JP2017112665A - Frame of solar cell panel - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a frame of a solar cell panel, in which a storage, conveyance to a construction site, and a treatment can be easily performed, which can be efficiently assembled in a site precisely and firmly.SOLUTION: A frame of a solar cell panel, comprises: a plurality of solar cell panel attachment lateral materials 1 that are arranged in parallel at a predetermined interval in a longitudinal direction; a plurality of longitudinal materials 2 that are arranged in parallel at an appropriate interval in a lateral direction, and support the lateral materials 1 from below; front and rear connection members which are slidably/fixedly mounted to front and rear part lower surfaces of respective longitudinal members 2; front and rear leg pole members 5 and 6 that pivot upper end parts to the front and rear connection members; and diagonal girder materials 11 coupling between the front and rear leg pole members 5 and 6. By sliding the front and rear leg pole members toward end parts of the longitudinal members 2, the front and rear leg pole members 5 and 6 and the diagonal girder material 11 are constructed so as to be folded to bottom surfaces of the longitudinal members 2.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a solar cell panel mount for mounting a plurality of solar cell panels in a state where they are laid out vertically and horizontally.

  Conventionally, as a pedestal for this type of solar cell panel, for example, as described in Patent Document 1, a plurality of vertical members for mounting solar cell panels arranged in parallel to each other at regular intervals in the left-right direction A plurality of cross members arranged in parallel to each other at regular intervals in the front-rear direction and supporting the vertical member from the lower side, a connecting bracket for integrally connecting the vertical member and the cross member, 2. Description of the Related Art A gantry including a leg portion provided with a joint portion for supporting a material at a tip is known.

  Patent Document 2 discloses a plurality of solar panel mounting vertical members (panel support members) arranged in parallel in the left-right direction at regular intervals, and arranged in parallel in the front-rear direction at regular intervals. A plurality of cross members (foundation members) that support the vertical members from below, bolts that connect and fix the crossing portions of the vertical members and the cross members, struts that support the cross members, and cross members And a connecting member for attaching the support column, and the connecting member includes a planar rectangular upper surface plate and both side surface plates that hang downward in parallel from both side edges of the upper surface plate. The top plate is joined to the bottom surface of the cross member in a direction orthogonal to the length direction of the cross member, and this connecting member is fixed to the bottom surface of the cross member by a mounting member such as a bolt, and both side plates Insert the upper end of the column between them and use bolts to align the column in the length direction of the cross member Solar panel of the stand formed by pivotally rotatably in a direction perpendicular Te is described.

JP 2013-185393 A JP 2014-34830 A

  According to the solar cell panel mount described in Patent Literature 1, the cross member and the vertical member are firmly connected to each other by the connecting bracket, and the joint portion is provided on the leg portion supporting the cross member. Since the legs are attached to the lower surface of the cross member by tightening it to the outer peripheral surface of the cross member with the cross member inserted in the part, the entire base becomes strong and the solar cell panel is stable over a long period of time. Although it has the advantage that it can be supported in a state, when assembling this mount on the ground surface such as the ground, it is necessary to attach a cross member on the legs via the Jonito part at the installation site However, the work is cumbersome and time-consuming, and there is a problem that efficient construction cannot be expected.

  Similarly, also in the solar cell panel mount described in Patent Document 2, it is necessary to attach a column to a cross member via a connecting member at the installation site. In this case, the column can be folded and fixed by a bolt with respect to the connecting member fixed to the lower surface of the cross member so that the column can be folded, but the folding direction is orthogonal to the cross member. This column cannot be bundled together with vertical and horizontal members, and the work efficiency is reduced due to difficulties in handling during transportation and construction. There is a risk of injury to workers due to the projecting struts, and when the struts collide with the foundation surface or other objects, there is a risk of damage due to large bending stress acting on the bolts that the struts are attached to. was there.

  In addition, when the vertical member that supports the solar cell panel is tilted with respect to the foundation surface using long and short columns, and the frame is installed on the foundation surface so that the solar cell panel faces the sun, A problem that the cross member supporting the lower surface is inclined with respect to the upper end of the column and the load of the solar cell panel or the like acts in a direction intersecting the axis of the column, and stable support cannot be obtained. A point is created.

  The present invention has been made in view of such problems, and the purpose of the present invention is to facilitate and safely transport and handle to the construction site, and to perform efficient and robust assembly at the site. It is in providing the stand of the solar cell panel which can support a solar cell panel in the stable state.

  In order to achieve the above object, a solar cell panel mount according to the present invention includes a plurality of solar cell panel mounting cross members arranged in parallel in the front-rear direction, and the left-right direction. Are arranged in parallel with each other, and a plurality of vertical members supporting the solar cell panel mounting cross member from the lower surface side, and sliding in the longitudinal direction of the vertical member on the lower surface of the front and rear portions of each vertical member, A connecting member that is fixedly mounted, and a front and rear pedestal whose upper ends are pivotally attached to the front and rear connecting members so as to be rotatable in the longitudinal direction of the longitudinal member and to be overlapped with the lower surface of the longitudinal member. And a base attached to the lower ends of these front and rear leg columns.

  In the solar cell panel mount thus configured, in the invention according to claim 2, the horizontal member for mounting the solar cell panel and the vertical member supporting the horizontal member are formed of square pipes, A concave groove is provided over the entire length of the vertical member at the center of the upper surface of the vertical member, and a locking protrusion having a constant width is provided at the lower end of both side surfaces. The groove is fitted with a clamp having a pressing piece for sandwiching the end of the solar cell panel together with the upper surface of the end of the cross member, and the concave groove provided in the vertical member projects to the lower ends of both side surfaces of the cross member. A clamp having a locking piece for fixing the cross member to the vertical member by being locked to the locking protrusion piece provided is mounted.

  According to a third aspect of the present invention, the clamp having a pressing piece for sandwiching the end portion of the solar cell panel has a bolt insertion hole penetrating in the vertical direction in the pressing piece, and a head in the bolt insertion hole. Is inserted into the upper surface of the presser piece, and a nut body disposed in the concave groove of the solar panel mounting cross member is screwed to the lower portion of the bolt. A locking projection for locking to the lower surface of the protruding piece protruding from the upper end opening of the groove is provided on both side surfaces of the groove.

  Similarly, the clamp having the locking piece for fixing the cross member to the vertical member is provided with a bolt insertion hole penetrating in the vertical direction in the locking piece and the bolt as described in claim 4. A bolt whose head is crimped to the upper surface of the locking piece is inserted into the insertion hole, and a nut body disposed in a concave groove provided in the vertical member is screwed to the lower portion of the bolt. Further, a locking projection for locking to the lower surface of the projecting piece projecting from the upper end opening of the concave groove is provided on both side surfaces of the nut body.

  As described in claim 5, the nut body described in claim 3 and claim 4 is formed so that it can be inserted and disposed in the groove from the upper end opening of the groove. The locking protrusions provided on both side surfaces of the body are composed of a locking protrusion having a short protrusion length and a locking protrusion having a long protrusion length, and the inner wall surface of the groove for locking the long locking protrusion is formed at the upper end of the groove. It is characterized in that it is formed on an inclined wall surface that is inclined outward from the base end of one projecting piece projecting at the opening.

  In the invention according to claim 6, the connecting member is provided so as to protrude from a rectangular horizontal plate portion in which the center portion of the upper surface is slidably overlapped with the lower surface of the vertical member, and both sides of the upper surface of the horizontal plate portion, The clamp piece part which locked the front-end | tip part to the latching protrusion which is protrudingly provided in the lower end of both sides of a vertical member, and this clamp piece part is pressed down, and the front-end | tip part is made into the said engagement protrusion. A fixing bolt that fixes the connecting member to the lower surface of the vertical member by crimping, and a leg that hangs downward from both sides of the lower surface of the horizontal plate portion and inserts the upper end portion of the leg pillar material between the opposing inner surfaces It is characterized by comprising a column member mounting piece and a support hole which is provided in the leg column member mounting piece and which is inserted and supported at both ends of a bolt pivotally attached to the upper end portion of the leg column member.

  Further, in the invention according to claim 7, the lower end portion is pivotally attached to the base of either the front or rear leg column member between the front and rear leg column members, and the upper end portion is the upper end of the other leg column member. A slanting girder material that is pivotally attached to this leg column material mounting piece by bolts is inserted between the leg column material mounting pieces of the connecting member attached to the connecting member. It is configured to be foldable so as to overlap with the lower surface of the vertical member together with the pillar material.

  On the other hand, in the invention according to claim 8, an intermediate connection member is mounted on the lower surface of the intermediate portion in the longitudinal direction of the longitudinal member between the front and rear leg column members, and between the connection member and the base of the leg column member. The lower end is pivotally attached to the base of the pedestal member, and the upper end is interposed between the pedestal attachment pieces of the intermediate connecting member and is pivotally attached to the attachment piece by bolts. The diagonal girder material is arranged, and the diagonal girder material is configured to be foldable so as to overlap with the lower surface of the vertical member together with the leg column material.

  In the invention according to claim 9, the base protrudes upward on both sides of the rectangular horizontal substrate and the upper surface of the horizontal substrate, and the lower end portion of the pillar material is inserted between the opposing surfaces. It consists of a vertical plate on both sides and a vertical hole provided in the vertical plate on both sides, and both ends of bolts pivotally attached to the lower end of the pillar material are inserted through these vertical holes, The bolts are fastened and fixed to the vertical plate portions on both sides by nuts screwed to the bolts.

  According to the first aspect of the present invention, the connecting member can be slid and fixed in the longitudinal direction of the longitudinal member on the lower surface of the front and rear portions of the plurality of longitudinal members that support the horizontal member for mounting the solar cell panel from the lower surface side. It is attached and pivotally attached to this connecting member so that the upper end of the columnar member can be pivoted in the longitudinal direction of the vertical member and can be folded so as to overlap the lower surface of the vertical member. When storing and transporting before construction, without removing the front and rear pedestal column members pivotally attached to the upper and lower pivots of the connecting members attached to the front and rear parts of each vertical member, If the front and rear pedestal members are folded in the longitudinal direction from the upper end pivot part, these pedestal members can be easily stacked in the longitudinal direction along the lower surface of the longitudinal members. The vertical members with the pillars folded together with the multiple transverse members can be compactly focused. In, storage and transportation, handling safely and easily.

  Furthermore, at the construction site, the front and rear pedestal members are erected downward from each vertical member, and the base attached to the lower end of the pedestal member is fixed to the foundation surface such as the ground. An assembly structure supporting vertical members can be easily formed, and the vertical members are juxtaposed in the left-right direction at predetermined intervals, and solar cell panels are formed on these vertical members so as to be orthogonal to the vertical members. By mounting the mounting cross members in the front-rear direction at predetermined intervals, the solar cell panel can be efficiently assembled. In addition, the connecting member that connects the pedestal material to the longitudinal member is slidable and fixed in the longitudinal direction of the longitudinal member, so the standing position of the front and rear pedestal material with respect to the foundation surface is set to the desired position can do.

  In addition, in the assembled state, the length of the rear pillar material is longer than the front pillar material, and the solar cell panel support surface is inclined downward from the rear end side toward the front end side. Even when assembled, the load from the side of the large number of solar cell panels arranged on the cross member can be applied in the axial direction of the front and rear leg column members, and it is made stronger and stable by the front and rear columns. Support is possible, and a platform for a solar cell panel with excellent durability can be provided.

  According to a second aspect of the present invention, the cross member and the vertical member are formed of square pipes, and a concave groove is provided over the entire length at the center of the upper surface, and a constant width is provided at the lower ends of both side surfaces. Stop projections are projected, and in the concave grooves provided in the vertical members, the horizontal members are fixed to the vertical members by engaging the locking protrusions protruding from the lower ends of both side surfaces of the horizontal members. Since the clamp having the locking piece for mounting is mounted, the cross member can be firmly and accurately attached to the vertical member at the desired interval by the clamp, and the concave groove provided in the cross member is also provided. Is attached with a clamp having a pressing piece for sandwiching the end of the solar cell panel together with the upper surface of the end of the cross member, so that the solar cell disposed between the front and rear adjacent cross members The front and rear ends of the panel can be easily and firmly fixed by this clamp.

  According to the invention of claim 3, the clamp having the pressing piece for sandwiching the end portion of the solar cell panel is provided with a bolt insertion hole penetrating in the vertical direction in the pressing piece and this bolt insertion. Bolts whose heads are crimped to the upper surface of the pressing pieces are inserted into the holes, and nuts disposed in the concave grooves of the solar cell panel mounting transverse members are screwed into the lower portions of the bolts. Since the locking projections that lock the bottom surface of the protruding piece projecting from the upper end opening of the groove are provided on both side surfaces of the nut body, the inside of the groove provided in the cross member By moving the nut body arranged in the groove along the concave groove, the clamp can be easily positioned at the solar panel fixing position and the bolt can be screwed to fix the end of the solar panel. Can be done efficiently.

  Similarly, according to the invention of claim 4, the clamp having the locking piece for fixing the cross member to the vertical member is provided with a bolt insertion hole penetrating in the vertical direction in the locking piece. A bolt whose head is crimped to the upper surface of the locking piece is inserted into the bolt insertion hole, and a nut body disposed in a concave groove provided in the vertical member is screwed into the lower portion of the bolt. In addition, since the locking projections to be locked to the lower surface of the projecting piece projecting from the upper end opening of the concave groove are provided on both side surfaces of the nut body, the vertical members arranged in parallel in the left-right direction After arranging the cross members so as to be orthogonal to each other, if the nut body arranged in the concave groove provided in the vertical member is moved toward the front and rear surfaces of the cross member along this concave groove, the clamp will be The cross member can be easily positioned at the cross member fixing position, and the cross member is firmly fixed on the vertical member by screwing the bolt at that position. One can be easily fixed.

  Furthermore, according to the invention which concerns on Claim 5, the nut body screwed together by the lower part of the volt | bolt which is one part of the said clamp is the upper end opening part of the said ditch | groove provided in the upper surface of a vertical material, or the upper surface of a horizontal material The locking projections provided on both side surfaces of the nut body are composed of a locking projection having a short protruding length and a long locking projection. Since the inner wall surface of the groove that locks the locking protrusion is formed on an inclined wall surface that is inclined outward from the base end of one projecting piece projecting from the upper end opening of the groove. When a clamp is installed in a groove in a vertical or horizontal member, the nut body of this clamp is inserted into the groove from the opening end side that opens at the longitudinal end of the vertical or horizontal member. Without opening, the upper end opening of the groove that opens upward on the upper surface of the vertical member and the upper surface of the cross member Insert it can be from any portion of the length direction of the longitudinal member or cross member can be attached to clamp easily.

  At this time, the nut body is recessed while the locking protrusion is inclined obliquely toward the tip from the locking protrusion side protruding from one side of the both sides of the nut body. The inner wall of the concave groove facing the locking projection is an inclined wall surface that is inclined outward from the upper end opening. Therefore, if the nut body is inserted into the groove and then returned so that the nut body is in a horizontal state, the locking protrusion having a long projecting length is inwardly facing the upper end opening of the groove. The other locking projection having a short projecting length is slidably contacted with the inclined wall surface of the concave groove that is inclined in the direction toward the lower end of the other protruding piece projecting from the upper end opening of the concave groove. The long and short locking protrusions can be easily and accurately locked to both protrusions. Rukoto can, fixing work of the crosspiece can be performed efficiently and accurately with respect to the fixed work and stringer of the solar cell panel onto crosspieces by the clamp.

  According to the invention which concerns on Claim 6, the upper end part of a leg pillar material is provided in the lower surface both sides of the horizontal board part which slidably follows the lower surface of a longitudinal member in the said connection member of a vertical member and a leg pillar material. Since there are mounting pieces for pivotal mounting, the upper end of the columnar material is inserted between these mounting pieces, and the columnar column can be rotated in the longitudinal direction of the vertical member by bolts. The connecting bracket can be pivotally attached, and both clamp pieces projecting from the upper surface of both sides of the horizontal plate portion are engaged with engaging projections projecting from the lower ends of both side surfaces of the vertical member. It can be slidably arranged in the lengthwise direction of the vertical member along the locking protrusion, and the columnar member can be made to be a desired vertical member by fixing the clamp piece to the locking protrusion with a fixing bolt. It can be arranged in the part.

  According to the invention which concerns on Claim 7, between the said front-and-back leg column materials, a lower end part is pivotally attached to the base of either one of the front-and-rear leg column materials, and an upper end part is the upper end of the other leg column material. Since the diagonal girder material is pivotally attached to this mounting piece with bolts by interposing between the leg column mounting pieces of the connecting member attached to the front and rear legs. The pillar material can be installed in a solid and stable standing state on the ground surface such as the ground, and when storing or transporting before installation etc., by moving the connecting member to the end side of the vertical material The oblique girder material can be easily folded so as to overlap the lower surface of the vertical member together with the pillar material.

  Similarly, according to the invention according to claim 8, an intermediate connection member is mounted on the lower surface of the intermediate portion in the longitudinal direction of the longitudinal member between the front and rear leg column members, and the connection member and the base of the leg column member In between, the lower end is pivotally attached to the base of the pedestal material, and the upper end is interposed between the pedestal material attachment pieces of the intermediate connecting member and can be turned to the attachment pieces by bolts. Because it is pivotally attached, it is possible to install the pedestal material on the foundation surface such as the ground in a stable and stable standing state with this diagonal girder, and it is also connected during storage and transportation before installation etc. By moving the member to the end portion side of the vertical member, the oblique girder member can be easily folded together with the pillar member so as to overlap the lower surface of the vertical member.

  According to the ninth aspect of the present invention, the base mounted on the lower end of the pedestal member protrudes upward on both sides of the rectangular horizontal substrate and the upper surface of the horizontal substrate, and the leg is between the opposing surfaces. The both ends of the bolt, which consists of the vertical plates on both sides into which the lower ends of the pillars are inserted, and the vertically long holes provided in the vertical plates on both sides, are pivotally attached to the lower ends of the pillars. The bolts are respectively inserted into these vertically elongated holes, and the bolts are fastened and fixed to the vertical plate portions on both sides by nuts screwed to the bolts, so that the standing height of the pedestal material from the foundation surface such as the ground is adjusted. The surface of the solar cell panel with respect to sunlight can be set to an optimum state.

The simplified perspective view of the mount frame of the solar cell panel of the present invention. The simplified side view. The longitudinal section front view of the principal part of the state which assembled the vertical material and the horizontal material on the pillar material. The side view which abbreviate | omitted that part. The perspective view of the state which attached the vertical member via the connection member on the pillar material. The perspective view of a connection member. The perspective view of the state which attached the cross member on the vertical member. The perspective view of a clamp. (A), (B), and [C] are explanatory diagrams of the sequential attachment of the nut body to the concave groove. The perspective view of the part which fixed the edge part of the solar cell panel on the crosspiece with the clamp. The simplified perspective view of the state which decomposed | disassembled the mount frame of the solar cell panel. The simplified side view before folding a pillar material on the lower surface of a solar cell panel. The simplified side view of the folded state. The simplified side view which shows the modification of the mount frame of this invention solar cell panel.

  Referring to the drawings, specific embodiments of the present invention will be described. In FIGS. 1 to 4, a solar cell panel has a plurality of fixed lengths arranged in parallel with each other at predetermined intervals in the front-rear direction. The horizontal members 1 for mounting the solar cell panels are arranged in parallel with each other at appropriate intervals in the left-right direction, and these horizontal members 1 are supported from the lower surface side so as to be orthogonal to the horizontal members 1 for mounting the solar cell panels. A plurality of vertical members 2 having a certain length, connecting members 3 and 4 that are slidably fixed in the longitudinal direction of the vertical member 2 on the lower surface of the front and rear portions of each vertical member 2, and upper end portions The front and rear leg column members 5 and 6 are pivotally attached to the front and rear connecting members 3 and 4 so as to be rotatable in the longitudinal direction of the vertical member 1 and to be foldable so as to overlap the lower surface of the vertical member 2. And bases 9 and 10 attached to the lower ends of the front and rear pillar members 5 and 6, and the sun disposed on the cross member 1 The solar cell panel fixing clamp 7 for fixing the pond panel A to the cross member 1 and the cross member fixing clamp 8 for fixing the cross member 1 on the vertical member 2 are provided. .

  Further, a diagonal girder member 11 is disposed between the front and rear leg column members, and the upper and lower end portions of the oblique girder member 11 are connected to the lower surface of the vertical member 2 at the front leg column member 5. The connecting member 3 and the base 10 of the rear leg column 6 are pivotally attached to each other.

  The solar cell panel mounting cross member (hereinafter simply referred to as cross member 1) and the vertical member 2 supporting the cross member 1 and being combined with the cross member 1 in a planar lattice shape are aluminum or aluminum alloy. Are formed by extruding, and the like, and a groove 1a, 2a having a constant width and depth is provided over the entire length at the center of the upper surface of these cross member 1 and vertical member 2. In addition, the lower end of both side surfaces (surfaces facing in the front-rear direction in the cross member 1) continuously extending downward from the long side edge of the upper surface has a constant width that is refracted upward. Elongated locking protrusions 1b, 1b; 2b, 2b are provided so as to protrude over their entire length.

  The locking protrusions 1b and 1b provided at the lower ends of the front and rear side surfaces of the cross member 1 project outward from the front and rear side surfaces, as shown in FIGS. As shown in FIGS. 3 and 5, the locking protrusions 2b, 2b provided at the lower ends of both side surfaces (left and right side surfaces) are recessed inwardly at the lower ends of both side surfaces over the entire length. The lateral grooves 2e and 2e having a certain vertical width and depth are provided, and the horizontal grooves 2e and 2e are formed by refracting the front end of the horizontal lower end surface at a right angle upward. In the same manner as the locking projections 1b and 1b provided on the cross member 1, the projections may be projected outward from the lower ends of both side surfaces.

  Furthermore, narrow projecting piece portions 1c, 1c projecting horizontally inward from the opening edges of the both sides of the concave grooves 1a, 2a of the cross member 1 and the vertical member 2; One inner wall surface that projects 2c and 2c, and has the upper end portion connected to the base end of one projecting piece portion 1c and 2c, on the opposite inner wall surfaces of the concave grooves 1a and 2a. Are formed on the inner inclined wall surfaces 1d and 2d which are inclined in the direction in which the distance from the other vertically formed inner wall surface increases from the upper end toward the lower side. Further, positioning protrusions 1e and 1e of the solar cell panel A are provided so as to protrude upward from the edge of the upper end opening of the concave groove 1a in the cross member 1.

  The solar cell panel A is formed in a planar rectangular shape, and a positioning protrusion is provided on the upper surface of the opposed end portions of the adjacent front and rear transverse members 1 and 1 in the vertical width (width in the front-rear direction) of the solar cell panel A. The cross member 1 is juxtaposed and fixed on the vertical member 2 so that the distances between the pieces 1e and 1e are equal, and the solar cell panel A is opposed to the cross members 1 and 1 adjacent to each other in the front and rear. It is configured so that it is placed on the upper surface of the end portion and its front and rear end portions are fixed to the cross member 1 by a clamp 7. The length of the cross member 1 is several times the width of the solar cell panel A, and a plurality of solar cell panels A are attached in a row between the adjacent cross members 1 and 1. ing.

  As shown in FIGS. 4 and 10, the clamp 7 for fixing the solar cell panel A to the cross member 1 is pressed against the upper end surface of the solar cell panel A and the solar cell panel together with the upper end surface of the cross member 1. A flat rectangular holding piece 7a sandwiching the end of A, a bolt insertion hole 7b penetrating in the vertical direction at the center of the holding piece 7a, and a bolt insertion hole 7b, and the head is bolted It consists of a bolt 7c that can be pressed onto the holding piece 7a around the insertion hole, and a nut body 7d that is screwed into the lower part of the bolt 7c. The nut body 7d is a small rectangular block shape with a fixed rectangular thickness. The width between the front and rear side surfaces of the nut body 7d inserted in the groove 1a of the cross member 1 in the front-rear direction is shorter than the opening width of the groove 1a. At the same time, projecting from the front and rear sides of the groove 1a Locking projections 7e and 7e 'for locking to the lower surfaces of the projecting piece portions 1c and 1c are projected in the opposite horizontal directions.

  In these locking projections 7e and 7e ', one locking projection 7e protruding from the nut body 7d toward the inner inclined wall surface 1d side in the concave groove 1a is more than the other locking projection 7e'. The protruding length is formed long. In addition, in the plurality of cross members 1 arranged in parallel at predetermined intervals in the front-rear direction on the plurality of vertical members 2 juxtaposed in the left-right direction, the cross members disposed on the foremost side and the rearmost side. Since the solar panel A is arranged on both front and rear sides of the cross member 1 arranged in the middle other than 1, the holding piece 7a of the clamp 7 has a bolt 7c as the center and holding pieces on both the front and rear sides. The thing of the shape which provided the part is used.

  As shown in FIGS. 3, 7, and 8, the cross member fixing clamp 8 for fixing the cross member 1 in an orthogonal state on the vertical member 2 is provided at the lower ends of the front and rear side surfaces of the cross member 1. The locking protrusions 1b, the locking piece 8a made of a rectangular plate piece having a fixed thickness and having a locking piece portion bent downward to be locked to the locking piece 1b, and the center of the locking piece 8a in the vertical direction A bolt insertion hole 8b that penetrates the bolt insertion hole, a bolt 8c that is inserted into the bolt insertion hole 8b, and whose head can be pressed onto the locking piece 8a at the periphery of the bolt insertion hole, and screwed to the lower part of the bolt 8c The nut body 8d is formed in the same shape as the nut body 7d of the clamp 7 for fixing the solar cell panel A to the cross member 1.

  That is, the nut body 8d is formed in a small block shape having a flat rectangular shape with a certain thickness, and both left and right sides of the nut body 8d inserted in the concave groove 2a of the vertical member 2 in the left-right direction. The above-mentioned projecting piece portion 2c is formed so that the width between the faces is shorter than the left and right opening width of the concave groove 2a, and on both the left and right side surfaces, the upper end opening of the concave groove 2a faces each other. Locking projections 8e and 8e 'for locking to the lower surface of 2c are provided in the opposite horizontal directions. Further, in these locking projections 8e, 8e ′, one locking projection 8e protruding from the nut body 8d toward the inner inclined wall surface 2d side in the concave groove 2a is replaced with the other locking projection 8e ′. The protrusion length is formed longer than.

  In order to dispose the clamp 8 on the vertical member 2, as shown in FIG. 9 (a), the nut body 8d of the clamp 8 protrudes from one side and has a long protruding length. The locking protrusion 9e is inclined obliquely downward from the protrusion 8e side toward the tip, and inserted into the groove 2a from the upper end opening of the groove 2a of the longitudinal member 2, and subsequently the nut body 8d is When the posture of the provided bolt 8c is changed from the inclined state to the vertical state, the tip of the locking projection 8e comes into contact with the inner inclined wall surface 2d of the concave groove 2a and then moves upward along the inner inclined wall surface 2d. A short locking projection 8e 'projecting on the other side surface of the nut body 8d according to the movement is located below the other projecting piece 2c projecting from the upper end opening of the groove 2a. As shown in FIG. 9 (c), the both side locking projections 8e, 8e 'of the nut body 8d are inserted into the above-mentioned projecting piece at the upper end opening of the groove 2a. 2c, it can be locked to 2c. Since the arrangement of the clamp 7 with respect to the cross member 1 can be performed by the same operation, a detailed description is omitted.

  In the front and rear connecting members 3 and 4 in which the front and rear pedestal members 5 and 6 are respectively attached to the lower surface of the vertical member 2, as shown in FIGS. A rectangular horizontal plate portion 4a slidably superposed on the lower surface of 2, and projecting upward on the upper surfaces of both sides of the horizontal plate portion 4a projecting outward from both side surfaces of the vertical member 2, Clamp piece portions 4b and 4b, which are slidably engaged in the longitudinal direction of the longitudinal member 2 with the above-mentioned locking projection piece 2b projecting from the lower ends of both side surfaces of the longitudinal member 2, and this clamp Fixing bolts 4c for pressing the pieces 4b, 4b downward and crimping and fixing the tip portions thereof to the locking projections 2b of the vertical member 2, and downwardly suspended from both sides of the lower surface of the horizontal plate 4a The pedestal member mounting pieces 4d and 4d are provided.

  Similarly, in the front and rear connection members 3 and 4 in which the front and rear leg column members 5 and 6 are respectively attached to the lower surface of the vertical member 2, the front connection member 3 also has a central portion on the upper surface in the same manner as the rear connection member 4. A rectangular horizontal plate portion 3a slidably superimposed on the lower surface of the vertical member 2, and projecting upward on the upper surfaces of both side portions of the horizontal plate 3a projecting outward from both side surfaces of the vertical member 2 Clamp pieces 3b, 3b, which are slidably locked in the lengthwise direction of the vertical member 2 on the locking protrusion 2b projecting from the lower end of the side surface of the vertical member 2; The clamp pieces 3b, 3b are pressed downward, and their tips are pressed and fixed to the locking protrusions 2b of the longitudinal member 2, and the fixing bolts 3c are suspended downward from both sides of the lower surface of the horizontal plate 3a. It has leg post mounting pieces 3d and 3d, and the difference from the rear leg post 4 is the difference between the horizontal plate 3a and the leg post mounting pieces 3d and 3d. As shown in FIG. 4, the length (width) in the direction is larger than the length (width) in the front-rear direction between the horizontal plate portion 4a 3 of the rear leg column member 4 and the leg column attachment pieces 4d, 4d. It is only the point which forms.

  The clamp piece portions 3b and 4b in the front and rear connection members 3 and 4 are provided with support piece portions 3b1 and 4b1 projecting from the upper surfaces of the horizontal plate portions 3a and 4a, and vertical members from the support piece portions 3b1 and 4b1. A locking piece portion 3b2 that protrudes horizontally toward the locking projection piece 2b provided at the lower end of the side surface 2 and is provided with a downwardly bent locking end portion that engages with the locking projection piece 2b at the tip thereof; 4b2, and a locking protrusion 2b protruding from the lower end of the side of the vertical member 2 is interposed between the locking pieces 3b2 and 4b2 and the upper surfaces of both sides of the horizontal plates 3a and 4a. ing. Further, bolt insertion holes penetrating in the vertical direction are formed in the locking piece portions 3b2 and 4b2, and the horizontal plate portions 3a and 4a below the bolt insertion holes are inserted into the bolt insertion holes. Screw holes 3e, 4e for screwing the fixing bolts 3c, 4c are provided, and the locking pieces 3b2, 4b2 are moved downward by screwing the fixing bolts 3c, 4c into the screw holes 3e, 4e. And the distal end locking end is crimped and fixed to the locking protrusion 2b of the longitudinal member 2.

  In addition, the upper end portions of the leg column members 5 and 6 are turned around the leg column member mounting pieces 3d and 4d that are suspended downward from both sides of the lower surfaces of the horizontal plate portions 3a and 4a of the front and rear connection members 3 and 4, respectively. Support holes 14 and 15 are formed so as to be inserted through and supported by both end portions of the columnar member mounting bolts 12 that are pivotally attached. In addition, the pedestal member mounting bolt 12 has a nut 13 screwed into its tip.

  The front and rear leg columns 5 and 6 are formed by appropriately cutting a square pipe manufactured by extruding aluminum or an aluminum alloy or the like, similar to the horizontal member 1 and the vertical member 2. Bolt insertion holes 5a and 6a through which the above-mentioned pedestal member mounting bolts 12 are inserted are formed on both side surfaces of the upper ends of the materials 5 and 6. The front and rear leg column members 5 and 6 are inserted between the both side leg column member mounting pieces 3d and 3d of the front connection member 3 and between the both side leg column member mounting pieces 4d and 4d of the rear connection member 4, respectively. The columnar member mounting bolts 12 are pivotally attached to the lower surface of the vertical member 2 so that the bolts 12 can be rotated in the longitudinal direction of the vertical member 2 and greatly rotated around the bolt 12. The length of the front pillar member 5 is shorter than the length of the rear pillar member 6 so that the solar battery panel A disposed on the cross member 1 is directed toward sunlight. Is configured to have a desired inclination angle.

  Further, a diagonal girder material mounting bolt that rotatably supports the upper end portion (upward tilted end portion) of the above-mentioned diagonal girder material 11 at the rear part of the both-side leg pillar material mounting pieces 3d, 3d of the front connection member 3. Support holes 17 and 17 are formed through which both end portions of 16 are inserted and supported. The diagonal girder member 11 is also formed of a square pipe manufactured by extruding aluminum or an aluminum alloy or the like in the same manner as the columnar members 5 and 6, the cross member 1 and the vertical member 2.

The bases 9 and 10 attached to the lower ends of the front and rear column members 5 and 6 are rectangular horizontal substrates 9a and 10a.
And both side vertical plate portions 9b, 10b projecting upward on both sides of the upper surface of the horizontal substrates 9a, 10a and inserting the lower ends of the front and rear leg pillar members 5, 6 between the opposing surfaces, respectively; The vertical vertical holes 9b and 10b are formed with vertically elongated holes 9c and 10c which are formed so as to face each other on the left and right sides. An insertion hole is provided, and the base mounting bolts 18 and 18 are drilled in the vertical plate portions 9b and 10b on both sides of the front and rear bases 9 and 10 from one of the elongated holes 9c and 10c through the insertion hole to the other vertical. By inserting the nuts into the front ends of the bolts protruding from the vertical holes 9c and 10c of the plate portions 9b and 10b, respectively, and protruding from the vertical holes 9c and 10c, The bases 9 and 10 are rotatably attached respectively.

  In addition, the front part of the vertical plate parts 10 and 10b on both sides of the rear base 10 is provided with an oblique girder mounting bolt 19 that rotatably supports the lower end part (downward inclined end part) of the above-mentioned oblique girder material 11. Support holes 20, 20 each having a vertically long hole inserted and supported at both ends are formed.

  When assembling the solar cell panel frame constructed as described above, the front and rear connection members 3 and 4 are attached to the front and rear lower surfaces of all the vertical members 2, and the front and rear leg column members 5 are attached to the front and rear connection members 3 and 4, respectively. The upper end of 6 is rotatably attached by a bolt 12, and the front connection member 3 and the base 10 of the rear leg column 5 are connected by a diagonal beam 11. The front / rear connecting members 3 and 4 and the front and rear leg pillar members 5 and 6 and the oblique girder member 11 may be attached to the vertical members 2 at the installation site of the solar cell panel A. It is preferable to carry out in advance at the time of transportation to the construction site. If the front and rear connecting members 3 and 4 and the columnar members 5 and 6 and the diagonal beam member 11 are attached to the longitudinal member 2 in this way, The frame assembly work can be performed smoothly and efficiently, and accurate assembly is possible.

  In order to attach the front and rear connecting members 3 and 4 to each vertical member 2, the upper surfaces of the end portions of the horizontal plate portions 3a and 4a of the front and rear connecting members 3 and 4 are vertically applied to the lower surfaces of the front and rear ends of the vertical member 2. If it is moved so as to be inserted in the length direction of the material 2, the locking piece 3 b, the locking piece portion 3 b 2 of the both-side clamp piece 3 b, 4 b 2, The connecting members 3 and 4 can be slidably attached to the lower surface of the vertical member 2 by engaging with 2b. The engaging protrusions 2b and 2b are used as guides on the front and rear portions of the lower member 2 respectively. Keep it in place.

  The front and rear leg column members 3 and 4 are attached to the front and rear connection members 3 and 4 by connecting the upper end portions of the front and rear leg column members 3 and 4 between the leg column member mounting pieces 3d and 3d of the front and rear connection members 3 and 4, respectively. The column member mounting pieces 4d are inserted between the four column members 4d and the columnar member mounting bolts 12 and 12 are used to connect the front and rear connecting members 3 and 4 to the leg column member mounting pieces 3d and 4d in the longitudinal direction of the longitudinal member 2, respectively. This is done by mounting it so that it can rotate freely. After attaching the columnar members 3 and 4 to the connecting members 3 and 4 in advance at the lower ends of these front and rear columnar members 3 and 4, the front and rear bases 9 and 10 are respectively mounted by the base mounting bolts 18 as described above. deep.

  Further, a slanting girder member 11 is provided between the rear portions of the both-side leg column member mounting pieces 3d, 3d of the front side connection member 3 and the front side portions of both side vertical plate portions 10, 10b of the base 10 of the rear leg column member 6. The upper and lower ends of the oblique girder member 11 are arranged in a state where the upper and lower end portions are inserted, and the upper and lower end portions of the oblique girder member 11 are arranged on the bases of the both side leg column attachment pieces 3d and 3d of the front connection member 3 The two front and rear vertical plate portions 10 and 10b are pivotally attached by bolts 16 and 19, respectively, and the front and rear leg column members 5 and 6 are connected by a diagonal beam member 11.

  In this manner, the front and rear leg column members 5 and 6 are attached to the lower surfaces of the front and rear portions of the vertical members 2 via the front and rear connection members 3 and 4, and the front and rear leg column members are connected by the oblique girder material 11 for storage and storage. When transporting to the site, first, in FIG. 12, the rear connection member 4 is retracted to the rear end of the longitudinal member 2 along the lower surface of the longitudinal member 2, and the both-end locking protrusions on the lower end of the longitudinal member 2. The two clamp pieces 4b and 4b of the connecting member 4 slidably engaged with 2b and 2b are fixed to the both-side locking protrusions 2b and 2b of the vertical member 2 by screwing the fixing bolt 4c. The rear connection member 4 is fixed to the lower surface of the rear end of the longitudinal member 2.

  Next, when the front connection member 3 is slid and moved toward the front end side of the vertical member 2 along the locking protrusions 2b and 2b of the vertical member 2, as shown in FIG. After the diagonal girder 11 connecting the upper end moves toward the front end of the longitudinal member 2 integrally with the front connection member 3 and is connected to the lower end of the diagonal girder 11 along with the movement. The base 10 of the side columnar member 6 is drawn forward, the rear side columnar member 6 is tilted forward with the pivotal connection portion of the bolt 12 with the rear side connection member 4 as a fulcrum, and the front side connection member 3 is vertically When moving to the front end side of the material 2, the oblique girder material 11 and the rear leg column material 6 are stretched to form a single straight bar and overlapped on the lower surface of the vertical material 2. It is done. In addition, the front leg column member 5 is also tilted forward with the pivotal joint with the front connection member 3 as a fulcrum, along the lower surface of the vertical member 2, and tightened with the leg column member mounting bolts 12 as necessary. Hold the state.

  In this state, the clamp members 3b, 3b of the front connection member 3 slidably engaged with the both-end locking projections 2b, 2b on the lower end of the longitudinal member 2 are fastened by screwing the fixing bolts 3c. If the front connection member 3 is fixed to the lower surface of the front end portion of the vertical member 2, the front and rear leg column members 3, 4 and the diagonal beam member 11 are attached to the vertical member 2. It can be folded straight along the bottom surface.

  In this way, if the front and rear leg column members 3 and 4 and the oblique girder member 11 are folded on the lower surface of each longitudinal member 2 and bundled together with the transverse member 1 and tied together with a band or the like, storage, transportation, It can be handled easily and workability is improved.

  Next, in order to assemble the solar cell panel mount in the field, the clamp pieces 3b and 4b of the front and rear connection members 3 and 4 fixed to the both-side locking protrusions 2b and 2b of the vertical member 2 are fixed bolts. By loosening 3c and 4c, the fixing to both side locking projections 2b and 2b is released, and these front and rear connection members 3 and 4 are moved toward each other along the both side locking projections 2b and 2b of the longitudinal member 2. When sliding and moving, the rear base 10 that pivots the lower ends of the rear leg column 6 and the diagonal girder 11 is spaced downward from the vertical member 2 while the rear leg column 6 is rear The diagonal girder member 11 stands downward with the pivotal connection portion with the side connection member 4 as a fulcrum, and also rotates downward with the pivotal connection portion with the front connection member 3 as the fulcrum. If the pivoting portion with the member 3 is pivoted downward with the pivot point as a fulcrum, the front and rear leg column members 5 and 6 are placed upright with respect to the base surface B such as the ground. Door can be.

  Thereafter, the fixing bolts 3c and 4c are screwed to fix the front and rear connecting members 3 and 4 to the front and rear portions of the lower surface of the vertical member 2, respectively. Similarly, with respect to the other vertical members 2, the front and rear leg pillar members 5 and 6 are raised by the above operation, and the front and rear connecting members 3 and 4 are fixed to the front and rear portions of the lower surface of the vertical member 2, respectively.

  Then, these longitudinal members 2 are juxtaposed on the base surface B at appropriate intervals in the left-right direction, and the front and rear bases 9 and 10 are fixed to the base surface B via a base, anchor member, etc. A plurality of cross members 1 are arranged in parallel at predetermined intervals in the front-rear direction at intervals where the solar cell panel A can be installed so that the length direction of the vertical members 2 is orthogonal to the length direction of the vertical members 2. The cross member 1 and the vertical member 2 are combined in a lattice frame shape, and then the crossing portion of the cross member 1 and the vertical member 2 is integrally connected and fixed by the cross member fixing clamp 8.

  At this time, at each crossing portion of the cross member 1 and the vertical member 2, two cross member fixing clamps are arranged so that the cross member 1 is sandwiched between the grooves 2 a provided on the upper surface of the vertical member 2 at the front and rear of the cross member 1. The nut bodies 8d of 8, 8 are inserted into the concave groove 2a from above the concave groove 2a by the above-described operation, and these clamps 8, 8 are moved to the front and rear sides of the cross member 1 along the concave groove 2a. Then, the front end locking pieces of the locking pieces 8a and 8a are locked to the locking protrusions 1b and 1b provided at the lower ends of both the front and rear sides of the cross member 1, and then the bolts 8c and 8c are fixed. When the nut body 8d is pulled upward by screwing and the locking projections 8e and 8e 'projecting from the left and right side surfaces of the nut body 8d are brought into contact with the upper end opening of the concave groove 2a of the longitudinal member 2 with each other. The cross member 1 is fixed on the vertical member 2 by being pressed against the lower surface of the projecting piece portions 2c, 2c projecting to the vertical member 2.

  In this way, after fixing a plurality of cross members 1 on the plurality of vertical members 2 arranged side by side at appropriate intervals on the left and right by the cross member fixing clamps 8 in the front-rear direction, the solar cell panel A A plurality of solar panel fixing clamps 7 are arranged so as to span between the ends of the lateral members 1, 1 adjacent to each other, and the end portions are attached to the concave grooves 1 a of the lateral members 1. To the cross member 1.

  This fixing manner is the same as the transverse member fixing manner by the transverse member fixing clamp 8 described above. A plurality of solar cell panel fixing clamps 7 are attached to the concave grooves 1a of the transverse member 1 and these clamps 7 are pressed. Locking projections projecting on both front and rear sides of the nut body 7d by pulling the nut body 7d upward by screwing the bolts 7c and 7c with the piece 7a facing the upper surface of the end of the solar battery panel A 7e and 7e 'are pressed against the lower surface of the projecting piece portions 1c and 1c projecting in the abutting direction at the upper end opening of the groove 1a of the cross member 1 so that the holding piece 7a is attached to the end of the solar cell panel A. A plurality of solar cells are placed on the cross member 1 by pressing the end portion of the solar cell panel A together with the upper surface of the end portion of the cross member 1 that presses against the upper surface of the solar cell panel A and supports the lower surface of the end portion of the solar cell panel A. Panel A is fixed and supported in a state where it is laid out vertically and horizontally.

  In addition, as shown in FIG. 1, the platform of the solar cell panel assembled on the base surface B as described above has the brace 21 connecting the rear leg column members 6, 6 adjacent to the left and right. Thus, a more rigid gantry can be configured.

  Further, in the above-described embodiment, the upper and lower end portions of the oblique girder member 11 are attached to the front connection member 3 pivotally attached to the upper end portion of the front leg column member 5 and the lower end base 10 of the rear leg column member 6. As shown in FIG. 14, an intermediate connection member 30 having the same structure as the front and rear connection members 3 and 4 is attached to the longitudinal portion 2 of the longitudinal direction of the longitudinal member 2. The front and rear pedestals of both side hanging pieces 30a and 30a are arranged so as to be slidable and fixed along the pieces 2b and 2b and are suspended from both sides of the lower surface of the horizontal plate portion of the intermediate connecting member 30. Between the pace 9 of the member 5 and, if necessary, between the rear portions 30a, 30a of the intermediate connecting member 30 and the pace 10 of the rear leg column member 6, the slant beam 11a (11b) The upper and lower ends may be pivotally attached to each other. Since other configurations are the same as those in the above embodiment, the same portions are denoted by the same reference numerals and detailed description thereof is omitted.

1 Cross member 2 Vertical member
1a, 2a Groove
1b, 2b Locking protrusions 3, 4
3a, 4a Horizontal plate
3b, 4b Clamp piece
3c, 4c Fixing bolts 5, 6 Front and rear pedestal columns 7 Solar panel fixing clamps 8 Horizontal material fixing clamps
7a Presser piece
8a Locking piece
7c, 8c bolt
7d, 8d nut body
7e, 8e Locking projection 9, 10 Front / rear base
11 Diagonal girders
12 Pillar mounting bolt
16 Diagonal girder mounting bolt

Claims (9)

  A plurality of solar cell panel mounting cross members arranged in parallel in the front-rear direction and a plurality of cross members arranged in parallel in the left-right direction and supporting the solar cell panel mounting cross members from the lower surface side Vertical members, connecting members that are slidably fixed in the longitudinal direction of the longitudinal members on the lower surfaces of the longitudinal parts of each longitudinal member, and upper ends that are connected to the longitudinal connecting members in the longitudinal direction of the longitudinal members, respectively. A sun characterized by comprising a front and rear leg pillar material pivotably mounted so as to be able to rotate and overlap with a lower surface of a vertical member, and a base attached to the lower ends of these front and rear leg pillar materials Battery panel mount.   The horizontal member for mounting the solar cell panel and the vertical member supporting the horizontal member are formed of square pipes, and a groove is provided over the entire length of the central part of the upper surface of the horizontal member and the vertical member. A locking protrusion having a certain width is provided at the lower end of the surface over the entire length, and the end of the solar cell panel is sandwiched between the upper surface of the end of the cross member in the groove provided in the cross member. A clamp having a pressing piece to be worn is mounted, and the transverse member is fixed to the longitudinal member by engaging the concave groove provided in the longitudinal member with the above-mentioned locking projection piece protruding from the lower end of both side surfaces of the transverse member. 2. A solar cell panel pedestal according to claim 1, wherein a clamp having a locking piece is mounted.   A clamp having a pressing piece for sandwiching the end portion of the solar cell panel has a bolt insertion hole penetrating in the vertical direction in the holding piece, and a bolt whose head is pressed against the upper surface of the pressing piece in the bolt insertion hole The nut body disposed in the groove of the horizontal member for mounting the solar cell panel is screwed to the lower part of the bolt, and the upper end of the groove is formed on both side surfaces of the nut body. The stand for a solar cell panel according to claim 1 or 2, wherein a locking projection for locking to the lower surface of the projecting piece projecting from the opening is provided.   The clamp having a locking piece for fixing the cross member to the vertical member has a bolt insertion hole penetrating in the vertical direction in the locking piece, and the head is placed on the upper surface of the locking piece. A bolt to be crimped is inserted, and a nut body disposed in a concave groove provided in the vertical member is screwed into a lower portion of the bolt, and the concave groove is formed on both side surfaces of the nut body. The stand for a solar cell panel according to claim 1 or 2, wherein a locking projection for locking to a lower surface of the protruding piece portion protruding from the upper end opening is provided.   The nut body is formed so as to be able to be inserted and disposed in the groove from the upper end opening of the groove, and the locking protrusions provided on both side surfaces of the nut body are long and the locking protrusions are long. The inner wall surface of the concave groove having a top end connected to the base end of one projecting piece projecting from the upper end opening of the concave groove for locking the long locking projection 5. The solar cell panel mount according to claim 3, wherein the solar cell panel mount is formed on an inclined wall surface inclined outward.   The connecting member has a rectangular horizontal plate portion that is slidably overlapped with the center of the upper surface on the lower surface of the vertical member, and is protruded on both sides of the upper surface of the horizontal plate portion, and the tip portion is provided on both side surfaces of the vertical member. A clamp piece locked to a locking protrusion projecting from the lower end, and a connecting member is a vertical member by pressing the clamp piece downward and crimping the tip to the locking protrusion. A fixing bolt to be fixed to the lower surface of the pedestal, a pedestal mounting member that hangs downward from both sides of the lower surface of the horizontal plate portion, and inserts the upper end of the pedestal material between the opposing inner surfaces, and the pedestal 3. The support hole according to claim 1, further comprising: a support hole that is provided on the material mounting piece and is inserted through and supported by both ends of a bolt pivotally attached to the upper end portion of the pillar member. A solar panel mount.   Attach the pedestal of the connecting member between the front and rear pedestal members, with the lower end pivotally attached to the base of one of the front and rear pedestal members and the upper end attached to the upper end of the other pedestal material An oblique girder material that is pivotally attached to this mounting piece with bolts by interposing between the pieces is arranged, and this oblique girder material can be folded so as to overlap the lower surface of the vertical material together with the pillar material. The frame of the solar cell panel according to claim 1 or 6, wherein the frame is configured as follows.   An intermediate connection member is mounted on the lower surface of the intermediate portion in the longitudinal direction of the longitudinal member between the front and rear pedestal members, and the lower end portion is connected to the base of the pedestal material between the connection member and the base of the pedestal material. An oblique girder material is provided that is pivotally attached to the upper end portion of the intermediate connecting member and is pivotally attached to the attachment piece by a bolt. 7. The solar cell panel pedestal according to claim 1 or 6, wherein the diagonal girder material is configured to be foldable so as to overlap the lower surface of the vertical member together with the pillar material.   The base has a rectangular horizontal board and both sides vertical plate part projecting upward on both sides of the upper surface of the horizontal board, and the lower end of the pedestal material is inserted between the opposing faces. It consists of vertical holes provided in the plate part, and both ends of the bolts pivotally attached to the lower end of the pillar material are inserted into these vertical holes, and the bolts are tightened by nuts screwed into the bolts. The solar cell panel mount according to claim 1, wherein the frame is fastened and fixed to both vertical plate portions.

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