, the present invention comprises a solar cell element, a substrate adjacent to one end surface of the solar cell element, and a wiring provided on the other end surface of the solar cell element, In a solar cell module in which one end of the wiring is passed through a hole formed in the element and the substrate,
A terminal box that surrounds the hole and accommodates the one end of the wiring;
The hole is filled with a first sealing material, and the interior of the terminal box is filled with a second sealing material having a higher moisture permeability than the first sealing material,
The first sealing material is made of either a butyl resin or a polyisobutylene resin, and the second sealing material is made of a silicone resin.

  That is, in the present invention, the hole formed in the solar cell element and the substrate for passing the wiring is filled with the first sealing material made of butyl resin or polyisobutylene resin having relatively low moisture permeability. I am doing so. For this reason, since it is avoided that a water | moisture content reaches the light-receiving surface of a solar cell element through a hole, the concern that this solar cell element and wiring corrode is wiped away.

  In addition, the inside of the terminal box is filled with a second sealing material made of silicone resin. Silicone resin is easy to fill in the terminal box and hardens in a short time. In addition, it is inexpensive. For this reason, the 2nd sealing material in which it was avoided that the space | gap which can permeate | transmit a water | moisture content was avoided can be obtained efficiently and at low cost.

  Since the above configuration is employed, first, it is difficult for moisture to enter the terminal box. Even if moisture penetrates into the terminal box and permeates the second sealing material, it is difficult to permeate the first sealing material having a lower moisture permeability. As understood from this, according to the present invention, the waterproofness in the terminal box can be improved.

  The first sealing material preferably contains an inorganic hygroscopic material. In this case, even if moisture reaches the first sealing material, the moisture is absorbed by the inorganic hygroscopic material contained in the first sealing material. For this reason, it becomes more difficult for moisture to permeate the first sealing material, and as a result, waterproofness is further improved.

  In addition, as a suitable example of an inorganic hygroscopic material, CaO or a zeolite can be mentioned. This kind of inorganic hygroscopic material is blended in the first sealing material as particles.

  Further, when the substrate is made of glass, it is preferable that the first sealing material contains a silane coupling material. Due to the chemical action of the silane coupling material, the first sealing material adheres firmly and tightly to the substrate. For this reason, it is avoided that a gap through which moisture can pass is formed between the first sealing material and the substrate. That is, it becomes physically difficult for moisture to pass through the first sealing material, and the waterproofness is further improved.

  According to the present invention, in the terminal box, the second sealing material in which a void that allows moisture to enter is avoided, is formed from the silicone resin efficiently and at low cost, The holes formed in the solar cell element and the substrate are filled with a first sealing material made of a butyl resin or a polyisobutylene resin having a relatively low moisture permeability. For this reason, it is difficult for moisture to enter the terminal box, and even if it enters, the first sealing material prevents moisture from reaching the light receiving surface of the solar cell element through the hole. Is done. Thereby, the concern that the solar cell element and the wiring are corroded is eliminated.

It is the whole schematic rear view which shows the solar cell module which concerns on embodiment of this invention from the back surface. It is the II-II sectional view taken on the line of FIG. FIG. 3 is a cross-sectional view taken along line III-III in FIG. 1. It is a graph which shows the deterioration ratio of the solar cell module which concerns on this Embodiment, and the solar cell module of a comparative example. It is a principal part schematic longitudinal cross-sectional view of the terminal box of the solar cell module which concerns on a comparative example.

  DESCRIPTION OF EMBODIMENTS Hereinafter, preferred embodiments of a solar cell module according to the present invention will be described and described in detail with reference to the accompanying drawings.

  FIG. 1 is an overall schematic rear view showing a solar cell module 10 according to the present embodiment from the back surface (end surface opposite to the light receiving surface). This solar cell module 10 has two terminal boxes 12a and 12b on the back surface. The terminal box 12a is for the cathode, and the terminal box 12b is for the anode. The terminal boxes 12a and 12b are different from each other only in whether they are for the cathode or the anode, and the respective configurations are the same. Therefore, the configuration related to the terminal box 12a will be described in detail below, and the description of the configuration related to the terminal box 12b will be omitted.

  2 and 3 are a cross-sectional view taken along line II-II and a cross-sectional view taken along line III-III in FIG. 1, respectively. As shown in FIGS. 2 and 3, the solar cell module 10 includes a plurality of solar cell elements 14 (one of them is shown in FIGS. 2 and 3), a cover material 16, a substrate 18, and the like. It is comprised by pinching with.

  The cover material 16 disposed on the light receiving surface side of the solar cell element 14 is made of a translucent material such as glass or transparent resin so that light can reach the solar cell element 14. On the other hand, the substrate 18 disposed on the back side of the solar cell element 14 is generally made of a plastic material such as a film-like polyethylene terephthalate (PET) resin or polyvinyl fluoride (PVF) resin. It may be made of glass. Each of the solar cell elements 14 is enclosed in a protective material 20 made of ethylene vinyl acetate (EVA) or the like, and in this state, is sandwiched between the cover material 16 and the substrate 18.

  A wiring 22 is provided on the light receiving surface of the solar cell element 14. Among a plurality of solar cell elements 14, adjacent ones are electrically connected via this wiring 22.

  The wirings 22 of the solar cell elements 14 disposed at both ends of the solar cell module 10 (see FIG. 1) are a cathode wiring and an anode wiring, respectively. The solar cell element 14 and the substrate 18 are formed with through holes 24 for drawing out the wiring 22 to the back surface of the solar cell element 14 (see FIGS. 2 and 3). It is passed through the hole 24.

  The terminal box 12a is joined to the substrate 18 via an adhesive 25 and surrounds the hole 24 (see FIG. 2). Of course, the one end of the wiring 22 is accommodated inside the terminal box 12a by this enclosure. Note that one end of the wiring 22 is once locked to a fixing portion 26 provided inside the terminal box 12a, and then connected to a metal connection terminal 28. Another solar cell module 10 or an external load is electrically connected to the connection terminal 28.

  In the above configuration, the hole 24 is filled with the first sealing material 30. In this case, the first sealing material 30 slightly protrudes from the back surface of the substrate 18 into the terminal box 12a, and the protruding portion has a substantially hemispherical shape.

  The first sealing material 30 is a cured product of either a butyl resin or a polyisobutylene resin. Preferable examples of the butyl resin include butyl resin and polyvinyl butyl resin, and a preferable example of the polyisobutylene resin includes polyisobutylene resin. All of these resins have low moisture permeability. In other words, it is difficult for moisture to pass through the first sealing material 30.

  The first sealing material 30 may be obtained by dispersing and blending CaO or zeolite particles. These particles function as a hygroscopic material that absorbs moisture (water). Therefore, it becomes more difficult for moisture to pass through the first sealing material 30. That is, the moisture permeability of the first sealing material 30 is further reduced.

  When the substrate 18 is made of glass, a silane coupling material may be blended with the first sealing material 30. In this case, when the silane coupling material performs a chemical action on the substrate 18, the first sealing material 30 and the substrate 18 are firmly bonded via a chemical bonding force. For this reason, it is avoided that the first sealing material 30 is in close contact with the substrate 18, and as a result, a gap through which moisture can pass is formed between the first sealing material 30 and the substrate 18. Is done. That is, it is difficult for moisture to enter physically.

  Further, the inside of the terminal box 12a is filled with a second sealing material 32 made of a cured product of silicone resin. Although the silicone resin has a slightly lower moisture permeability than the first sealing material 30, it can be easily filled in the terminal box 12a, has an advantage of being cured in a short time and inexpensive. .

  That is, when a silicone resin is used, the inside of the terminal box 12a can be densely filled. In other words, the formation of a gap in the second sealing material 32 is avoided.

  As described above, the terminal box 12b is configured in the same manner as the terminal box 12a (see FIG. 3). Therefore, the same components are denoted by the same reference numerals, and detailed description thereof is omitted.

  The solar cell module 10 according to the present embodiment is basically configured as described above. Next, the function and effect will be described.

  When the solar cell module 10 is used outdoors, the solar cell module 10 may be exposed to rain or snow. Therefore, it is assumed that the terminal boxes 12a and 12b are attacked by moisture.

  In this case, moisture is first blocked by the second sealing material 32 filled in the terminal boxes 12a and 12b. As described above, the second sealing material 32 densely fills the terminal boxes 12a and 12b, so that the formation of voids in the terminal boxes 12a and 12b is avoided. Therefore, it is difficult for water to enter the terminal boxes 12a and 12b.

  Even if moisture enters the terminal boxes 12a and 12b, the silicone resin forming the second sealing material 32 filled in the terminal boxes 12a and 12b exhibits sufficient moisture permeability. For this reason, it is also difficult for moisture to pass through the second sealing material 32 and reach the vicinity of the hole 24. Therefore, corrosion of the connection terminals 28 provided in the terminal boxes 12a and 12b is avoided.

  Even if moisture permeates the second sealing material 32 and reaches the vicinity of the hole 24, the hole 24 has a first seal with higher moisture permeability than the second sealing material 32. The material 30 is filled. For this reason, it is extremely difficult for moisture to pass through the first sealing material 30, that is, the hole 24.

  This effect becomes even more prominent when the first sealing material 30 is obtained by dispersing and blending CaO or zeolite particles. This is because these particles function as a hygroscopic material that absorbs moisture (water), so that moisture is absorbed in the vicinity of the interface of the first sealing material 30. Even if moisture enters the inside of the first sealing material 30, the moisture absorbing material is also present inside, so that it is eventually prevented that the moisture permeates the first sealing material 30.

  Moreover, in the first sealing material 30, the portions protruding into the terminal boxes 12a and 12b have a substantially hemispherical shape. For this reason, if it is an interface with the 2nd sealing material 32 in this site | part, the distance to the wiring 22 coat | covered with the 1st sealing material 30 is substantially the same irrespective of the position. That is, the existence of a thin portion where moisture easily enters is avoided. This also makes it difficult for moisture to enter the first sealing material 30.

  Further, when the substrate 18 is made of glass, if the silane coupling material is included in the first sealing material 30, the first sealing material 30 is in close contact with the substrate 18, so that moisture can pass therethrough. Formation of a simple void is avoided. Combined with this, it becomes more difficult for moisture to pass through the first sealing material 30. That is, the moisture permeability of the first sealing material 30 is further reduced.

  After all, according to the present embodiment, it is avoided that moisture reaches the light receiving surface of the solar cell element 14 through the hole 24. Therefore, corrosion of the wiring 22 and the solar cell element 14 is also prevented.

  As a result of preventing the solar cell element 14 from corroding in this way, an increase in the resistance of the solar cell element 14 is avoided. For this reason, it can avoid that the output of the solar cell module 10 falls.

  FIG. 4 is a graph showing the deterioration ratio between the solar cell module 10 according to the present embodiment and the solar cell module (see FIG. 5) in which the holes 24 and the terminal boxes 12a and 12b are filled with only silicone resin. is there. In FIG. 4, the latter is referred to as “comparative example”. In FIG. 5, the same reference numerals are assigned to the components corresponding to the components shown in FIG.

  Furthermore, the deterioration ratio is obtained by converting the initial conversion efficiency of each solar cell module to 100% and examining the change with time. For example, assuming that the initial actual conversion efficiency is 20%, the deterioration ratio is 50% when the conversion efficiency is 10%, and the deterioration ratio is 75% when the conversion efficiency is 5%.

  From FIG. 4, it is clear that the deterioration ratio is small in the solar cell module 10 according to the present embodiment, in other words, the conversion efficiency is maintained over a long period of time. This is because, as described above, the hole 24 is filled with the first sealing material 30 made of a cured product of a butyl resin or a polyisobutylene resin.

  The present invention is not particularly limited to the above-described embodiment, and various modifications can be made without departing from the scope of the invention.

  For example, in the above-described embodiment, the cathode wiring 22 and the anode wiring 22 are individually provided in the terminal boxes 12a and 12b, but both the wirings 22 are provided in the same terminal box. May be.

DESCRIPTION OF SYMBOLS 10 ... Solar cell module 12a, 12b ... Terminal box 14 ... Solar cell element 16 ... Cover material 18 ... Substrate 20 ... Protection material 22 ... Wiring 24 ... Hole 30 ... 1st sealing material 32 ... 2nd sealing material

Claims (4)

A solar cell element; a substrate adjacent to one end surface of the solar cell element; and a wiring provided on the other end surface of the solar cell element; In the solar cell module through which one end of
A terminal box that surrounds the hole and accommodates the one end of the wiring;
The hole is filled with a first sealing material, and the interior of the terminal box is filled with a second sealing material having a higher moisture permeability than the first sealing material,
The solar cell module, wherein the first sealing material is made of either a butyl resin or a polyisobutylene resin, and the second sealing material is made of a silicone resin.   2. The solar cell module according to claim 1, wherein the first sealing material contains an inorganic hygroscopic material. 3.   3. The solar cell module according to claim 2, wherein the inorganic hygroscopic material is CaO or zeolite.   4. The solar cell module according to claim 1, wherein the substrate is made of glass, and the first sealing material contains a silane coupling material. 5.

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