JP2015113169A - Solar battery module packing member - Google Patents

Abstract

PROBLEM TO BE SOLVED: To obtain a solar battery module packing member difficult to deviate from solar battery modules and capable of improving stacking efficiency of the solar battery modules.SOLUTION: A solar battery module packing member includes: a sidewall 107a abutting on side surfaces 104 and 114 of frame 101 and 111; and a top surface 105 covering a corner of a first solar battery module 100a that extends from a central portion of the sidewall 107a in a thickness direction and that is arranged on a lower side, and mounting and receiving a lower flange 113 of a second solar battery module 110a that is arranged on an upper side, the top surface 105 including a protruding shape 106 provided on a lower surface thereof for restricting the solar battery module packing member from moving laterally to the first solar battery module 100a arranged on the lower side, and including an engagement portion 109 provided on an upper surface thereof for restricting the solar battery module packing member from moving laterally to the second solar battery module 110a arranged on the upper side.

Description

  The present invention relates to a packaging member for a solar cell module that is attached to a corner portion of the solar cell module to prevent a load slip during transportation.

  Conventionally, when transporting a solar cell module having a solar cell of a crystalline system using a wafer mainly made of silicon or a compound thin film system such as silicon or CIS (Cupper Indium Selenium), In some cases, the solar cell module is packaged in order to prevent it from coming into contact with other solar cell modules and damaging other articles and people.

  When packaging an article, the entire article may be packaged, or a part of the article, for example, only an end or a corner may be packaged. Various packaging materials (packaging members) are developed depending on the application. Has been.

  Patent Document 1 discloses a corner pad capable of simultaneously performing a stacking operation of solar cell modules and a mounting operation of a corner member to the solar cell module.

JP 2012-243963 A

  However, Patent Document 1 discloses a corner pad having a structure portion that snap-engages with a flange portion on the back surface of a frame mainly composed of an aluminum alloy or the like provided around a solar cell module. If a corner pad is placed on the top surface of the battery module, there is no structure that suppresses horizontal movement, so if you touch it inadvertently during loading, it may be displaced from the desired position or fall off. is there. For this reason, it is hard to say that it is preferable to load the solar cell module on the corner pad disclosed in Patent Document 1.

  Further, in the corner pad disclosed in Patent Document 1, a certain amount of space is required between the modules to be stacked due to the structure in which the snap engagement portion has a spring property. As a result, the space occupied by one solar cell module increases, and for example, the number of solar cell modules that can be loaded on a transportation truck or the like decreases.

  This invention is made | formed in view of the above, Comprising: It aims at obtaining the packing member for solar cell modules which is hard to slip | deviate from a solar cell module and can improve the lamination | stacking efficiency of a solar cell module.

  In order to solve the above-described problems and achieve the object, the present invention provides a solar cell panel having a rectangular shape, a side surface portion, an upper flange portion extending from the upper end of the side surface portion, and a solar cell from the upper end of the side surface portion. A fitting that has a middle flange portion that extends from a position lowered by the thickness of the panel and a lower flange portion that extends from the lower end of the side surface portion, and is surrounded by the side surface portion, the upper flange portion, and the middle flange portion. Solar cell module that protects each corner portion of a solar cell module that includes a frame that is fitted with a solar cell panel and is attached to each side of the solar cell panel, and is sandwiched between stacked solar cell modules An orthogonal wall that is in contact with two side surfaces of the corner portion of the solar cell module, and a corner portion of the solar cell module that is disposed on the lower side and extends from a central portion in the thickness direction of the orthogonal wall. From above And a top surface portion for receiving the lower flange portion of the solar cell module disposed on the upper side, and the top surface portion has a lower surface with a protrusion for restricting lateral movement relative to the solar cell module disposed on the lower side. It is provided with the engaging part which regulates the movement of the horizontal direction with respect to the solar cell module arrange | positioned at an upper side while being provided in a side, It is characterized by the above-mentioned.

  According to the present invention, when the solar cell module is loaded on a pallet for transportation after being manufactured, it is arranged on the upper surface of each corner portion of the solar cell module, so that the projection shape and the side wall portion matched to the upper surface shape of the frame. Since the solar cell module can be arranged on the top without being easily displaced because it is positioned, and it is engaged with the back surface of the frame of the solar cell module arranged on the top, after loading a plurality of sheets, when transporting, etc. There is an effect that it is possible to suppress the load slippage due to the vibrations.

FIG. 1 is a view showing a state in which a solar cell module is loaded on a pallet using a corner pad as an embodiment of a packaging member for a solar cell module according to the present invention. FIG. 2 is a side view of the solar cell module loaded using the solar cell module packaging member. FIG. 3 is a partial plan view of the solar cell module loaded using the solar cell module packaging member. FIG. 4 is a partial cross-sectional view of a solar cell module loaded using a solar cell module packaging member. FIG. 5 is a partial cross-sectional view of the engaging portion between the corner pad and the frame. FIG. 6 is a partial cross-sectional view of the engaging portion between the corner pad and the frame. FIG. 7 is a diagram showing a state in which two solar cell modules loaded on a pallet are fastened by a fastening band.

  DESCRIPTION OF EMBODIMENTS Embodiments of a solar cell module packaging member according to the present invention will be described below in detail with reference to the drawings. Note that the present invention is not limited to the embodiments.

Embodiment.
FIG. 1 is a view showing a state in which a solar cell module is loaded on a pallet using a corner pad as an embodiment of a packaging member for a solar cell module according to the present invention. FIG. 2 is a side view of the solar cell module loaded using the solar cell module packaging member. FIG. 3 is a partial plan view of the solar cell module loaded using the solar cell module packaging member. FIG. 4 is a partial cross-sectional view of the solar cell module loaded using the solar cell module packaging member, and shows a cross section taken along line IV-IV in FIG. 3. FIG. 5 is a partial cross-sectional view of an engagement portion between the corner pad and the frame, and shows an A portion in FIG. 4 in an enlarged manner. FIG. 6 is a partial cross-sectional view of an engagement portion between the corner pad and the frame, and shows an enlarged B portion in FIG.

  The first solar cell module 100 includes a solar cell panel 100a and a frame 101. Frame 101 surrounds the outer edge of solar cell panel 100a and holds solar cell panel 100a. The first solar cell module 100 has four corner portions, and a corner pad 30 is disposed on the module surface side of each corner portion.

  The solar cell panel 100a is a rectangular flat plate member in which a plurality of solar cells (not shown) are arranged and electrically connected, and the solar cell panel 100a and an external load are electrically connected to the back surface thereof. A terminal box (not shown) is arranged. The frame 101 has a rectangular frame shape, holds the solar cell panel 100a, and is fixed to the gantry when the first solar cell module 100 is installed.

  The frame 101 includes a side surface portion 104, an upper flange portion 101 a extending from the upper end of the side surface portion 104, a lower flange portion 103 extending from the lower end of the side surface portion 104, and a solar cell panel 100 a generally from the upper end of the side surface portion 104. And an intermediate flange portion 120 extending from a position lowered by the thickness of the inner flange portion 120. A portion surrounded by the side surface portion 104, the upper flange portion 101a, and the middle flange portion 120 serves as a solar cell panel fitting portion 121, and the solar cell panel 100a is fitted to the solar cell panel fitting portion 121. Is retained. The lower flange portion 103 is used for fixing when the first solar cell module 100 is installed on a frame or the like. The lower flange portion 103 extends from the lower end of the side surface portion 104 toward the center portion of the solar cell panel 100 a and forms the bottom surface of the frame 101. The side surface portion 104 forms the outer surface of the corner portion of the first solar cell module 100.

  The upper flange portion 101a of the frame 101 of the first solar cell module 100 is formed so as to become thinner toward the central portion of the solar cell panel 100a so as not to block sunlight incident on the solar cell panel 100a. An inclined surface portion 102 is provided at the tip portion.

  The structure of the second solar cell module 110 is the same as that of the first solar cell module 100, and includes a solar cell panel 110a and a frame 111. The frame 111 surrounds the outer edge of the solar cell panel 110a and holds the solar cell panel 110a. The second solar cell module 110 has four corner portions, and a corner pad 30 is disposed on the module surface side of each corner portion.

  The solar cell panel 110a is a rectangular flat plate member in which a plurality of solar cells (not shown) are arranged and electrically connected, and the solar cell panel 110a and an external load are electrically connected to the back surface thereof. A terminal box (not shown) is arranged. The frame 111 has a rectangular frame shape, holds the solar cell panel 110a, and is fixed to the gantry when the second solar cell module 110 is installed.

  The frame 111 includes a side surface portion 114, an upper flange portion 111a extending from the upper end of the side surface portion 114, a lower flange portion 113 extending from the lower end of the side surface portion 114, and a solar cell panel 110a generally from the upper end of the side surface portion 114. And an intermediate flange portion 122 extending from a position lowered by the thickness of the intermediate flange portion 122. The portion surrounded by the side surface portion 114, the upper flange portion 111a, and the middle flange portion 122 is a solar cell panel fitting portion 123, and the solar cell panel 110a is fitted to the solar cell panel fitting portion 123. Is retained. The lower flange portion 113 is used for fixing when the second solar cell module 110 is installed on a frame or the like. The lower flange portion 113 extends from the lower end of the side surface portion 114 toward the center portion of the solar cell panel 110a and forms the bottom surface of the lower frame 113. The side surface portion 114 forms the outer surface of the corner portion of the second solar cell module 110.

  The upper flange portion 111a of the frame 111 of the second solar cell module 110 is formed to become thinner toward the center of the solar cell panel 110a so as not to block sunlight incident on the solar cell panel 110a. An inclined surface portion 112 is provided.

  The corner pad 30 has side wall portions 107 (107a, 107b) and a top surface portion 105. The side wall 107b is located on an extension of the side wall 107a. The two side wall portions 107 are orthogonal to the side surface portion 104 of the frame 101 of the first solar cell module disposed below and the side surface portion 114 of the frame 111 of the second solar cell module disposed above. doing. That is, the two side wall portions 107 are orthogonal walls. The top surface portion 105 protrudes in a bowl shape from the central portion (generally intermediate height) in the thickness direction of the side wall portion 107 to the inside of the corner sandwiched between the two side wall portions 107. Note that the side wall 107a and the side wall 107b need not have the same height.

  On the lower surface of the top surface portion 105, a protruding shape 106 having an inclined surface portion 106a facing the inclined surface portion 102 formed on the upper flange portion 101a of the frame 101 of the first solar cell module 100 is provided. That is, the protrusion shape 106 is a shape that engages with the inclined surface portion 102 that is the tip portion of the upper flange portion 101 a of the frame 101 in surface contact. When the protrusion shape 106 is in surface contact with the tip of the upper flange portion 101a, the corner pad 30 is less likely to be displaced with respect to the first solar cell module. An open concave notch 108 is formed at the upper end of the side wall 107a.

  On the upper surface of the top surface portion 105, an inner edge portion 103a of the lower flange portion 103 and a protrusion-shaped engagement portion 109 that engages with the inner edge portion 113a of the lower flange portion 113 are formed. The engaging portion 109 includes a rising portion 109a that stands up to a height slightly higher than the lower flange portion 103, and a return portion 109b that extends from the upper end of the rising portion 109a toward the side wall portion 107. Yes. The rising portion 109 a is formed in parallel with the side wall portion 107, and the distance between the rising portion 109 a and the side wall portion 107 is substantially the same as the width dimension of the lower flange portion 103. Therefore, for convenience, the top surface of the top surface portion 105 can be divided into an L-shaped stepped lower portion 105a along the side wall portion 107 and a stepped upper portion 105b farther from the side wall portion 107 than the rising portion 109a.

  The corner pad 30 is formed by plastic molding, for example. If the top surface portion 105 is too thick, sink marks will occur during molding, or the flatness will deteriorate and a gap will tend to occur when engaged with the first and second solar cell modules 100 and 110. If the plate | board thickness of the top | upper surface part 105 shall be 3 mm or less, these problems will hardly generate | occur | produce.

  Next, a procedure for loading the solar cell module 100 on a pallet or the like will be described. First, the corner pad 30 is disposed on the corner portion of the first solar cell module 100. The corner pad 30 disposed on the upper surface of the corner portion of the first solar cell module 100 has a top surface portion 105 disposed in parallel with the solar cell panel 100a, and a protrusion shape 106 formed on the lower side of the top surface portion 105 has a first shape. It contacts the inclined surface portion 102 formed on the upper surface of the frame 101 of the solar cell module. Moreover, the upper end vicinity of the side part 104 of the two flame | frames 101 of the 1st solar cell module 100 is covered in contact with the side wall part 107a. That is, the side wall portion 107 a that is an orthogonal wall contacts the side surface portion 104 that forms the outer surface of the corner portion of the first solar cell module 100. Thereby, the protrusion shape 106 and the side wall portion 107a are in a state of sandwiching the upper flange portion 101a of the first solar cell module 100, and the corner pad 30 moves laterally with respect to the first solar cell module 100. That is regulated. Further, the corner portion of the first solar cell module 100 is covered with the top surface portion 105 from above.

  Then, the 2nd solar cell module 110 is arrange | positioned through the corner pad 30 above the 1st solar cell module 100. FIG. That is, the lower flange portion 113 of the second solar cell module 110 is placed on the top surface portion 105. At this time, the lower flange portion 113 of the second solar cell module 110 is disposed on the stepped lower portion 105 a of the top surface portion 105. Since the height of the rising portion 109a is higher than that of the lower flange portion 103, the lower flange portion 103 is engaged with the engaging portion 109 in a state where the return portion 109b covers the inner edge portion 113a that is the tip portion of the lower flange portion 103 from above. Match. Further, the vicinity of the lower ends of the side surface portions 114 of the two frames 111 of the second solar cell module 110 is covered in contact with the side wall portion 107b. That is, the side wall portion 107 b that is an orthogonal wall contacts the side surface portion 114 that forms the outer surface of the corner portion of the second solar cell module 110. As a result, the engagement portion 109 and the side wall portion 107b are in a state of sandwiching the lower flange portion 113 of the second solar cell module 110, and the corner pad 30 moves laterally with respect to the second solar cell module 110. Doing is regulated.

  As described above, the corner pad 30 is prevented from being laterally shifted with respect to the first solar cell module 100 by the side wall portion 107a and the protrusion shape 106. In addition, the corner pad 30 is prevented from being laterally shifted with respect to the second solar cell module 110 by the side wall portion 107b and the engaging portion 109.

  As described above, the corner pad 30 is in contact with the inclined surface portion 102 and the side surface portion 104 of the frame of the first solar cell module 100 and is engaged with the inner edge portion 113a of the lower flange 113 of the second solar cell module 110. It is arranged between the first solar cell module 100 and the second solar cell module 110 so as to be in contact with the side surface portion 114. Thereafter, by repeating the same procedure, a plurality of solar cell modules can be easily and reliably stacked.

  Further, after loading a plurality of solar cell modules on the pallet for transportation 115, the fastening band 130 is engaged with the notch 108 provided in the corner pad, so that the transportation condition can be reduced. In addition, it is possible to more reliably prevent load slippage even against vertical vibration and impact in a container yard. FIG. 7 is a diagram showing a state in which two solar cell modules loaded on a pallet are fastened by a fastening band. By engaging the fastening band 130 with the notch 108, the corner pad 30 is prevented from longitudinal displacement with respect to the first and second solar cell modules 100 and 110.

  Furthermore, since the thickness of the top surface portion 105 of the corner pad 30 can be made thin with a plate thickness that allows plastic molding, the gap between the modules can be reduced. Thereby, it becomes possible to load more solar cell modules on the pallet 115 for transportation so as to engage with each other, and the transportation cost per sheet can be reduced. That is, by configuring the top surface portion 105 to be thin, more solar cell modules can be loaded within a limited height range. In addition, since the snap engagement structure is unnecessary when engaging with the first and second solar cell modules 100 and 110, the size of the corner pad itself can be reduced, and the waste material after use is reduced. be able to.

  In the above description, the projection provided on the lower surface side of the top surface portion has an example of a configuration having an inclined surface in surface contact with the inclined surface portion of the upper flange portion. However, the shape of the protrusion provided on the lower surface side of the top surface portion is not necessarily the upper flange. There is no need for the shape (transfer shape) to be in surface contact with the tip of the portion. In the above description, an example in which the inclined surface portion is provided on the upper flange portion of the frame is taken as an example, but the present invention is a packaging member for a solar cell module in which the inclined surface portion is not provided on the upper flange portion. It can also be implemented. When implemented as a packaging member for a solar cell module in which the upper flange portion is not provided with an inclined surface portion (the cross-sectional shape of the upper flange portion is rectangular), the top surface portion is in contact with the tip surface of the upper flange portion. By providing the protrusion on the lower surface (the protrusion is provided away from the side wall portion by the same distance as the width dimension of the upper flange portion), the lateral displacement of the corner pad can be prevented. In this case, even if the protrusion provided on the lower surface side of the top surface portion has a shape that does not come into surface contact with the tip portion of the upper flange portion, for example, a hemispherical shape or a cylindrical shape, it is possible to prevent the lateral displacement of the corner pad. As described above, the protrusion provided on the lower surface side of the top surface portion may have any shape as long as the lateral movement of the corner pad with respect to the solar cell module disposed on the lower side can be restricted.

  Similarly, the engaging portion that engages with the lower flange portion of the solar cell module disposed on the upper side is not limited to the structure having the rising portion and the return portion, and restricts the lateral movement of the lower flange portion. Any other structure can be used as long as it can.

  As described above, the packaging member for a solar cell module according to the present invention is useful for packaging the solar cell module and improving the transportation efficiency.

  30 corner pad, 100 first solar cell module, 100a, 110a solar cell panel, 101, 111 frame, 101a, 111a upper flange portion, 102, 106a, 112 inclined surface portion, 103, 113 lower flange portion, 104, 114 side surface Part, 105 top surface part, 105a step lower part, 105b step upper part, 106 projection shape, 107, 107a, 107b side wall part, 108 notch, 109 engagement part, 109a rising part, 109b return part, 110 second solar cell module , 120, 122 Middle flange portion, 121, 123 Solar cell panel fitting portion, 130 Fastening band.

Claims (7)

A rectangular solar cell panel, a side surface portion, an upper flange portion extending from the upper end of the side surface portion, and an intermediate flange portion extending from a position lower than the upper end of the side surface portion by the thickness of the solar cell panel And a lower flange portion extending from the lower end of the side surface portion, and the solar cell panel is fitted into a fitting portion surrounded by the side surface portion, the upper flange portion, and the middle flange portion. A solar cell module packaging member that protects each corner portion of a solar cell module comprising a frame attached to each side of the solar cell panel and is sandwiched between the stacked solar cell modules,
Side wall portions that form orthogonal walls that come into contact with two side surfaces of the corner portion of the solar cell module;
The corner portion of the solar cell module extending from the center portion in the thickness direction of the side wall portion and covering the corner portion of the solar cell module disposed on the lower side, and the lower flange portion of the solar cell module disposed on the upper side The top surface to receive,
Have
The top surface portion includes a protrusion on the lower surface side that restricts lateral movement relative to the solar cell module disposed on the lower side, and an engagement that regulates lateral movement relative to the solar cell module disposed on the upper side. A solar cell module packaging member, comprising a portion on the upper surface side.   2. The solar cell module packaging member according to claim 1, wherein the protrusion engages with a front end portion of the upper flange portion of the solar cell module disposed on the lower side. The tip portion of the upper flange portion disposed on the lower side is provided with an inclined surface portion that becomes thinner toward the center side of the solar cell panel,
The solar cell module packaging member according to claim 2, wherein the protrusion includes an inclined surface in surface contact with the inclined surface portion.   The said engaging part engages with the front-end | tip part of the said lower flange part of the said solar cell module arrange | positioned above, The packaging for solar cell modules of any one of Claim 1 to 3 characterized by the above-mentioned. Element.   The engaging part is separated from the side wall part by the same distance as the width of the lower flange part, and rises in parallel with the side wall part, and extends from the upper end of the rising part toward the side wall part. The solar cell module packaging member according to claim 4, further comprising an existing return portion.   The said side wall part covers the two side surfaces of the corner part of each solar cell module arrange | positioned up and down, The packaging member for solar cell modules of any one of Claim 1 to 5 characterized by the above-mentioned.   The solar cell module packaging member according to any one of claims 1 to 6, wherein the side wall portion has a notch formed at an upper end thereof.

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