JPWO2014045692A1 - Solar cell encapsulant sheet and solar cell module - Google Patents

Abstract

The present invention provides a sealing material sheet for a solar cell, which can simultaneously suppress problems of blocking during storage of the solar cell sealing material and cell misalignment during lamination in a solar cell manufacturing process. When one surface is an A surface and the other surface is a B surface, the A surface has irregularities (A1) having an average roughness Ra (A1) of 3 to 95 μm and an average roughness Ra (A2). ) Has an unevenness (A2) of 0.3 to 2.5 μm. [Selection] Figure 1

Description

  The present invention relates to a solar cell encapsulant sheet. In particular, a solar cell encapsulant sheet and a solar cell module using the same that can simultaneously suppress problems during blocking of the solar cell encapsulant and cell misalignment during lamination in the solar cell manufacturing process About.

In recent years, from the viewpoint of effective use of resources and reduction of CO ₂ emissions, solar cells that directly convert sunlight into electrical energy have attracted attention and technical development has been promoted.

  In crystalline silicon solar cells, which are currently mainstream, glass, encapsulant sheet, solar cell, encapsulant sheet, and back sheet are laminated in this order, and the laminate is laminated and melted under vacuum and heating conditions. A solar cell module is manufactured by sealing a cell with a sealing material resin.

  The resin that is mainly used at present in the encapsulant sheet is an ethylene vinyl acetate copolymer (hereinafter, the ethylene vinyl acetate copolymer may be referred to as EVA). In the case where the encapsulant sheet is stored in a roll or stacked, blocking occurs in which the encapsulant sheets are in close contact with each other, and there is a problem that workability is greatly reduced in the above-described lamination process.

  Further, in the above laminating step, when the solar battery cell and the sealing material sheet are in close contact with each other and the sealing material sheet contracts under heating conditions, interference between the cells due to the positional deviation of the solar battery cells occurs, This is one of the causes of the module yield reduction due to cell damage.

  In order to avoid the above trouble, embossing is performed in the manufacturing process of the encapsulant sheet, unevenness is formed on the sheet surface, and adhesion between the encapsulant sheets during storage is improved by improving the blocking resistance between the sheets. While preventing, the countermeasure which reduces the friction coefficient of a sealing material sheet and a photovoltaic cell is taken.

  In Patent Documents 1 and 2, an encapsulant sheet in which a plurality of protrusions having a skirt portion having a cylindrical shape or a truncated cone shape and a convex curved top portion are formed, or an independent protrusion having a height of 0.05 to 0.5 mm. A sealing material sheet having a portion has been proposed.

  On the other hand, Patent Documents 3, 4, and 5 propose a sealing material sheet in which Ra has an unevenness of about 1 to 20 μm on the sealing material sheet.

  Patent Documents 6 and 7 propose a sealing material sheet in which Ra has an unevenness of about 1 to 2 μm on the surface opposite to the embossed surface of the sealing material sheet.

JP 2010-258123 A JP 2010-232231 A JP 2010-192804 A JP 2012-7087 A JP 2012-99713 A JP 2010-269506 A JP 2010-269507 A

  However, even with the sealing material sheets described in Patent Documents 1 to 7, there is a certain effect in suppressing the positional deviation of the cells by reducing the blocking resistance and the friction coefficient, but sufficient workability and module yield can be ensured. It was not a thing.

Therefore, an object of the present invention is to provide a solar cell encapsulant sheet and the same sheet that can simultaneously suppress problems during blocking of the solar cell encapsulant and cell misalignment during lamination in the solar cell production process. It is in providing the used solar cell module.

In order to solve the above problems, the present invention has the following configuration. That is,
(1) When one surface is an A surface and the other surface is a B surface, the A surface has irregularities (A1) with an average roughness Ra (A1) of 3 to 95 μm and an average roughness Ra (A2). Having an unevenness (A2) of 0.3 to 2.5 μm.
(2) The solar cell package according to (1), wherein the convexity of the irregularity (A1) has irregularities (A3) having an average roughness Ra (A3) of 0.3 to 2.5 μm. Stop sheet.
(3) The solar cell encapsulant sheet according to (1) or (2), wherein an average interval Sm (A1) of the irregularities (A1) is 100 to 2,000 μm.
(4) The solar cell encapsulant sheet according to any one of (1) to (3), wherein an average interval Sm (A2) of the unevenness (A2) is 5 to 80 μm.
(5) For the A surface, a ratio (Sm (Am) of the average interval Sm (A-MD) [μm] in the sheet flow direction and the average interval Sm (A-TD) [μm] in the direction orthogonal to the sheet flow direction. (A-MD) / Sm (A-TD)) is 1.1-5, The solar cell sealing material sheet in any one of (1)-(4) characterized by the above-mentioned.
(6) The B surface has irregularities (B1) having an average roughness Ra (B1) of 0.5 to 4 μm, and an average interval Sm (B1) of the irregularities (B1) is 10 to 400 μm. The solar cell encapsulant sheet according to any one of (1) to (5), wherein
(7) Light-receiving surface protective material, solar cell sealing material sheet according to any one of (1) to (6), solar battery cell, solar cell sealing material according to any one of (1) to (6) The solar cell module obtained by arrange | positioning a sheet | seat and a back surface protection material in this order, and sealing.
(8) The solar battery module according to (7), wherein the solar battery cell is disposed so as to be in contact with an A surface side of the solar battery sealing material sheet.
It is.

  ADVANTAGE OF THE INVENTION According to this invention, the solar cell sealing material sheet | seat which can suppress simultaneously the malfunction at the time of the blocking in the storage of a solar cell sealing material and the cell position shift at the time of the lamination in the manufacturing process of a solar cell is used. The solar cell module can be provided.

It is a figure explaining the outline curve of a sealing material sheet, an unevenness | corrugation (A1), and an unevenness | corrugation (A2). It is a figure explaining the average line and the convex part of the unevenness | corrugation (A1) of a sealing material sheet.

  Hereinafter, embodiments of the present invention will be described in detail.

  The resin used for the solar cell encapsulant sheet of the present invention is not particularly limited, but is preferably a thermoplastic resin that is transparent and melts at a hot plate temperature (130 to 160 ° C.) during vacuum lamination. An ethylene vinyl acetate copolymer (hereinafter referred to as “EVA”), modified polyethylene, ionomer, polyvinyl butyral, and the like are preferably used.

  Moreover, the solar cell encapsulant sheet of the present invention appropriately contains additives such as a cross-linking agent, a cross-linking aid, a coupling agent, an ultraviolet absorber, and a light stabilizer as necessary for improving the sealing properties. May be.

  In the solar cell encapsulant sheet of the present invention, when one surface is an A surface and the other surface is a B surface, the A surface has unevenness (A1) with an average roughness Ra (A1) of 3 to 95 μm. And the roughness (A2) having an average roughness Ra (A2) of 0.3 to 2.5 μm. By having both a relatively rough unevenness (A1) with Ra of 3 to 95 μm and a fine unevenness (A2) with Ra of 0.3 to 2.5 μm, the sealing material sheets, and the sealing material sheet and the solar cell The contact area with the cell is reduced, and the positional deviation of the cell during storage and the cell during lamination can be suppressed as compared with the case where only any unevenness or no unevenness is provided. From the above viewpoint, the average roughness Ra (A2) of the unevenness (A2) is particularly preferably 0.5 to 2.5 μm. When the average roughness Ra (A1) of the unevenness (A1) is less than 3 μm, or the average roughness Ra (A2) of the unevenness (A2) is less than 0.3 μm, the sealing material sheets and the sealing material sheet The contact area with the solar battery cell is increased, and there is a possibility that blocking or positional deviation of the solar battery cell may occur. When the average roughness Ra (A1) of the unevenness (A1) exceeds 95 μm, the gap of the encapsulant sheet becomes large, and bubbles remain between the encapsulant sheet and the solar battery cells during lamination, and the module appearance May worsen. In addition, when the average roughness Ra (A2) of the unevenness (A2) exceeds 2.5 μm, only the unevenness (A1) may be substantially obtained, and the required effect cannot be obtained. From the above viewpoint, the average roughness Ra (A1) of the unevenness (A1) is particularly preferably 3 to 45 μm, and more preferably 6 to 15 μm.

  In addition, the measuring method of average roughness Ra (A1) and average roughness Ra (A2) of A surface is mentioned later.

  About the solar cell sealing material sheet | seat of this invention, average roughness Ra (A1) has unevenness | corrugation (A1) whose average roughness Ra (A1) is 3-95 micrometers, and unevenness | corrugation (A2) whose average roughness Ra (A2) is 0.3-2.5 micrometers. In order to obtain the A surface, as described later, in the manufacturing process of the solar cell encapsulant sheet, a method of transferring the shape of the embossing roller having the unevenness of the shape to be imparted to the A surface to the A surface. Can be mentioned.

  It is preferable that the solar cell sealing material sheet of this invention has the unevenness | corrugation (A3) whose average roughness Ra (A3) is 0.3-2.5 micrometers in the convex part of an unevenness | corrugation (A1). By having fine irregularities (A3) on the projections of relatively rough irregularities (A1), the contact area between the encapsulant sheets and between the encapsulant sheets and the solar cells is reduced, and blocking during storage It is easy to obtain the effect of suppressing the positional deviation of the solar cells during lamination.

  In addition, the convex part of an unevenness | corrugation (A1) means the peak (profile peak) of JIS B0601 (2001) 3.2.4 term. That is, as shown in FIG. 2, the portion above the average line (in the direction from the object to the space) among the curved portions sandwiched between two adjacent intersections when the contour curve is cut by the average line. . And having the unevenness | corrugation (A3) in the convex part of an unevenness | corrugation (A1) means that Ra (A3) calculated | required about the area | region higher than the average line in the contour curve of an unevenness | corrugation (A1) is 0.3-2.5 micrometers. Means that.

  For the solar cell encapsulant sheet of the present invention, in order to provide an A surface having irregularities (A3) with an average roughness Ra (A3) of 0.3 to 2.5 μm on the convexities of the irregularities (A1), As will be described later, in the manufacturing process of the solar cell encapsulant sheet, a method of transferring the shape of an embossing roller having irregularities of a shape to be imparted to the A surface to the A surface can be mentioned.

  As for the solar cell sealing material sheet of this invention, it is preferable that the average space | interval Sm (A1) of the said unevenness | corrugation (A1) is 100-2,000 micrometers. By setting the average distance Sm (A1) to 2,000 μm or less, the contact area between the sealing material sheets and between the sealing material sheet and the solar battery cell is reduced, and the solar battery cell during blocking and laminating during storage. It is easy to obtain the effect of suppressing the positional deviation. On the other hand, by setting the average interval Sm (A1) of the unevenness (A1) to 100 μm or more, the gap of the encapsulant sheet is reduced, and bubbles remain between the encapsulant sheet and the solar battery cells during lamination. The risk of deteriorating the appearance of the module can be reduced.

  In addition, the average interval Sm (A1) of the unevenness (A1) means the Sm value obtained in the measurement of Ra (A1).

  About the solar cell sealing material sheet of this invention, in order to set the average space | interval Sm (A1) of an unevenness | corrugation (A1) to 100-2,000 micrometers, as mentioned later, in the manufacturing process of a solar cell sealing material sheet, The method of transferring the shape of the embossing roller which has the average space | interval Sm of the unevenness | corrugation to give to this A surface with respect to A surface can be mentioned.

  In the solar cell encapsulant sheet of the present invention, it is preferable that the average interval Sm (A2) of the unevenness (A2) is 5 to 80 μm. By setting the average interval Sm (A2) of the fine irregularities (A2) to 80 μm or less, it is easy to obtain the effect of blocking during storage and suppressing the positional deviation of the solar cells during lamination as described above. On the other hand, by setting the average interval Sm (A2) of the projections and depressions (A2) to 5 μm or more, it is possible to reduce the risk that bubbles remain and the appearance of the module is deteriorated as described above. If the average interval Sm (A2) of the irregularities (A2) is less than 5 μm, the risk that bubbles remain may increase.

  In addition, the average space | interval Sm (A2) of an unevenness | corrugation (A2) means the Sm value obtained in the measurement of Ra (A2).

  About the solar cell sealing material sheet | seat of this invention, in order to set the average space | interval Sm (A2) of an unevenness | corrugation (A2) to 5-80 micrometers, as mentioned later, in the manufacturing process of a solar cell sealing material sheet, it is A surface. In contrast, a method of transferring an embossing roller having an average interval Sm of unevenness to be imparted to the A surface can be mentioned.

  The solar cell encapsulant sheet of the present invention has an average interval Sm (A-MD) [μm] in the sheet flow direction and an average interval Sm (A-TD) in the direction orthogonal to the sheet flow direction with respect to the A plane. [Μm] ratio (Sm (A-MD) / Sm (A-TD)) is preferably 1.1-5. By increasing the average interval Sm (A-MD) in the sheet flow direction, a long uneven shape is formed along the sheet flow direction, and between the embossing roller and the sheet at the time of manufacturing the sealing material sheet described later. The amount of air biting is reduced, and bubble defects due to air biting can be reduced. By making the above ratio (Sm (A-MD) / Sm (A-TD)) 1.1 or more, the effect of reducing bubble defects can be easily obtained, and by making it 5 or less, the direction of blocking resistance. Unevenness can be suppressed.

  About solar cell sealing material sheet | seat of this invention, in order to set ratio (Sm (A-MD) / Sm (A-TD)) to 1.1-5, as mentioned later, solar cell sealing material sheet In the manufacturing process, the method of transferring the shape of the embossing roller having the ratio of the average distance Sm to be applied to the A surface to the A surface can be mentioned.

  The sealing material sheet of the present invention can also have an uneven shape similar to that of the A surface for the B surface, but preferably the B surface has unevenness (average roughness Ra (B1) of 0.5 to 4 μm). B1) and the average interval Sm (B1) of the irregularities (B1) is 10 to 400 μm.

  The sealing material sheet of the present invention is easy to obtain the effect of suppressing the positional deviation of the solar cells as described above by laminating and laminating the A surface toward the solar cells. On the other hand, the B surface comes into contact with the glass or the back sheet, and the one having a larger friction coefficient with the glass or the back sheet is in close contact with the glass or the back sheet, and the sealing material sheet is fixed. Is less likely to occur, and the positional deviation of the cell is reduced. Therefore, for the B surface, it is preferable that the average roughness Ra (B1) of the unevenness (B1) is 0.5 to 4 μm, which is lower than the Ra (A1) of the A surface and the friction system number is increased. By making Ra (B1) 0.5 μm or more, it is preferable in that blocking between the sealing material sheets can be suppressed, and by making it 4 μm or less, it is preferable that the positional deviation of the cells hardly occurs.

  Moreover, about the average space | interval Sm (B1) of an unevenness | corrugation (B1), it is preferable at the point which can block blocking of sealing material sheets by making the range into 400 micrometers or less, By making it into 10 micrometers or more, at the time of lamination The risk that air bubbles remain between the encapsulant sheet and the glass or the back sheet to deteriorate the appearance of the module can be reduced.

  In addition, the measuring method of average roughness Ra (B1) of B surface is mentioned later.

  Further, the average interval Sm (B1) of the unevenness (B1) means the Sm value obtained in the measurement of Ra (B1).

  About the solar cell sealing material sheet of this invention, average roughness Ra (B1) has the unevenness | corrugation (B1) of 0.5-4 micrometers, and the average space | interval Sm (B1) of this unevenness | corrugation (B1) is 10-400 micrometers. In order to form the B surface, as described later, in the manufacturing process of the solar cell encapsulant sheet, the shape of the embossing roller having irregularities of the shape to be imparted to the B surface is transferred to the B surface. Can be mentioned.

  Such a solar cell sealing material sheet is cut into a cut sheet having a desired length and used for manufacturing a solar cell module.

  The solar cell module of the present invention includes a light-receiving surface protective material, a solar cell encapsulant sheet of the present invention, a solar cell, a solar cell encapsulant sheet of the present invention, and a back surface protective material arranged in this order, and sealed. Obtained by stopping. Since the sealing material sheet of the present invention can suppress blocking at the time of storage of the solar cell sealing material, it is excellent in work efficiency when laminating the materials having the above-described structure, and the positional deviation of the cells when being integrated by laminating. Since defects can be suppressed, a solar cell module with excellent long-term durability is obtained.

  Furthermore, the solar cell module of the present invention has a light receiving surface protective material, a solar cell encapsulant sheet of the present invention, a solar cell, a solar cell encapsulant sheet of the present invention, and a back surface protective material in this order, It is a module obtained by sealing. Furthermore, it is preferable that the said photovoltaic cell is obtained by arrange | positioning so that the A surface side of the said solar cell sealing material sheet may be contact | connected. By setting it as the solar cell module of such arrangement | positioning, it is preferable at the point from which the effect which suppresses the position shift of a photovoltaic cell becomes easier to be acquired.

  In the present invention, the blocking resistance and the A-surface static friction coefficient described in the examples are employed as methods for simply evaluating blocking during storage and positional deviation of solar cells during lamination, respectively. Smaller values are better with less risk of blocking during storage and cell positional deviation.

  Hereinafter, the preferable manufacturing method for obtaining the sealing material sheet of this invention is demonstrated.

  The unevenness (unevenness (A1), unevenness (A2), unevenness (A3), unevenness (B1)) of the solar cell encapsulant sheet of the present invention is a metal embossing roller or rubber embossing having similar unevenness. It can be applied by transfer from a roller. Preferably, for the purpose of improving the transferability of the unevenness, the process sheet in a high temperature state (here, the process sheet is a sealing material sheet before forming the unevenness) on two embossing rollers made of metal and rubber facing each other In other words, a method of introducing the sealing material sheet of the present invention by providing irregularities (A1) and irregularities (A2) to the process sheet can be mentioned. Moreover, in the solar cell encapsulant sheet, when it is desired to simultaneously provide the unevenness of the A surface and the B surface (unevenness (A1), unevenness (A2), unevenness (A3), unevenness (B1)), A process sheet in a high temperature state is introduced into a metal embossing roller having the same unevenness as the rough A surface and a rubber embossing roller having the same unevenness as the facing relatively uneven fine B surface, and the above A surface , Unevenness on both sides B (unevenness (A1), unevenness (A2), unevenness (A3), unevenness (B1)) can be provided at a time.

  The measurement method used in this example is shown below. Unless otherwise specified, the number of measurement n was 5, and the average value was adopted.

(1) Ra (A1) of unevenness (A1)
The surface A of the encapsulant sheet is photographed at a magnification of 100 using a shape measurement laser microscope VK-X100 (manufactured by Keyence Corporation) in accordance with JIS B0601 (2001). Using the obtained image, a contour curve is created so that the evaluation length is 2500 μm, and the Ra value when the cutoff value (λc) is 8.0 mm and the cutoff value (λs) is 0.25 μm Ra (A1). Arbitrary measurement was performed with n number of 10 in each of two orthogonal directions, and an average value in the two directions was adopted.

(2) Sm (A1) of unevenness (A1)
The Sm value (average value in two directions) obtained in the measurement of Ra (A1) was defined as Sm (A1).

(3) Ra (A2) of unevenness (A2)
For the A surface of the encapsulant sheet, the magnification was taken at 400, the evaluation length was changed to 100 μm to create a contour curve, the cut-off value (λc) was changed to 0.080 mm, and the others were average roughness Ra Ra value (average value in two directions) when measured by the same method as (A1) was defined as Ra (A2).

(4) Unevenness (A2) Sm (A2)
The Sm value (average value in two directions) obtained in the measurement of Ra (A2) was defined as Sm (A2).

(5) Ra (A3) of unevenness (A3)
About the image obtained by (1), the convex part of the unevenness | corrugation (A1) was calculated | required by drawing an outline curve and an average line according to JISB0601 (2001). And the convex part arbitrarily selected in this unevenness | corrugation (A1) (In addition, the convex part selected arbitrarily here is a convex part arbitrarily selected in the length of a convex part 40 micrometers or more. ), The magnification is 400, the evaluation length is changed to 40 μm to create a contour curve, the cut-off value (λc) is changed to 0.080 mm, and the others are the same as the average roughness Ra (A1). Ra (A3) was defined as the Ra value (average value in two directions) when the same portion as the average roughness Ra (A1) was measured by the method. In addition, when the length of all the convex portions of the unevenness (A1) in the image obtained in (1) is less than 40 μm, the convex length arbitrarily selected for the evaluation length of the arbitrarily selected convex portion The length of the part was set and measured.

(6) Sm ratio (ratio (Sm (A-MD) / Sm (A-TD) is hereinafter simply referred to as Sm ratio))
With respect to the Sm value obtained by measuring the A-side of the sheet along the sheet flow direction under the conditions described in (1), the average value of n number 10 was defined as Sm (A-MD).

  Similarly, the average value of the Sm values obtained by measuring along the direction orthogonal to the sheet flow direction was Sm (A-TD).

  The ratio (Sm (A-MD) / Sm (A-TD)) was determined from the obtained Sm (A-MD) and Sm (A-TD).

(7) Ra (B1)
When the B surface of the encapsulant sheet is measured by the same method as the average roughness Ra (A1) except that the magnification is 200, the evaluation length is 500 μm, and the cutoff value (λc) is 0.8 mm. Ra value (average value in two directions) was defined as Ra (B1).

(8) Sm (B1)
The Sm value (average value in two directions) obtained in the measurement of Ra (B1) was defined as Sm (B1).

(9) At the time of manufacture of the sealing material sheet with or without air biting into the embossing roller The presence or absence of air between the metal embossing roller and the sealing material sheet after passing through the embossing roller was visually observed.

(10) Two test pieces having a size of 100 mm in the sheet flow direction and 50 mm in the width direction were cut out from the blocking-resistant sealing material sheet. Two pieces of this test piece are laminated so that the A side and the B side are in contact with each other, and an area of 2/3 (66 mm × 50 mm) from one end in the flow direction of the encapsulant sheet is applied on one side with a silicone release agent. The PET (polyethylene terephthalate) release film is sandwiched so that the silicone-coated surface and the sealing material sheet are in contact with each other, and the outside of the PET release film is further halved from one end in the flow direction of the sealing material sheet. An area (50 mm × 50 mm) is sandwiched between two glass plates, and a weight is placed on the glass plate so that the load applied to the area is 5 kg. The sample set as described above was treated in an oven at 40 ° C. for 24 hours, and then left in an atmosphere of 23 ° C. and 65% humidity for 30 minutes or more with the load removed. Then, the glass plate (2 sheets) was removed from the sample. Next, these two samples (that is, two sealing material sheets as test pieces) are peeled 180 °, and the peel force is measured using a tensile tester (Autograph ASG-J, manufactured by Shimadzu Corporation). , Measured at 200 mm / min.

(11) Coefficient of static friction coefficient of surface A The surface A of the sealing material sheet is sealed with a slider (brass, hard chrome treatment, 40 g) using a friction meter (HEIDON tribogear Muse TYPE: 94i manufactured by Shinto Kagaku Co., Ltd.) The static friction coefficient with the A surface of the stopping material sheet was measured. The measurement was performed with n number of 20, and the average value was adopted.

Example 1
EVA resin (vinyl acetate content: 28% by mass, melt flow rate: 15 g / 10 min (190 ° C.), melting point: 71 ° C.) 100 parts by mass, t-butylperoxy-2-ethylhexyl monocarbonate (1 (Time half-life temperature: 119 ° C.) 0.7 parts by mass was supplied to a twin-screw extruder, melted and kneaded, and extruded from a T-die to obtain an EVA sheet having a thickness of 450 μm. This EVA sheet is heated to a sheet temperature of 70 ° C. with a ceramic heater, and in the heated state, a SUS (stainless steel) embossing roller (surface temperature of 25 ° C.) and a silicon rubber embossing roller (surface temperature). 25 ° C.) (linear pressure: 350 N / cm) to obtain a sealing material sheet.

  Ra (A1), Sm (A1), Ra (A2), Sm (A2), Ra (A3), Sm ratio, Ra (B1), Sm (B1) and air to the embossing roller of the obtained sheet The presence or absence of biting, blocking resistance, and the static friction coefficient of the A surface were evaluated. The results are shown in Table 1. As shown in Table 1, it was a sealing material sheet with little air biting into the embossing roller and excellent in blocking resistance and static friction coefficient.

(Example 2)
A sealing material sheet was prepared in the same manner as in Example 1 except that the SUS embossing roller was changed so that Ra (A1) of the sheet was small. As shown in Table 1, the obtained encapsulant sheet was an encapsulant sheet with little air biting into the embossing roller and excellent in blocking resistance and static friction coefficient.

(Example 3)
A sealing material sheet was prepared in the same manner as in Example 1 except that the SUS embossing roller was changed so that Ra (A1) of the sheet was increased. As shown in Table 1, the obtained encapsulant sheet was an encapsulant sheet with little air biting into the embossing roller and excellent in blocking resistance and static friction coefficient.

Example 4
A sealing material sheet was prepared in the same manner as in Example 1 except that the SUS embossing roller was changed so that Ra (A1) of the sheet was increased. As shown in Table 1, the obtained encapsulant sheet was an encapsulant sheet with little air biting into the embossing roller and excellent in blocking resistance and static friction coefficient.

(Example 5)
A sealing material sheet was prepared in the same manner as in Example 1 except that the SUS embossing roller was changed so that Ra (A2) of the sheet was small. As shown in Table 1, the obtained encapsulant sheet was an encapsulant sheet with little air biting into the embossing roller and excellent in blocking resistance and static friction coefficient.

(Example 6)
A sealing material sheet was prepared in the same manner as in Example 1 except that the SUS embossing roller was changed so that Ra (A2) of the sheet was increased. As shown in Table 1, the obtained encapsulant sheet was an encapsulant sheet with little air biting into the embossing roller and excellent in blocking resistance and static friction coefficient.

(Example 7)
A sealing material sheet was prepared in the same manner as in Example 1 except that the SUS embossing roller was changed so that the Sm (A1) of the sheet was increased. As shown in Table 1, the obtained encapsulant sheet was slightly inferior in blocking resistance and static friction coefficient, but was an encapsulant sheet with little air biting into the embossing roller.

(Example 8)
A sealing material sheet was prepared in the same manner as in Example 1 except that the SUS embossing roller was changed so that Ra (A3) of the sheet was small. As shown in Table 1, the obtained encapsulant sheet was slightly inferior in blocking resistance and static friction coefficient, but was an encapsulant sheet with little air biting into the embossing roller.

Example 9
A sealing material sheet was prepared in the same manner as in Example 1 except that the SUS embossing roller was changed so that the Sm (A2) of the sheet was increased. As shown in Table 1, the obtained encapsulant sheet was slightly inferior in blocking resistance and static friction coefficient, but was an encapsulant sheet with little air biting into the embossing roller.

(Example 10)
A sealing material sheet was prepared in the same manner as in Example 1 except that the SUS embossing roller was changed so that the Sm ratio of the sheet was 1.0. As shown in Table 1, the obtained encapsulant sheet was confirmed to be air-engaged with the embossing roller, but was an encapsulant sheet excellent in blocking resistance and static friction coefficient.

(Example 11)
A sealing material sheet was prepared in the same manner as in Example 1 except that the silicon rubber embossing roller was changed so that Ra (B1) of the sheet was small. As shown in Table 1, the obtained encapsulant sheet was slightly inferior in blocking resistance, but it was an encapsulant sheet with little air biting into the embossing roller and excellent in the coefficient of static friction.

(Example 12)
A sealing material sheet was prepared in the same manner as in Example 1 except that the silicon rubber embossing roller was changed so that the Sm (B1) of the sheet was increased. As shown in Table 1, the obtained encapsulant sheet was slightly inferior in blocking resistance, but it was an encapsulant sheet with little air biting into the embossing roller and excellent in the coefficient of static friction.

(Example 13)
A sealing material sheet was prepared in the same manner as in Example 1 except that the SUS embossing roller was changed so that the Sm (A2) of the sheet was increased. As shown in Table 1, the obtained encapsulant sheet was an encapsulant sheet with little air biting into the embossing roller and excellent in blocking resistance and static friction coefficient.

(Comparative Example 1)
A sealing material sheet was prepared in the same manner as in Example 1 except that the SUS embossing roller was changed so that Ra (A1) of the sheet was small. As shown in Table 1, the obtained encapsulant sheet was an encapsulant sheet with less air biting into the embossing roller but inferior in blocking resistance and static friction coefficient.

(Comparative Example 2)
A sealing material sheet was prepared in the same manner as in Example 1 except that the SUS embossing roller was changed so that Ra (A2) of the sheet was small. As shown in Table 1, the obtained encapsulant sheet was an encapsulant sheet with less air biting into the embossing roller but inferior in blocking resistance and static friction coefficient.

  In the table, “Sm ratio” indicates “Sm (A-MD) / Sm (A-TD)”.

Since the sealing material sheet of the present invention can simultaneously suppress problems of blocking during storage of the solar cell sealing material and positional displacement of the cells during lamination in the manufacturing process of the solar cell, as a sealing material sheet for solar cells Preferably used.

A: Contour curve
B: Concavity and convexity (A1)
C: Concavity and convexity (A2)
D: Average line
E: Convex part (A1) convex part (the hatched part in the figure is the convex part (A1) convex part)

Claims (8)

  When one surface is the A surface and the other surface is the B surface, the A surface has irregularities (A1) with an average roughness Ra (A1) of 3 to 95 μm and an average roughness Ra (A2) of 0. A solar cell encapsulant sheet, having unevenness (A2) of 3 to 2.5 μm.   2. The solar cell encapsulant sheet according to claim 1, wherein the projections of the irregularities (A1) have irregularities (A3) having an average roughness Ra (A3) of 0.3 to 2.5 μm. .   The solar cell sealing material sheet according to claim 1 or 2, wherein an average interval Sm (A1) of the unevenness (A1) is 100 to 2,000 µm.   The solar cell sealing material sheet according to any one of claims 1 to 3, wherein an average interval Sm (A2) of the unevenness (A2) is 5 to 80 µm.   The ratio of the average interval Sm (A-MD) [μm] in the sheet flow direction to the average interval Sm (A-TD) [μm] in the direction orthogonal to the sheet flow direction (Sm (A-MD) ) / Sm (A-TD)) is 1.1-5, The solar cell sealing material sheet in any one of Claims 1-4 characterized by the above-mentioned.   The B surface has irregularities (B1) having an average roughness Ra (B1) of 0.5 to 4 μm, and an average interval Sm (B1) of the irregularities (B1) is 10 to 400 μm. The solar cell sealing material sheet according to any one of claims 1 to 5.   A light-receiving surface protective material, the solar cell sealing material sheet according to any one of claims 1 to 6, a solar battery cell, the solar cell sealing material sheet according to any one of claims 1 to 6, and a back surface protective material. A solar cell module obtained by arranging and sealing in this order.   The solar cell module according to claim 7, wherein the solar cell is disposed so as to be in contact with the A surface side of the solar cell encapsulant sheet.

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