JP3186278U - Outdoor structures - Google Patents

Abstract

An outdoor structure capable of easily and inexpensively obtaining electricity by photovoltaic power generation outdoors.
A structure 1 is provided at a crossing portion of a solar cell module 2, a connecting frame 3 having a rectangular cross-section in which a substantially groove-shaped guide groove 3a is formed in each side, and a connecting frame 3 that intersects. The connecting member 41 includes a connecting member 41, a nut 42 movably inserted along the guide groove 3 a of the connecting frame 3, and a bolt 43 that can be screwed to the nut 42. The connecting frame 3 is fixed to the frame members 23 and 24 of the solar cell module 2 via bolts 43 and nuts 42, and the connecting frame 3 extending in the vertical direction at each end of the connecting frame 3 is connected to the connecting member 4. It is erected through.
[Selection] Figure 2

Description

  This invention relates to an outdoor structure such as a pergola.

  In recent years, photovoltaic power generation has been widely used as renewable energy, and solar cell modules are installed in various places including the roof of a house. For example, since electricity can be supplied outdoors without laying an electric wire, it has been proposed to use it for lighting such as a carport (see, for example, Patent Documents 1 and 2).

Japanese Patent Laid-Open No. 11-303439 JP 2001-55782 A

  Such a solar cell module is constructed by combining structural elements such as beams and pillars and installed on the roof. That is, a construction is adopted in which a building contractor constructs a structure using dedicated beams, pillars, etc., and installs a solar cell module on a part of the roofing material. For this reason, there are disadvantages that the number of parts is increased and the cost is increased.

  This invention is made | formed in view of such a problem, and provides the outdoor structure which can obtain the electricity by photovoltaic power generation easily and cheaply outdoors.

  The present invention provides a solar cell module composed of a rectangular solar cell panel and a frame member disposed around the solar cell panel, and a plurality of rectangular cross sections each having a substantially guide groove formed in the longitudinal direction on each side. A connecting frame, a plurality of connecting members that can be disposed at the intersection of the intersecting connecting frames, a plurality of nuts that are movably inserted along the guide grooves of the connecting frame, and can be screwed to the nuts A connecting member composed of a plurality of bolts, and a connecting frame is fixed to at least one side of the frame member of the solar cell module via a bolt nut, and one or more extending in the vertical direction to the connecting frame The connecting frame is erected via a connecting member.

  According to the present invention, it becomes possible to obtain electricity by photovoltaic power generation by supporting a single solar cell module on a structure having a simple and inexpensive structure outdoors, and can be used as a charging station for various battery-powered devices. Or, it can be used as a security light by attaching lighting equipment.

  The present invention is composed of a rectangular solar cell panel and a frame member disposed around the solar cell panel, and a plurality of solar cell modules arranged in the lateral direction, and a substantially grooved guide groove on each side in the longitudinal direction. A plurality of connection frames having a square cross section formed, a plurality of connection members that can be disposed at the intersections of the crossing connection frames, and a plurality of nuts that are movably fitted along the guide grooves of the connection frames And a connecting member composed of a plurality of bolts that can be screw-coupled to the nut, and before and after extending in the lateral direction over the front side and the rear side of the frame member in the plurality of solar cell modules arranged in the lateral direction. The connection frame is fixed via bolts and nuts, and one or more connection frames extending in the vertical direction on one of the front and rear connection frames or the front and rear connection frames are erected via a connection member. And wherein the Rukoto.

  According to the present invention, it is possible to obtain electricity by photovoltaic power generation by supporting a plurality of solar cell modules arranged in a lateral direction on a structure having a simple and inexpensive structure outdoors, and various battery-driven devices. It can be used as a charging station, or it can be used as a security light with a lighting facility.

  The present invention is composed of a rectangular solar cell panel and a frame member disposed around the solar cell panel, and a plurality of solar cell modules arranged in the longitudinal direction, and a substantially grooved guide groove on each side in the longitudinal direction. A plurality of connection frames having a square cross section formed, a plurality of connection members that can be disposed at the intersections of the crossing connection frames, and a plurality of nuts that are movably fitted along the guide grooves of the connection frames And left and right connection frames extending in the vertical direction over the left and right sides of the frame member in the plurality of solar cell modules arranged in the vertical direction. Is fixed through bolts and nuts, and one or more connecting frames extending in the vertical direction on one of the left and right connecting frames or the left and right connecting frames are erected via the connecting members. And wherein the Rukoto.

  According to the present invention, it is possible to obtain electricity by photovoltaic power generation by supporting a plurality of solar cell modules arranged in the vertical direction on a structure having a simple and inexpensive structure outdoors. It can be used as a charging station, or it can be used as a security light with a lighting facility.

  The present invention comprises a rectangular solar cell panel and a frame member disposed around the solar cell panel, and a plurality of solar cell modules arranged in the vertical direction and the horizontal direction, respectively, and a guide groove that is substantially formed on each side. A plurality of connecting frames having a rectangular cross section formed in the longitudinal direction, a plurality of connecting members that can be disposed at the intersections of the connecting frames that intersect, and a plurality of nuts that are movable along the guide grooves of the connecting frames And a connecting member composed of a plurality of bolts that can be screwed to the nut, and extends in the lateral direction across the front side and the rear side of the frame member in the plurality of solar cell modules in each row arranged in the lateral direction. The front and rear connection frames are respectively fixed via bolts and nuts, and the left and right connection frames extending in the vertical direction are fixed to the left and right ends of the plurality of pairs of front and rear connection frames via connection members. In addition, the frontmost connection frame, the rearmost connection frame, the frontmost connection frame and the rearmost connection frame, or one of the left and right connection frames, or the left and right connection frames are vertically aligned. One or more extending connecting frames are erected via a connecting member.

  According to the present invention, it is possible to obtain electricity by photovoltaic power generation by supporting a plurality of solar cell modules arranged in the vertical and horizontal directions on a structure with a simple and inexpensive structure outdoors. It can be used as a charging station for various driving devices, or it can be used as a security light by attaching lighting equipment.

  The present invention comprises a rectangular solar cell panel and a frame member disposed around the solar cell panel, and a plurality of solar cell modules arranged in the vertical direction and the horizontal direction, respectively, and a guide groove that is substantially formed on each side. A plurality of connecting frames having a rectangular cross section formed in the longitudinal direction, a plurality of connecting members that can be disposed at the intersections of the connecting frames that intersect, and a plurality of nuts that are movable along the guide grooves of the connecting frames And a connecting member composed of a plurality of bolts that can be screwed to the nut, and extending in the vertical direction over the left side and the right side of the frame member in the plurality of solar cell modules in each row arranged in the vertical direction The connecting frames are fixed through bolts and nuts, and the front and rear connecting frames extending in the lateral direction are fixed to the front and rear ends of the plurality of pairs of left and right connecting frames through the connecting members. In addition, the leftmost connection frame, the rightmost connection frame, the leftmost connection frame and the rightmost connection frame, one of the front and rear connection frames, or the front and rear connection frames One or more connecting frames extending in the vertical direction are erected via a connecting member.

  According to the present invention, it is possible to obtain electricity by photovoltaic power generation by supporting a plurality of solar cell modules arranged in the vertical and horizontal directions on a structure with a simple and inexpensive structure outdoors. It can be used as a charging station for various driving devices, or it can be used as a security light by attaching lighting equipment.

  The present invention is composed of a rectangular solar cell panel and a frame member disposed around the solar cell panel, and a plurality of solar cell modules arranged in the lateral direction, and a substantially grooved guide groove on each side in the longitudinal direction. A plurality of connection frames having a square cross section formed, a plurality of connection members that can be disposed at the intersections of the crossing connection frames, and a plurality of nuts that are movably fitted along the guide grooves of the connection frames And a connecting member composed of a plurality of bolts that can be screw-coupled to the nut, and before and after extending in the lateral direction over the front side and the rear side of the frame member in the plurality of solar cell modules arranged in the lateral direction. The connection frame is fixed via bolts and nuts, and the connection frame extending in the vertical direction is fixed to the left and right ends of the front and rear connection frames via the connection members. A connecting frame extending in the vertical direction is provided on each part via a connecting member, and a connecting frame is fixed to each of the lower ends of a pair of adjacent struts via a connecting member, at least between a pair of adjacent struts. The door is provided to be openable and closable, and a wall panel is provided between the remaining adjacent columns.

  According to the present invention, it becomes possible to obtain electricity by photovoltaic power generation by supporting a plurality of solar cell modules arranged in the lateral direction on a structure having a simple and inexpensive structure outdoors, such as a storeroom or a disaster prevention warehouse. Can be used.

  The present invention is composed of a rectangular solar cell panel and a frame member disposed around the solar cell panel, and a plurality of solar cell modules arranged in the longitudinal direction, and a substantially grooved guide groove on each side in the longitudinal direction. A plurality of connection frames having a square cross section formed, a plurality of connection members that can be disposed at the intersections of the crossing connection frames, and a plurality of nuts that are movably fitted along the guide grooves of the connection frames And left and right connection frames extending in the vertical direction over the left and right sides of the frame member in the plurality of solar cell modules arranged in the vertical direction. Are fixed via bolts and nuts, and connecting frames extending in the lateral direction are fixed to the front and rear end portions of the left and right connecting frames via connecting members. A connecting frame extending in the vertical direction is provided on each part via a connecting member, and a connecting frame is fixed to each of the lower ends of a pair of adjacent struts via a connecting member, at least between a pair of adjacent struts. The door is provided to be openable and closable, and a wall panel is provided between the remaining adjacent columns.

  According to the present invention, it becomes possible to obtain electricity by photovoltaic power generation by supporting a plurality of solar cell modules arranged in the vertical direction on a structure having a simple and inexpensive structure outdoors. Can be used.

  According to the present invention, electricity by photovoltaic power generation can be easily and inexpensively obtained outdoors.

It is a perspective view which shows an example of the solar pergola which is one Embodiment of the outdoor structure of this invention. FIG. 2 is a cross-sectional view of the solar pergola in FIG. 1 taken along the line AA. It is a disassembled perspective view which shows the relationship between a connection frame and a connection member. It is a schematic perspective view which decomposes | disassembles and shows the modification of a solar pergola. It is a front view of the solar pergola of FIG. It is a perspective view which abbreviate | omits and shows the relationship between the solar cell module in the solar pergola of FIG. 4, a support frame, and a support | pillar. It is a perspective view which shows the aspect which fixes the support frame of a solar cell module to an inclined state via a connection member corresponding to FIG. It is a schematic perspective view which decomposes | disassembles and shows the other modification of a solar pergola. It is a schematic perspective view which decomposes | disassembles and shows another modification of a solar pergola. It is a perspective view which shows an example of the solar box which is other embodiment of the outdoor structure of this invention.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

  1 and 2 show an embodiment of the outdoor structure 1 of the present invention.

  This outdoor structure 1 is a solar pergola 1 </ b> A, and includes a single solar cell module 2, a plurality of connecting frames 3, and connecting members 4 that connect the connecting frames 3 and 3 that intersect each other.

  The solar cell module 2 includes a rectangular solar cell panel 21 and a frame member 22 attached to the periphery of the solar cell panel 21, specifically, a pair of opposed solar cell panels 21 arranged in a horizontally long shape. The first frame member 23 attached to the long side of the solar cell panel 21 and the second frame member 24 attached to the pair of short sides facing the solar cell panel 21 and connected to each other. It is a known product, and the first frame member 23 and the second frame member 24 have sub-bottom walls 231 and 241 (see FIG. 2) in which a plurality of mounting holes are formed so that they can be fixed to a roof material or the like. It is extended.

  Note that a terminal box and a cable (not shown) for taking out electricity are provided on the back surface of the solar cell panel 21.

  The connecting frame 3 is an aluminum pultruded product that is used after being cut to a set dimension, and is formed in a square cross-section. On each side of the connecting frame 3, a substantially grooved guide groove 3 a is formed along the longitudinal direction. (See FIG. 3).

  The connecting frame 3 includes a connecting frame having a square cross-section in which one guide groove is formed on each side. In addition, although not shown in detail, one guide groove is provided on each pair of opposing sides. A connecting frame having a rectangular cross section in which two guide grooves are formed on each of a pair of opposite sides is prepared. The connecting frame is appropriately selected according to the use site.

  As shown in FIG. 3, the connecting member 4 is formed in an L-shaped connecting member 41 and a nut 42 having a substantially trapezoidal cross section corresponding to the guide groove 3 a of the connecting frame 3 and having a female screw. And a bolt (with a hexagonal hole) 43 in which a male screw that can be screw-coupled to the female screw of the nut 42 is formed. At each end of the connecting member 41, a mounting hole 41a through which the bolt 43 can be inserted is formed. ing.

  Here, the nut 42 is formed in a parallelogram having a lateral dimension substantially corresponding to the opening width of the guide groove 3a and a vertical dimension substantially corresponding to the width of the guide groove 3a when viewed from above. Further, a stepped portion having an interval corresponding to the opening width of the guide groove 3 a is formed on the upper surface of the nut 42. As a result, the bolt 43 is screwed to the nut 42, and the nut 42 is inserted into the guide groove 3 a through the opening and moved to an arbitrary position along the longitudinal direction. The top of the diagonal line is in contact with the inner surface of the guide groove 3a to prevent rotation, and the aforementioned stepped portion is set to face the opening of the guide groove 3a in parallel. That is, the bolt 43 is inserted into the mounting hole 41a of the connecting member 41, the nut 42 is screwed to the bolt 43, and the nut 42 is inserted into the guide frame 3a of the connecting frame 3 along the opening, By moving the bolt 43 to an arbitrary position and rotating the bolt 43 in the fastening direction, the rotation can be prevented and the screw 42 can be coupled to the nut 42 at a position where the bolt 43 is prevented from coming out of the guide groove 3a. Can be fixed. At this time, the stepped portion of the nut 42 is fitted into the opening of the guide groove 3a, and the rotation is reliably prevented and positioning is performed.

  As will be described later, a plate-like connecting member 44 (see FIG. 7) is also prepared as the connecting member. In the pair of connecting frames 3 and 3 arranged on the same vertical plane, one connecting member is provided. The other connecting frame 3 can be disposed at a set angle with respect to the connecting frame 3 and fixed using the connecting member 4 including the connecting member 44, the bolt 43, and the nut 42.

  Next, the case where the solar pergola 1A which is the outdoor structure 1 is assembled using these solar cell modules 2, the connection frame 3, and the connection member 4 is demonstrated.

  First, the connecting frame 3 is cut to a length substantially corresponding to the inner surface spacing of the opposing second frame members 24, 24 of the solar cell module 2 to prepare one supporting frame 11, and the connecting frame 3 is set. Two struts 12 are prepared by cutting into lengths. Further, a bolt 43 is inserted into the attachment hole 41 a of the connecting member 41, and a nut 42 is screwed to the bolt 43. Further, a bolt 43 is inserted into a mounting hole formed in the sub-bottom wall 231 of the frame member 23 of the solar cell module 2, and a nut 42 is screwed to the bolt 43.

  Next, the support frame 11 is disposed along the sub-bottom wall 231 of one of the first frame members 23 in the solar cell module 2, and after inserting the nut 42 into the guide groove 3a, the bolt 43 is screwed, The support frame 11 is fixed to the first frame member 23 of the solar cell module 2 via the nut 42.

  Thereafter, at each end in the longitudinal direction of the support frame 11, the upper end of the support column 12 is abutted against the lower surface of the support frame 11, the connecting member 41 is applied to the intersecting portion thereof, and the nut 42 is inserted into the guide grooves 3 a and 3 a. After inserting through the opening, the bolt 43 is screwed. Thereby, the support frame 11 and the support | pillar 12 can be fixed via the connection material 41, the volt | bolt 43, and the nut 42. FIG. That is, the support frame 11 and the support column 12 can be fixed to each other through the connecting member 4 in an orthogonal state.

  When the solar pergola 1A is assembled in this way, it can be constructed by inserting the lower end portion of the support column 12 into the foundation block K embedded in advance in the installation location and injecting concrete to solidify it.

  The solar pergola 1A, which is an outdoor structure 1 constructed in this manner, consumes the generated electricity on the spot or stores it in a battery (not shown) because the solar cell module 2 performs solar power generation in the daytime. It can be used as an emergency power source, or it can be used for night lighting with a separate lighting facility. That is, it is possible to use electricity generated without requiring a contract with an electric power company and without performing overhead work, thereby reducing costs.

  Specifically, it can be installed in customer-acquired facilities such as gardens, parks, campsites, open cafes, event venues, road stations, and amusement parks at homes, so that electronic devices such as smartphones, electric bicycles, and wheelchairs can be used. It can be used as a battery charging station, or can be used as a security light or a garden light with a lighting facility. Moreover, as will be described later, by arranging a plurality of solar cell modules, a larger light receiving area can be secured and used for a carport, a bus stop, or the like.

  Moreover, since the solar pergola 1A which is the outdoor structure 1 can be formed from the solar cell module 2, the connection frame 3, and the connection member 4, it is possible to reduce the number of parts by making the components common, and a special technique is required. Anyone can assemble it easily and in a short time, and the cost of the structure itself can be reduced.

  In the above-described embodiment, the support column 11 is erected at each end in the longitudinal direction of the support frame 11. However, one support column is erected at a substantially middle portion of the support frame 11 in the longitudinal direction. In addition to supporting the frame member 22 of the solar cell module 2, the support frame 11 is rectangularly framed, and pillars 12 are erected at the four corners, or a pair of opposed support frames 11 are opposed to each other. The support columns 12 can also be provided upright at substantially the middle portion of the support frame.

  4 to 6 show modified examples of the solar pergola 1A.

  This solar pergola 1A is obtained by cutting the connection frame 3 in correspondence with a solar cell module group in which a plurality of solar cell modules 2 are arranged in the horizontal direction (three in the embodiment) in the longitudinal direction. The support frame 10 is formed by fixing the support frames of the two to each other via the connecting member 4, and the pillars 12 are respectively provided upright at the four corners of the support frame 10 via the connecting member 4.

  Here, the connecting member 4 including the solar cell module 2, the connecting frame 3, the connecting member 41, the nut 42, and the bolt 43 is the same as that used in the above-described embodiment, and the same members have the same reference numerals. The detailed description is omitted.

  The support frame 10 has a long side length of the solar cell module group so that the opposing second frame member 24 (sub-bottom wall 241) which is the front side and the rear side of the solar cell module 2 facing vertically long can be respectively fixed. The connection frame 3 is cut to a length substantially equivalent to the length to prepare two long-side support frames 13 and substantially equivalent to the distance between the pair of second frame members 24, 24 facing the solar cell module 2. The connecting frame 3 is cut to a length to prepare two short-side support frames 14, and the short-side support frames 14, 14 are respectively arranged at the left and right ends of the long-side support frames 13, 13. These intersections are formed by fixing each other through the connecting member 4. And the support | pillar 12 is mutually fixed to the left-right each edge part of each long side support frame 13 used as the four corners of the support frame 10 via the connection member 4, respectively, and the support | pillar 12 is fixed to the foundation block K, respectively. Has been.

  The left and right struts 12 are formed in a gate shape by connecting a connection frame 15 prepared by cutting the connection frame 3 to a set length across the upper end portions thereof via the connection member 4.

  Also in this embodiment, the support column 12 may be erected only at the left and right ends of one long side support frame 13 of the support frame 10, and at the middle part of the front and rear long side support frames 13, respectively. You may stand upright. In addition, the support column 12 is provided with front and rear end portions of the left and right short side support frames 14 of the support frame 10, front and rear end portions of one short side support frame 14, or an intermediate portion of the left and right short side support frames 14. Can also be set up in Also in this case, it is preferable to form the connection frame 15 between the corresponding support columns 12 and 12 so as to form a gate shape.

  In addition, in embodiment mentioned above, although the case where the solar cell module 2 was arrange | positioned horizontally was illustrated, in order to increase received light energy, it is preferable to arrange | position the solar cell module 2 in an inclined state. Specifically, as shown in FIG. 7, the support frame 10 that fixes the solar cell module 2 or the solar cell module group is disposed in an inclined state with respect to the support column 12, and the support frame 14 ( 13) A plate-like connecting member 44 may be disposed, and the support column 12 and the support frame 14 (13) may be fixed to each other via the bolt 43 and the nut 42.

  FIG. 8 shows another modification of the solar pergola 1A.

  This solar pergola is obtained by cutting the connection frame 3 in correspondence with a solar cell module group in which a plurality of solar cell modules 2 are arranged vertically (two in the embodiment) in a vertically long manner. The support frames 10 are fixed to each other via the connecting member 4 to form the support frame 10, and the pillars 12 are erected on the four corners of the support frame 10 via the connecting member 4.

  The support frame 10 has a length substantially corresponding to the length of the long side of the solar cell module group so that the first frame member 23 facing the left side and the right side of the solar cell module 2 facing vertically long can be respectively fixed. The connection frame 3 is cut to prepare two long side support frames 13 and the connection frame 3 has a length substantially corresponding to the interval between the pair of first frame members 23, 23 facing the solar cell module 2. To prepare two short-side support frames 14, arrange the short-side support frames 14 and 14 between the front and rear ends of the long-side support frames 13 and 13, respectively, and connect the intersections thereof It is formed by fixing each other via the member 4. And the support | pillar 12 is mutually fixed to the front-and-back each end part of each long side support frame 13 used as the four corners of the support frame 10 via the connection member 4, respectively, and the support | pillar 12 is fixed to the foundation block K, respectively. Has been.

  The left and right struts 12 are formed in a gate shape by connecting a connection frame 15 prepared by cutting the connection frame 3 to a set length across the upper end portions thereof via the connection member 4.

  Also in this embodiment, the support column 12 may be erected only at the front and rear ends of one long side support frame 13 of the support frame 10, and at the middle part of the left and right long side support frames 13, respectively. You may stand upright. Further, the support column 12 has left and right end portions of the short side support frame 14 before and after the support frame 10, left and right end portions of one short side support frame 14, or an intermediate portion of the front and rear short side support frames 14. Can also be set up in Also in this case, it is preferable to form the connection frame 15 between the corresponding support columns 12 and 12 so as to form a gate shape.

  Although not shown in detail, the support frame formed corresponding to the solar cell module group in which a plurality of solar cell modules 2 are arranged in the vertical direction facing horizontally long is the same as the support frame 10 in FIG. 4 described above. The support frame 10 may be rotated 90 degrees and the long side support frame 13 may be installed in the vertical direction.

  Further, the support frame formed corresponding to the solar cell module group in which a plurality of solar cell modules 2 are arranged horizontally in the horizontal direction is the same as the support frame 10 of FIG. Is rotated 90 degrees, and the long side support frame 13 may be installed in the lateral direction.

  FIG. 9 shows another modification of the solar pergola 1A.

  In this solar pergola 1A, a plurality of solar cell modules 2 are arranged in the vertical direction and the horizontal direction in the vertical direction (in the embodiment, two in the vertical direction and three in the horizontal direction), and are arranged in the vertical direction. Corresponding to a plurality of rows of solar cell module groups, a support frame obtained by cutting the connection frame 3 is formed through the connection member 4 to form the support frame 10, and the support columns 10 are respectively connected to the four corners of the support frame 10. 4 is arranged upright.

  Specifically, the length substantially corresponds to the length of the long side of each row of solar cell modules so that the opposing first frame members 23 that are the left side and the right side of each solar cell module 2 can be fixed. A plurality of pairs of long side support frames 13 are prepared by cutting the connection frame 3, and a distance between the pair of first left and right first frame members 23, 23 in the plurality of rows of solar cell modules. The connecting frame 3 is cut to a length substantially corresponding to 2 to prepare two short side support frames 14. Next, the six long side support frames 13 are arranged in the vertical direction corresponding to the left and right first frame members 23 of the solar cell module group in each row, and the front and rear sides of the long side support frames 13 are arranged. The short-side support frames 14 and 14 are respectively arranged at the respective end portions, and the crossing portions thereof are fixed to each other via the connecting member 4, whereby a plurality of vertically oriented solar cell modules 2 are vertically arranged. The support frame 10 corresponding to the arrayed solar cell module groups in a plurality of rows is formed. And the support | pillar 12 is mutually fixed to the right-and-left each edge part of each short side support frame 14 used as the four corners of the support frame 10 via the connection member 4, respectively, and the support | pillar 12 is fixed to the foundation block K, respectively. Has been.

  The left and right struts 12 are formed in a gate shape by connecting a connection frame 15 prepared by cutting the connection frame 3 to a set length across the upper end portions thereof via the connection member 4.

  Also in this embodiment, the support pillars 12 may be erected only at the left and right ends of one short side support frame 14 of the support frame 10, respectively, and at the intermediate portions of the front and rear short side support frames 14, respectively. You may stand upright. Further, the support column 12 is provided with front and rear end portions of the outermost long side support frame 13 of the support frame 10, front and rear end portions of one outermost short side support frame 14, or outermost left and right short sides. It can also stand upright in the middle part of the side support frame 14. Also in this case, it is preferable to form the connection frame 15 between the corresponding support columns 12 and 12 so as to form a gate shape.

  Although not shown in detail, a plurality of solar cell modules 2 are arranged in the vertical direction and the horizontal direction in the horizontal direction, and a connection frame corresponding to a plurality of rows of solar cell module groups arranged in the horizontal direction. It is possible to form a solar pergola by forming the support frame 10 through the connecting member 4 from the support frame obtained by cutting 3, and standing upright at the four corners of the support frame 10 through the connecting member 4. Needless to say.

  Moreover, in embodiment mentioned above, tape-shaped LED (LED tape (not shown)) can be arrange | positioned in the guide groove 3a of the support frames 11,13,14, the support | pillar 12, and the connection frame 15 as lighting equipment. Can be used for night lighting.

  Furthermore, the installation plate can be fixed to the lower end of the support column 12 and fixed to the foundation with an anchor bolt.

  FIG. 10 shows another embodiment of the outdoor structure 1 of the present invention.

  This outdoor structure 1 is a solar box 1B, and includes a plurality of solar cell modules 2, a plurality of connection frames 3, and a connection member 4 that connects the connection frames 3 and 3.

  The solar box 1B of this embodiment has the same main part as the solar pergola 1A shown in FIGS.

  In this solar box 1B, a plurality of solar cell modules 2 are arranged in the horizontal direction (three in the embodiment) in the longitudinal direction, and a connection frame corresponding to the plurality of solar cell modules arranged in the horizontal direction. The four support frames obtained by cutting 3 are fixed to each other via the connecting member 4 to form the support frame 10, while the pillars 12 are raised at the four corners of the support frame 10 via the connecting member 4. In addition, the connection frame 16 is fixed between the lower ends of the pair of adjacent columns 12 and 12 via the connecting member 4, and the support frame 10, the pair of adjacent columns 12 and 12, and the connection frame 16 The door 17 is provided so as to be opened and closed using a hinge provided on the support column 12 on one of the four surrounding surfaces, and the wall panel 18 is provided on the remaining three surfaces.

  Such a solar box 1B can be used as a storeroom. In addition to storing food and drinking water in case of an emergency, the solar box 1B is usually used as an emergency power source by generating electricity with a solar cell module and storing it in a battery. It can be used for warehouses. In addition, it can be used as a hydroponic farm and vegetable factory in restaurants, cafes, supermarkets, and even outdoors where there is no power source, and can be used as a power source for lighting, water circulation pumps, and the like.

  Although not shown in detail, it is possible to construct a solar box 1B having various light receiving areas by arranging an appropriate number of solar cell modules 2 in the vertical and horizontal directions, similar to the solar pergola 1A.

DESCRIPTION OF SYMBOLS 1 Outdoor structure 1A Solar pergola 1B Solar box 2 Solar cell module 21 Solar cell panel 22 Frame material 23 1st frame material 24 2nd frame material 3 Connection frame 3a Guide groove 4 Connection member 41,44 Connection material 42 Nut 43 Bolt 10 Support Frame 11, 13, 14 Support frame 12 Support column 15, 16 Connection frame 17 Door 18 Wall panel

Claims (7)

One solar cell module composed of a rectangular solar cell panel and a frame member disposed around the solar cell panel, and a plurality of connecting frames having a square cross section in which substantially common guide grooves are formed in the longitudinal direction on each side. A plurality of connecting members that can be disposed at the intersections of the connecting frames that intersect, a plurality of nuts that are movably inserted along the guide grooves of the connecting frames, and a plurality of screws that can be screwed to the nuts A connecting member made of a bolt,
The connection frame is fixed to at least one side of the frame member of the solar cell module via a bolt and nut, and one or more connection frames extending in the vertical direction are vertically provided on the connection frame via the connection member. Features outdoor structures. A cross section in which a plurality of solar cell modules arranged in a lateral direction and a substantially groove-shaped guide groove are formed in a longitudinal direction, each of which is composed of a rectangular solar cell panel and a frame member disposed around the solar cell panel. A plurality of rectangular connecting frames, a plurality of connecting members that can be disposed at the intersections of the connecting frames that intersect, a plurality of nuts that are movably fitted along the guide grooves of the connecting frames, and the nuts A connecting member comprising a plurality of bolts that can be screwed together,
The front and rear connection frames extending in the horizontal direction across the front and rear sides of the frame member in the plurality of solar cell modules arranged in the horizontal direction are fixed via bolts and nuts, and one of the front and rear connection frames, or the front and rear One or more connecting frames extending in the vertical direction on the connecting frame are erected via a connecting member. A cross section in which a plurality of solar cell modules arranged in a vertical direction and a substantially groove-shaped guide groove are formed in a longitudinal direction, each of which is composed of a rectangular solar cell panel and a frame member disposed around the solar cell panel. A plurality of rectangular connecting frames, a plurality of connecting members that can be disposed at the intersections of the connecting frames that intersect, a plurality of nuts that are movably fitted along the guide grooves of the connecting frames, and the nuts A connecting member comprising a plurality of bolts that can be screwed together,
The left and right connection frames extending in the vertical direction across the left and right sides of the frame member in the plurality of solar cell modules arranged in the vertical direction are fixed via bolts and nuts, and one of the left and right connection frames or the left and right connection frames An outdoor structure characterized in that one or a plurality of connecting frames extending vertically in a frame are erected through a connecting member. A solar cell module comprising a rectangular solar cell panel and a frame member disposed around the solar cell panel, and a plurality of solar cell modules arranged in the vertical direction and the horizontal direction, respectively, and a substantially groove-shaped guide groove on each side in the longitudinal direction A plurality of connecting frames having a square cross section formed, a plurality of connecting members that can be disposed at intersections of the connecting frames that intersect, a plurality of nuts that are movable along the guide grooves of the connecting frames, and the nuts; A connecting member comprising a plurality of bolts that can be screwed, and
The front and rear connection frames extending in the horizontal direction across the front and rear sides of the frame member in the plurality of solar cell modules in each row arranged in the horizontal direction are fixed through bolts and nuts, and a plurality of pairs of front and rear connections The left and right connecting frames extending in the vertical direction are fixed to the left and right ends of the frame via connecting members, and the foremost connecting frame, the rearmost connecting frame, or the frontmost connecting frame and the rearmost An outdoor structure characterized in that one or a plurality of connecting frames extending in the vertical direction are vertically provided on the connecting frame of the left or right, or one of the left and right connecting frames or the left and right connecting frames. A solar cell module comprising a rectangular solar cell panel and a frame member disposed around the solar cell panel, and a plurality of solar cell modules arranged in the vertical direction and the horizontal direction, respectively, and a substantially groove-shaped guide groove on each side in the longitudinal direction A plurality of connecting frames having a square cross section formed, a plurality of connecting members that can be disposed at intersections of the connecting frames that intersect, a plurality of nuts that are movable along the guide grooves of the connecting frames, and the nuts; A connecting member comprising a plurality of bolts that can be screwed, and
The left and right connecting frames extending in the vertical direction across the left and right sides of the frame members in the plurality of solar cell modules in each row arranged in the vertical direction are fixed via bolts and nuts, and a plurality of pairs of left and right connecting frames The front and rear connection frames extending in the lateral direction are fixed to the respective front and rear end portions of the front and rear ends of the front and rear ends of the front and rear ends, and the leftmost connection frame, the rightmost connection frame, or the leftmost connection frame and The rightmost connection frame, or one of the front and rear connection frames, or one or a plurality of connection frames extending in the vertical direction on the front and rear connection frames, are erected through a connection member. Constructs. A cross section in which a plurality of solar cell modules arranged in a lateral direction and a substantially groove-shaped guide groove are formed in a longitudinal direction, each of which is composed of a rectangular solar cell panel and a frame member disposed around the solar cell panel. A plurality of rectangular connecting frames, a plurality of connecting members that can be disposed at the intersections of the connecting frames that intersect, a plurality of nuts that are movably fitted along the guide grooves of the connecting frames, and the nuts A connecting member comprising a plurality of bolts that can be screwed together,
The front and rear connection frames extending in the horizontal direction across the front and rear sides of the frame member in the plurality of solar cell modules arranged in the horizontal direction are fixed via bolts and nuts, and the left and right ends of the front and rear connection frames A connecting frame extending in the vertical direction is fixed through a connecting member, and a connecting frame extending in the vertical direction is provided on each of the left and right ends of the front and rear connecting frames via the connecting member, and a pair of adjacent frames. The connecting frame is fixed to the lower end of each support post via a connecting member, the door is provided to be openable and closable between at least a pair of adjacent support posts, and a wall panel is provided between the remaining adjacent support posts. And outdoor structures. A cross section in which a plurality of solar cell modules arranged in a vertical direction and a substantially groove-shaped guide groove are formed in a longitudinal direction, each of which is composed of a rectangular solar cell panel and a frame member disposed around the solar cell panel. A plurality of rectangular connecting frames, a plurality of connecting members that can be disposed at the intersections of the connecting frames that intersect, a plurality of nuts that are movably fitted along the guide grooves of the connecting frames, and the nuts A connecting member comprising a plurality of bolts that can be screwed together,
The left and right connecting frames extending in the vertical direction across the left and right sides of the frame member in the plurality of solar cell modules arranged in the vertical direction are fixed via bolts and nuts and are horizontally attached to the front and rear ends of the left and right connecting frames. A connecting frame extending in the direction is fixed via a connecting member, and a connecting frame extending in the vertical direction is provided on each of the front and rear ends of the left and right connecting frames via the connecting member, and a pair of adjacent columns The connecting frame is fixed to the lower end of each of the two through a connecting member, the door is provided so as to be openable and closable between at least a pair of adjacent columns, and a wall panel is provided between the remaining adjacent columns. Outdoor structures.

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