JP2019173298A - Roof structure - Google Patents

Abstract

To provide a roof structure which can present a roof with floating feeling.SOLUTION: A car port 1 comprises: a frame 2A, which consists of a pair of columns 3, and a beam 4 fixed to the pair of columns 3, being erected in parallel; a frame 2B, which consists of a pair of columns 3, and a beam 4 fixed to the pair of columns 3, being erected in parallel; a strut 10A erected on the beam 4 of the frame 2A; a strut 10B erected on the beam 4 of the frame 2B; and a roof 50 supported with the struts 10A, 10B. The positions of the struts 10A, 10B along the longitudinal direction of the beam 4 are arranged to be on the inside away from the edge of the roof 50.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a roof structure such as a carport.

Conventionally, as a roof structure, a carport including a support, a purlin support fixed to the support, and a roof attached to the purlin support is known (see Patent Document 1).
The roof is framed by a pair of left and right girder members and a pair of front and rear beams, and a plurality of purlin members along the front and rear direction are attached to the pair of beams, and the pair of girder members along the left and right direction A plurality of rafter members are attached, the plurality of rafter members support a resin roof plate, and the roof plate is pressed from above by a roof plate holding member screwed to the rafter member.
The above-mentioned girders, beams, purlin materials, rafter members and roof plate retainer members are structural materials formed of aluminum extrusions, and the purlin materials are screwed directly to the purlin receiving material.

Japanese Utility Model Publication No. 5-38105

  By the way, in the carport described in Patent Document 1, since the purlin material is screwed directly to the purlin receiving material, the roof cannot be disposed away from the purlin receiving material. For this reason, it is difficult to produce a floating feeling that makes the roof float with respect to the frame constituted by the purlin support material and the column.

  The objective of this invention is providing the roof structure which can produce the floating feeling of a roof.

The roof structure of the present invention includes at least two frames each of which is constituted by a pair of columns and beams fixed to the pair of columns, arranged in parallel, a bundle standing on each of the beams, and the bundle The bundle is arranged inside the peripheral edge of the roof in the longitudinal direction of the beam.
According to the roof structure of the present invention, since the bundle is disposed between the beam and the roof, the roof can be disposed away from the beam in accordance with the vertical dimension of the bundle. In addition, since the bundle is arranged on the inner side of the peripheral edge of the roof in the longitudinal direction of the beam, even if the roof is looked up from the column side, it is possible to configure an appearance in which the bundle is hidden to some extent and is not conspicuous.
In this way, by arranging the roof apart from the beam and making the bundle inconspicuous, it is possible to produce a floating feeling that the roof is floating above the beam.

In the roof structure of the present invention, the roof includes a roof frame constituting a peripheral portion of the roof, an upper beam having both ends attached to the roof frame, and a roof material attached to the roof frame. The upper beam may be attached to the upper end of the bundle, and the longitudinal direction of the upper beam may be parallel to the longitudinal direction of the beam.
According to such a configuration, since the longitudinal direction of the upper beam and the beam is parallel, for example, compared to the case where the longitudinal direction of the upper beam and the beam are orthogonal, the mounting position of the bundle on the upper beam and the beam is increased. It is possible to freely set the beam and the position along the longitudinal direction of the beam.

In the roof structure of the present invention, the roof includes a roof frame constituting a peripheral portion of the roof, an upper beam having both ends attached to the roof frame, and a roof material attached to the roof frame. The roof material may be arranged below the upper beam.
According to such a configuration, by arranging the roof material below the upper beam, it is possible to configure a simple appearance in which the upper beam is not visible even when the roof is looked up from the lower side.

In the roof structure of the present invention, the roof is configured by a roof material having a hollow portion, and the roof material is formed with an insertion port that communicates with the hollow portion. The upper end of the bundle may be inserted.
According to such a configuration, the upper end portion of the bundle can be placed in the hollow portion of the roof material by inserting the upper end portion of the bundle into the roof material insertion port. It can be arranged. Thus, the upper end part of the bundle can be hidden by the roof material, and a simple appearance in which the roof and the attachment part of the bundle are not exposed when the roof is looked up from the lower side can be configured.

In the roof structure of the present invention, the vertical dimension of the pair of struts in one of the two frames may be different from the vertical dimension of the pair of struts in the other of the two frames.
According to such a configuration, even if the bundle standing on one frame and the bundle standing on the other frame have the same vertical dimension, the support of one frame and the support of the other frame By making the vertical dimensions of the two different, it is possible to set the roof gradient in the direction in which the two frames are juxtaposed, and it is possible to employ a common bundle that is erected on each of the two frames.
The vertical dimension of the column here is the vertical dimension from the ground to the upper end of the column erected on the ground. This vertical dimension is, for example, the length of the column itself or the depth position at which the column foundation is embedded in the ground. It can be set by adjusting.

In the roof structure according to the present invention, the roof includes a roof frame that forms a peripheral edge of the roof, an upper beam having both ends attached to the roof frame, and both ends of the roof frame that are arranged in parallel in the roof frame. Comprises a roof material constituted by a plurality of metal panel members attached to the roof frame, and the longitudinal direction of the upper beam and the beam is parallel, and the longitudinal direction of the plurality of panel members is , And may be orthogonal to the longitudinal direction of the upper beam.
According to such a configuration, when an external force along the longitudinal direction of the upper beam is applied to the roof, the external force can be received by the upper beam, and along the longitudinal direction of the plurality of panel members. When an external force is applied to the roof, the external force can be received by a plurality of panel materials. As described above, in the present invention, in addition to the upper beam, a plurality of panel members can function as a roof structural member, and the rigidity of the roof can be increased.

In the roof structure of the present invention, an upper illumination tool that illuminates the lower surface of the roof may be installed in a region of the beam that faces the lower surface of the roof in the vertical direction.
According to such a configuration, it is possible to illuminate the floating feeling of the roof that is spaced upward from the beam by illuminating the lower surface of the roof with the upper illumination tool installed on the beam. In addition, compared with the case where the upper lighting fixture is mounted at a position protruding from the beam by, for example, a mounting arm, the upper lighting fixture fits in the region of the beam facing the lower surface of the roof, so the upper lighting fixture is not noticeable in appearance. Can be configured.

  ADVANTAGE OF THE INVENTION According to this invention, the roof structure which can produce the floating feeling of a roof can be provided.

The perspective view which shows the car port which concerns on 1st Embodiment of this invention. The front view which shows the carport which concerns on 1st Embodiment from the front. The side view which shows the car port which concerns on 1st Embodiment. Sectional drawing which shows the car port which concerns on 1st Embodiment. Explanatory drawing which shows the principal part of the carport which concerns on 1st Embodiment. Explanatory drawing which shows the beam of the carport which concerns on 1st Embodiment. Explanatory drawing which shows the lighting fixture of the carport which concerns on 1st Embodiment. The perspective view which decomposes | disassembles and shows the water stop structure of the carport which concerns on 1st Embodiment. Explanatory drawing which shows the bundle of the carport which concerns on 1st Embodiment. Explanatory drawing which shows the water stop member of the carport which concerns on 1st Embodiment. Sectional drawing which shows the roof material of the carport which concerns on 1st Embodiment. Explanatory drawing which shows construction of the roof material of the carport which concerns on 1st Embodiment. The perspective view which shows construction of the frame material of the carport which concerns on 1st Embodiment. The perspective view which shows construction of the corner part of the roof frame of the carport which concerns on 1st Embodiment. The perspective view which shows the water stop structure of the carport which concerns on 2nd Embodiment of this invention. The perspective view which shows the water stop member of the carport which concerns on 2nd Embodiment. The perspective view which decomposes | disassembles and shows the water stop structure of the carport which concerns on 2nd Embodiment. The perspective view which shows the water stop member of the carport which concerns on 3rd Embodiment of this invention. The perspective view which decomposes | disassembles and shows the water stop structure of the carport which concerns on 3rd Embodiment. The schematic diagram which shows the carport which concerns on the modification of this invention.

[First Embodiment]
Hereinafter, a first embodiment of the present invention will be described with reference to the drawings.
1-4, the carport 1 as the roof structure according to the first embodiment is erected on two frames 2A and 2B and frames 2A and 2B, which are lower structures installed in a parking space. A plurality of bundles 10 (10A, 10B) and a roof 50 that is an upper structure supported by the plurality of bundles 10 (10A, 10B) are provided.
In the following description, the front direction of the car port 1 is the X-axis direction, the depth direction of the car port 1 is the Y-axis direction, and the vertical direction of the car port 1 is the Z-axis direction. The X, Y, and Z axis directions are orthogonal to each other.

  The frames 2 </ b> A and 2 </ b> B are each configured as a gate-type frame including a pair of support columns 3 standing in a parking space and a beam 4 fixed to the pair of support columns 3. The frames 2A and 2B are juxtaposed in the Y axis direction with a gap therebetween, the pair of support columns 3 are opposed to each other with a gap in the X axis direction, and the longitudinal direction of the beam 4 is along the X axis direction. Yes. The interval between the pair of support columns 3 is set as appropriate according to the number of cars or the like parked in the parking space. The vertical dimension L1 of the column 3 in the frame 2A is larger than the vertical dimension L2 of the column 3 in the frame 2B, so that the roof 50 supported by the frames 2A and 2B extends from the rear side to the front side in the Y-axis direction. As it goes, the slope of the roof 50 is set to be inclined obliquely upward with respect to the virtual horizontal plane 52.

As shown in FIGS. 6A and 6B, the beam 4 includes a beam main body 410 and a recess forming body 420 attached to the upper portion of the beam main body 410. Here, FIG. 6 (A) shows a longitudinal section of the beam 4, and FIG. 6 (B) is a CC sectional view shown in FIG. 6 (A).
The beam main body 410 has a beam upper surface portion 411, a beam lower surface portion 412, and a pair of beam side surface portions 413 and 414, and is formed in a hollow frame shape.
The recess forming body 420 includes a bottom surface portion 421 attached to the beam upper surface portion 411, and side frame portions 422 and 423 having a rectangular cross-sectional shape formed on both side edges along the X-axis direction of the bottom surface portion 421. A recess 4A along the X-axis direction is formed by the recess bottom surface 421A of the bottom surface portion 421 and the recess side surfaces 422A and 423A facing each other with a gap in the Y-axis direction among the side frame portions 422 and 423. The recess 4A is in a region of the beam 4 that faces the lower surfaces 822A and 862A of the roof 50 in the Z-axis direction. The concave side surfaces 422A and 423A extend downward from the upper surface 424 of the side frame portions 422 and 423, and the concave bottom surface 421A is disposed between the lower edges of the concave side surfaces 422A and 423A. The side frame portions 422 and 423 are respectively formed with attachment piece portions 425 protruding in the Y-axis direction from the concave side surfaces 422A and 423A.

An illumination attachment member 501 is screwed to the attachment piece 425 of the side frame portions 422 and 423, and an upper light 510 as an upper illuminator whose irradiation direction is upward is attached to the illumination attachment member 501. It is attached via a metal fitting 502.
As shown in FIG. 7A, the upper light 510 is formed in a rectangular shape in plan view, and a plurality of light emitting elements 51 such as LEDs are installed on the upper surface 511 of the upper light 510 along the longitudinal direction thereof. ing.
As shown in FIG. 7B, the mounting bracket 502 is formed in a substantially U-shaped cross section, and engaging projections 503 projecting inward are formed on both edges. This mounting bracket 502 is screwed to the illumination mounting member 501.
The upper light 510 is attached to the mounting bracket 502 by fitting the upper light 510 from above and engaging the engaging projections 503 on both sides in the width direction of the upper light 510 (FIG. 6A, FIG. 6). (See (B))
Thus, the upper light 510 attached to the beam 4 is disposed in a space defined by the recess 4A of the recess forming body 420, and is disposed at the center position in the Y-axis direction between the recess side surfaces 422A and 423A. (See FIG. 6A). Further, as shown in FIG. 2, the upper light 510 is disposed away from the two bundles 10 by a distance L3 that is equal to the X-axis direction. That is, the upper light 510 is arranged at equal intervals with respect to the two bundles 10 described above. The upper light 510 is disposed at a central position in the X-axis direction between the two bundles 10. The conduit 100 is accommodated in the recess 4A.

An upper cover material 5A (cover material) that covers the opening in the upper portion of the recess 4A is attached to the recess forming body 420. The upper cover member 5 </ b> A includes a plate-like cover plate portion 521 extending in the X-axis direction and two engagement piece portions 522 extending downward from the cover plate portion 521. The two engaging pieces 522 are engaged with the two engaging claws 501A locked to the lighting attachment member 501 in a snap-fit manner, and the cover plate 521 covers the opening of the recess 4A. It is in contact with the upper surface 424 of the frame portions 422 and 423.
The cover plate portion 521 is formed with a bundle insertion port (not shown) through which the bundle 10 is inserted, and an illumination opening 523 disposed at a position corresponding to the upper light 510 in the Z-axis direction. A light-transmitting cover 524 having a light-transmitting property such as polycarbonate is provided at 523. The illumination opening 523 has a rectangular shape and is equal to or larger than the length dimension in the X-axis direction and the width dimension in the Y-axis direction of the upper surface 511 (particularly the light projecting surface) of the upper light 510. . The illumination opening 523 is disposed immediately above the upper surface 511 of the upper light 510.
The upper light 510 installed in this manner emits irradiation light upward from the upper surface 511, and this irradiation light passes through the translucent cover 524 to the roof 50 (mainly a plurality of roofing materials 81 in this embodiment). Illuminate the lower surfaces 822A, 862A. In this embodiment, the length dimension of the upper light 510 is about 80% of the dimension between the two bundles 10 in the X-axis direction, and the lower surfaces 822A and 862A of the roof 50 formed by the upper light 510. The irradiation range I in the X-axis direction (see FIG. 2) is that bundles 10A and 10A (X-axis bundles 10A, 10A ( The entire range between the bundles 10B, 10B). As a result, the floating effect of the roof 50 spaced upward from the beam 4 is illuminated.
Moreover, the reflected light reflected on the lower surfaces 822A and 862A of the roof 50 among the irradiation light described above becomes indirect illumination that illuminates the lower side from the roof 50 side. Furthermore, since the roof 50 is inclined obliquely upward as it goes from the rear side to the front side, the reflected light reflected on the lower surfaces 822A and 862A of the inclined roof 50 is a road located ahead of the carport 1. Illuminate.

  The beam side surface portions 413 and 414 of the beam main body 410 extend below the beam lower surface portion 412, and an engaging convex portion 415 is formed at each lower edge portion. A lower cover material 5 </ b> B in which an engagement recess 504 that engages with these engagement projections 415 is attached to the beam side surface portions 413 and 414. The lower cover material 5B is arranged so as to cover the lower surface of the beam main body 410, and a plurality of downlights 530 as a lower illumination tool whose irradiation direction is downward are installed along the X-axis direction as shown in FIG. Has been. As shown in FIG. 7C, the downlight 530 is formed in a substantially circular shape, and its lower surface 531 is a light projecting surface.

  The roof 50 includes a roof frame 60 that constitutes a peripheral portion of the roof 50 by framed four frame members 61 to 64, an upper beam 70 having both ends attached to the roof frame 60, and a parallel arrangement in the roof frame 60. A plurality of roofing materials 81 are provided. The frame members 61 to 64 and the upper beam 70 of the roof frame 60 are formed as a structural material by an aluminum extruded shape. In the present embodiment, a plurality of roof materials 81 are also formed by an aluminum extruded shape, and the roof By being fixed to the frame 60, the function as a structural material can be exhibited. The frame members 61 and 62 are configured as a front frame 61 and a rear frame 62 along the X-axis direction, and the frame members 63 and 64 are configured as side frames 63 and 64 along the Y-axis direction. The side frame 63 is formed with an upper overlapping portion 632 extending toward the side frame 64, and the side frame 64 is formed with an upper overlapping portion 642 extending toward the side frame 63 (see FIG. 4). . The roof material 81 is disposed below the upper beam 70. The roof material 81 is formed with insertion openings 91 and 92 through which the bundle 10 is inserted. The longitudinal direction of the upper beam 70 is along the X-axis direction and is parallel to the longitudinal direction of the beam 4. The longitudinal direction of the plurality of roof materials 81 is along the Y-axis direction and is orthogonal to the longitudinal direction of the upper beam 70. In this roof 50, the roof frame 60 is not fixed to the frames 2 </ b> A and 2 </ b> B, and the upper beam 70 is fixed to the bundle 10, so that the roof frame 60 protrudes in the X-axis direction from the pair of columns 3. It is possible to construct the roof 50 to be used. As shown in FIG. 8, on the upper surface portion 72 of the upper beam 70, through holes 73 and 74 through which a fixing bolt 7 and a fixing screw 123, which will be described later, pass, are formed. The plate-like lid member 75 is closed by being screwed to the upper surface portion 72.

The bundle 10 includes a plurality of bundles 10A erected on the beam 4 of the frame 2A and a plurality of bundles 10B erected on the beam 4 of the frame 2B. The bundles 10A and 10B are configured in the same manner. Yes. The plurality of bundles 10A are arranged on the inner side of a roof frame 60 (described later) that forms the peripheral edge of the roof 50 in the longitudinal direction (X-axis direction) of the beam 4 of the frame 2A. It is arrange | positioned inside the roof frame 60 in the longitudinal direction (X-axis direction) of the beam 4 of this.
As shown in FIGS. 5 and 8 to 10, the bundle 10 includes a bundle member 20 formed of an aluminum extruded shape, a steel reinforcing member 30 disposed in a hollow portion 25 of the bundle member 20, and a bundle member. 20 and a steel fixed body 40 fixed to the lower end 29 of the steel. As shown in FIG. 5, the fixed body 40 is disposed in the concave portion 4A of the beam 4, and the upper cover material 5A is disposed in the opening of the concave portion 4A so as not to be exposed to the outside.

The bundle 20 has a pair of first bundle pieces 21 and 22 that face each other in the Y-axis direction and a pair of second bundle pieces 23 and 24 that face each other in the X-axis direction. The first bundle piece portions 21 and 22 and the second bundle piece portions 23 and 24 form a hollow portion 25 along the Z-axis direction. The upper surface of the bundle 20 is inclined with respect to the virtual horizontal plane 52 at an angle corresponding to the gradient of the roof 50. In the present embodiment, the horizontal direction in the plane of the first bundle piece portion 21 and the first bundle piece portion 22 is along the Y axis direction, and the horizontal direction in the plane of the second bundle piece portions 23 and 24 is the X axis. Along the direction. The width dimension W1 along the Y-axis direction of the second bundle piece parts 23, 24 is set to be larger than the width dimension W2 along the X-axis direction of the first bundle piece part 21 and the first bundle piece part 22. .
On the inner surface of the second bundle piece portion 23, two abutting convex portions 231 projecting in the X-axis direction toward the second reinforcing piece portion 33 described later are formed. Are formed with two abutting convex portions 241 projecting in the X-axis direction toward a second reinforcing piece portion 34 to be described later.
The first corner portion 261 where the second bundle piece portion 23 and the first bundle piece portion 21 intersect bulges inward (on the axial center side of the bundle material 20) with respect to the second bundle piece portion 23 and the first bundle piece portion 21. The second corner portion 262 where the second bundle piece portion 23 and the first bundle piece portion 22 intersect is inside the second bundle piece portion 23 and the first bundle piece portion 22 (on the axial center side of the bundle material 20). The third triangular portion 263 where the second bundle piece portion 24 and the first bundle piece portion 21 intersect is inside the second bundle piece portion 24 and the first bundle piece portion 21 (the axial center of the bundle member 20). And the fourth square portion 264 where the second bundle piece portion 24 and the first bundle piece portion 22 intersect is inside (the bundle material 20) with respect to the second bundle piece portion 24 and the first bundle piece portion 22. It bulges out to the center of the shaft.
FIG. 10A is a plan view showing the bundle 10 and the water stop member 110. FIG. 10B is a cross-sectional view taken along line BB shown in FIG. 10A, and illustration of the bundle 10 is omitted. As shown in FIG. 10A, the thickness dimension T1 along the Y-axis direction of the first corner part 261 is larger than the thickness dimension T3 of the second bundle piece part 23, and the X-axis of the first corner part 261 is the same. The thickness dimension T2 along the direction is larger than the thickness dimension T4 of the first bundle piece portion 21. The second bundle pieces 23 and 24 have the same thickness T3, and the first bundle piece 21 and the first bundle piece 22 have the same thickness T4. Similarly to the first corner portion 261, the second corner portion 262 to the fourth corner portion 264 have thickness dimensions T1 and T2, and the second bundle piece portions 23 and 24 have a thickness dimension T3 and the first bundle piece. The thickness dimension is larger than the thickness dimension T4 of the part 21 and the first bundle piece part 22.
The first corner portion 261 to the fourth corner portion 264 are respectively provided with fixing holes 27 into which fixing bolts 7 as fixing tools are screwed. Each fixing hole 27 extends along the axial direction of the bundle member 20 and opens at the upper surface and the lower surface of the bundle member 20. Each fixed hole 27 formed in this way is not continuous with the hollow portion 25 of the bundle material 20 by a slit or the like, and the portion surrounding the fixed hole 27 in the bundle material 20 is sheared in the horizontal direction. It is used to improve proof stress.

The reinforcing member 30 is formed to extend in the Z-axis direction from the upper surface to the lower surface of the bundle member 20 and supports the vertical load of the roof 50. As shown in FIG. 10A, the reinforcing member 30 includes a pair of first reinforcing piece portions 31 and 32 facing each other in the Y-axis direction and a pair of second reinforcing piece portions 33 and 34 facing each other in the X-axis direction. And the four corners are formed into round corners by arcuate surfaces.
The second reinforcing piece portions 33 and 34 are respectively attached to the second bundle piece portions 23 and 24 of the bundle member 20 by screws 6, and the protruding ends of the contact convex portions 231 and 241 are secondly attached by screwing of the screws 6. The reinforcing pieces 33 and 34 are in contact with the outer surfaces.
The first reinforcing piece portion 31 is located closer to the first bundle piece portion 22 side than the first corner portion 261 and the third triangular portion 263 in the Y-axis direction, and the first reinforcing piece portion 32 is the first reinforcing piece portion 32 in the Y-axis direction. It is located closer to the first bundle piece part 21 side than the square part 262 and the fourth square part 264.
Further, the second reinforcing piece portion 33 is disposed at a position sandwiched between the first corner portion 261 and the second corner portion 262, and the second reinforcing piece portion 34 includes the third triangular portion 263 and the fourth corner portion 264. It is arranged at a position between them.

As shown in FIGS. 9A and 9B, the fixed body 40 is configured by vertically stacking a first fixing member 40A and a second fixing member 40B formed by press bending a metal plate material. Has been. The first fixing member 40A includes a fixing piece portion 41A, a pair of hanging piece portions 42A and 43A, and a pair of attachment piece portions 44A and 45A, and the second fixing member 40B includes a fixing piece portion 41B and And a pair of hanging piece portions 42B and 43B, a pair of attachment piece portions 44B and 45B, and two reinforcing ribs 46.
The fixed piece portion 41A has a quadrangular shape in plan view, and a hole through which the fixed bolt 7 is inserted is formed in the fixed piece portion 41A. The fixing piece portion 41 </ b> A is fixed to the lower end 29 of the bundle member 20 by fastening the fixing bolt 7 inserted through the hole into the fixing hole 27 of the bundle member 20. Further, a piping opening 471 is formed in a portion of the fixed piece portion 41 </ b> A that faces the hollow portion 25 of the bundle member 20. The hanging piece 42A is continuous with the side edge of the fixed piece 41A on the left side in FIG. 9A, and the hanging piece 43A is on the side edge of the fixed piece 41A on the right side in FIG. 9A. It is continuous. The attachment piece portion 44A is continuous with the lower edge of the drooping piece portion 42A and extends to the left side in FIG. 9A, and the attachment piece portion 45A is continuous with the lower edge of the drooping piece portion 43A. At the same time, it extends to the right side in FIG. A plurality of holes 48 through which the fixing screws 8 for fixing the beam 4 are inserted are formed in the attachment pieces 44A and 45A.
A pipe notch 472 is formed in the hanging piece portions 42A and 43A and the attachment piece portions 44A and 45A. The piping cutout 472 of the hanging piece portion 42A and the mounting piece portion 44A is formed continuously to the hanging piece portion 42A and the mounting piece portion 44A, and is an outer edge along the Y-axis direction of the mounting piece portion 44A. It is open. Further, the piping notch 472 of the hanging piece 43A and the mounting piece 45A is formed continuously from the hanging piece 43A and the mounting piece 45A, and the outside of the mounting piece 45A along the Y-axis direction. Open at the edge.
The fixed piece portion 41B, the suspended piece portions 42B and 43B, and the attachment piece portions 44B and 45B are formed in substantially the same manner as the fixed piece portion 41A, the suspended piece portions 42A and 43A, and the attachment piece portions 44A and 45A described above. The dimension in the X-axis direction of the fixed piece part 41B is slightly smaller than the dimension in the X-axis direction of the fixed piece part 41A, and the vertical dimension of the suspended piece parts 42B and 43B is smaller than the vertical dimension of the suspended piece parts 42A and 43A. The dimensions in the X-axis direction of the attachment pieces 44B and 45B are set slightly larger than the dimensions in the X-axis direction of the attachment pieces 44A and 45A. In addition, a hole through which the fixing bolt 7 is inserted is not formed in the fixing piece portion 41B.
The fixed piece portion 41B is disposed below the fixed piece portion 41A with a space therebetween, and forms a space 49 in which the fixed bolt 7 can be accommodated between the fixed piece portion 41B and the fixed piece portion 41A. The fixed piece portion 41B is attached to the fixed piece portion 41A by a plurality of mounting screws 9. The outer surface of the hanging piece portion 42B is superimposed on the inner surface of the hanging piece portion 42A, and the outer surface of the hanging piece portion 43B is superimposed on the inner surface of the hanging piece portion 43A. The upper surface of the attachment piece portion 44B is overlaid on the lower surface of the attachment piece portion 44A, and the upper surface of the attachment piece portion 45B is overlaid on the lower surface of the attachment piece portion 45A.
The two reinforcing ribs 46 are formed of a plate material along the X-axis direction, and are continuous with the inner surfaces of the hanging piece portions 42B and 43B and the lower surface of the fixed piece portion 41B.
The bundle member 20 may have the conduit 100 passed through the hollow portion 25 of the bundle member 20, the piping opening 471 and the piping notch 472 of the fixed body 40. In this way, the conduit 100 is passed through the bundle member 20, so that the conduit 100 continuous from the frames 2A and 2B to the roof 50 can be installed without being exposed to the outside.

The roof material 81 includes a roof material 81A shown in FIG. 11A, a roof material 81B shown in FIG. 11B, and a roof material 81C (end roof material) shown in FIG. 11C. is there.
As shown in FIG. 11A, the roof material 81A has a hollow frame-shaped panel material 82 opened at both ends, and a lower overlapping portion 836 and an upper overlapping portion 846 that are continuous with the panel material 82. Yes. The panel member 82 includes an upper surface portion 821, a lower surface portion 822, a pair of side surface portions 833 and 843 continuous to the upper surface portion 821 and the lower surface portion 822, and an upper surface portion 821 and a lower surface portion between the pair of side surface portions 833 and 843. 822 and two vertical piece portions 823 that are continuous to each other. A central portion of the upper surface portion 821 in the width direction of the panel member 82 is configured as a mounting portion 821A that protrudes upward from a lower overlapping piece portion 835 and an upper overlapping piece portion 845, which will be described later, and this mounting portion 821A is the upper beam. 70.
The mounting portion 821A, the lower surface portion 822, and the two vertical piece portions 823 form a box section 88 having a quadrangular cross section, and screw holes 85 are formed in the corners of the box section 88 in the longitudinal direction of the panel member 82. It is formed to extend. Further, screw holes 85 are formed to extend in the longitudinal direction of the panel member 82 at corners where the upper surface portion 821 and the side surface portion 833 intersect and corner portions where the upper surface portion 821 and the side surface portion 843 intersect.
Inside the panel member 82, three hollow portions 829, 839, 849 partitioned by two vertical piece portions 823 are formed.
The lower overlapping portion 836 includes a rising piece portion 834 raised upward from a corner portion where the upper surface portion 821 and the side surface portion 833 intersect, and an inner side of the panel member 82 from the rising piece portion 834 to the side surface portion 833. It has a lower overlapping piece portion 835 extending toward the side surface portion 843 in the width direction, and is formed in a substantially L-shaped cross section. The panel member 82 is formed with a flange portion 837 having a substantially L-shaped cross section that protrudes outward from the side surface portion 833.
The upper overlapping portion 846 includes a rising piece portion 844 that is brought out from the corner portion where the upper surface portion 821 and the side surface portion 843 intersect to the outside of the side surface portion 843 and raised upward, and the rising piece portion 844 to the side surface portion 843. On the other hand, it has an upper overlapping piece portion 845 extending toward the outer side (side away from the side surface portion 833 in the width direction of the panel member 82) and is formed in a substantially L-shaped cross section.
On the upper surface portion 821 of the roof material 81A, flange portions 831 and 841 along the X-axis direction are formed between the box portion 88 and the lower overlapping portion 836 and the upper overlapping portion 846, respectively.

As shown in FIG. 11B, the roof material 81 </ b> B has a hollow frame-shaped panel material 86, a lower overlapping portion 868, and an upper overlapping portion 869. The panel material 86 includes an upper surface portion 861, a lower surface portion 862, a pair of side surface portions 863 and 864 continuous with the upper surface portion 861 and the lower surface portion 862, and an upper surface portion 861 and a lower surface portion between the pair of side surface portions 863 and 864. 862 and two vertical piece portions 865 continuous to 862. The upper surface portion 861, the lower surface portion 862, and the two vertical piece portions 865 form a box portion 89 having a quadrangular cross section. A screw hole 85 extends in the longitudinal direction of the panel material 86 at each corner portion of the box portion 89. Is formed. Two rising piece portions 866 are formed on the upper surface portion 861, and the upper surface 861A of the upper surface portion 861 has a rising surface 866A (the upper surface of the rising piece portion 866) of the two rising piece portions 866. A ridge portion 867 having a concave cross section is formed. In addition, the above-described flange portion 837 that protrudes outward from the side surface portion 863 is formed in the panel material 86.
Further, the above-described insertion port 91 is configured to penetrate the lower surface portion 862, and the insertion port 92 is configured to penetrate the bottom portion of the flange portion 867.
Three hollow portions 871, 872, and 873 partitioned by two vertical piece portions 865 are formed inside the panel member 86, and the insertion openings 91 and 92 communicate with the central hollow portion 871. Yes.
The lower overlapping portion 868 is configured by a portion of the upper surface portion 861 that is closer to the side surface portion 863 than the flange portion 867, and is located on the inner side with respect to the side surface portion 863.
The upper overlapping portion 869 is configured by an upper overlapping piece portion that extends outward from the side surface portion 864.

  The roof material 81C is formed in substantially the same manner as the roof material 81A as shown in FIG. 11C, but has a lower overlapping portion 836A instead of the upper overlapping portion 846. The lower overlapping portion 836A includes a rising piece portion 834A and a lower overlapping piece portion 835A, and is configured in the same manner as the lower overlapping portion 836. However, the lower overlapping piece portion 835A is arranged in the width direction of the panel member 82. It extends toward the side surface portion 833 side. That is, the lower overlapping piece portions 835 and 835A extend from the rising piece portions 834 and 834A toward the center side in the width direction of the roof material 81C. Moreover, the collar part 837 is formed in both the side parts 833 and 843.

The front frame 61 includes an end plate material 611 extending in the X axis direction over the roof materials 81A and 81C located at both ends in the X axis direction among the plurality of roof materials 81, and the end plate material 611 includes the end plate material 611 in the X axis direction. An extended decorative material 615 is attached (see FIG. 13). The end plate material 611 and the decorative material 615 are formed of an aluminum extruded profile.
The end plate material 611 is formed in a substantially rectangular plate shape, and an extended piece portion 612 that extends outward in the X-axis direction is formed in the upper portion thereof, and a fitting that opens outward in the X-axis direction is formed in the lower portion thereof. A joint groove 613 is formed. Further, the end plate material 611 is formed with a plurality of holes 614 through which fixing screws 65 as fixing tools are respectively inserted. The positions of the holes 614 are arranged corresponding to the positions of the screw holes 85 of the plurality of roofing materials 81 (81A, 81B, 81C) shown in FIG.
The end plate material 611 is fixed in a state where a sheet-like dry sealing material 55 extending in the X-axis direction is sandwiched between end portions 811 (end portions on the front frame 61 side) in the longitudinal direction of the plurality of roof materials 81. It is fixed to each end portion 811 of the roofing material 81 with screws 65.
The dry sealing material 55 is formed in a rectangular sheet shape with sponge, rubber, or the like, and has substantially the same length as the end plate material 611. The dry sealing material 55 is inserted into each hole 614 of the end plate material 611 in a state where the screw shaft portion 65A of the fixing screw 65 is along the Y-axis direction and is screwed into each screw hole 85 of the plurality of roof materials 81. The openings at the end portions 811 of the hollow portions 829, 839, 849, 871, 872, 873 of the plurality of roof materials 81 are collectively closed, and the gap between the end portions 811 and the end plate materials 611 of the plurality of roof materials 81 is stopped. Watering.
As shown in FIG. 14, the decorative material 615 includes an upper surface portion 616A, a side surface portion 616B, and a lower surface portion 616C. The decorative body portion 616 has a substantially U-shaped cross section. It has a hollow frame-shaped makeup projecting portion 617 projecting outward. An abutting piece 618 that abuts against the end plate material 611 is formed on the edge of the upper surface portion 616A so as to hang downward. Enlarged fitting portions 619 that fit into the fitting groove portions 613 of the end plate material 611 are formed at the edge portion of the lower surface portion 616C. In addition, two hanging piece portions 616D are continuous with the lower surface portion 616C, and a bottom surface portion 616E is continuous with the lower edge of the two hanging piece portions 616D. In the makeup main body 616, screw holes 66 are formed along the X-axis direction in the top surface 616A, the side surface 616B, the hanging piece 616D and the bottom surface 616E on the fitting large portion 619 side. A plurality of screw holes 66 are formed along the X-axis direction on the inner surface of the decorative overhang portion 617.
An end 615A in the longitudinal direction of the decorative material 615 is obliquely cut so as to be able to abut on an end 645A in the longitudinal direction of the decorative material 645, which will be described later, and a corner seal member 68 shown in FIG. 14 is provided at the end 615A. It is fixed by a fixing screw 67 which is a fixing tool. The end 615A on the opposite side in the longitudinal direction of the decorative material 615 is also obliquely cut in the same manner as described above, and the corner seal member 68 is fixed by a fixing screw 67 (see FIG. 1).
The corner seal member 68 is configured as a resin cap member that covers the end portion 615A of the decorative material 615, and both sides of the seal plate portion 681 from the periphery of the seal plate portion 681 in the out-of-plane direction of the seal plate portion 681. And a peripheral extending portion 682 extending in the direction. The outer shape of the corner seal member 68 is a shape that roughly follows the outer shape of the decorative material 615.
In this decorative material 615, the contact piece 618 is placed on the extended piece 612 of the end plate material 611 and comes into contact with the outer surface of the end plate material 611, and the large fitting portion 619 is the fitting groove portion of the end plate material 611. By being fitted to 613, it is attached to the end plate material 611. The contact piece 618 may be screwed to the end plate material 611. The decorative material 615 attached to the end plate material 611 thus covers the end plate material 611 from the outside, and a space in which the conduit 100 or the like can be piped by the end plate material 611, the upper surface portion 616A, the side surface portion 616B, and the lower surface portion 616C. Is forming.

Since the roof 50 is inclined, the rear frame 62 located at a position lower than the front frame 61 has end portions 812 (end portions on the rear frame 62 side) in the longitudinal direction of the plurality of roof materials 81 as shown in FIG. A drainage end plate member 621 is attached to the drainage end plate member 621, and a decorative member 625 having a flange 626 formed along the X-axis direction is attached to the drainage end plate member 621. The drainage end plate material 621 and the decorative material 625 are formed of an aluminum extruded profile.
As shown in FIG. 12, the drain end plate member 621 is formed to extend in the X-axis direction across the roof materials 81A and 81C located on both ends in the X-axis direction among the plurality of roof materials 81, and has an upper edge. Among them, a plurality of drainage grooves 622 that open the flanges 831, 841, 867 are formed at positions corresponding to the flanges 831, 841, 867 of the roof materials 81A to 81C, and a plurality of drainage grooves 622 are formed. It is possible to drain to the collar 626 of the decorative material 625. Further, the lower edge of the end plate material 621 for drainage is disposed at a position higher than the lower surface portions 822 and 862 of each roof material 81, so that rainwater enters the roof material 81 having a hollow frame shape. In addition, water can be drained from below the draining end plate material 621 to the flange 626 of the decorative material 625.
As shown in FIG. 5, the decorative material 625 includes a makeup main body 627 in which the collar 626 is formed to have a substantially concave cross section, and a makeup overhang 628 that projects outward from the makeup main body 627 in the Y-axis direction. And it is formed in a frame shape. A plurality of screw holes 66 are formed in the decorative material 625 along the X-axis direction. When the fixing screws 67 (see FIG. 14) are screwed into these screw holes 66, the corner seal member 68 described above is applied to the decorative material 625. The material 625 is fixed to both ends 635A (see FIG. 1) in the longitudinal direction.

As shown in FIGS. 4 and 12, the side frame 63 includes a side plate 631 screwed to one end in the longitudinal direction of the upper beam 70, and a decorative material 635 is attached to the side plate 631. It has been. The side plate material 631 and the decorative material 635 are formed of an aluminum extruded profile. The side plate 631 is formed to extend in the Y-axis direction and has a screw hole, and the fixing plate 65 is screwed into the screw hole, whereby the end plate 611 and the drain end plate 621 are fixed to both ends of the side plate 631. Is done. The side plate member 631 is formed with the above-described upper overlapping portion 632.
The decorative material 635 is formed in a frame shape along the Y-axis direction, and the outer shape thereof is formed in the same shape as the outer shapes of the decorative materials 615 and 625. Both end portions 635A in the longitudinal direction of the decorative material 635 are respectively bonded to the corner seal members 68 fixed to the decorative materials 615 and 625, and thereby the end portion 635A is end portions of the decorative materials 615 and 625. A corner portion 69 of the roof frame 60 is configured by abutting 615A and 625A (see FIG. 1).

  As shown in FIGS. 1, 4, and 12, the side frame 64 includes a side plate material 641 formed in the same manner as the side plate material 631 of the side frame 63, and a decorative material formed in the same manner as the decorative material 635. 645 is attached to the side plate 641. The side frame 64 is disposed in the direction opposite to the side frame 63 in the X-axis direction. The side plate member 641 is formed with the above-described upper overlapping portion 642. The corner seal members 68 fixed to the decorative materials 615 and 625 are respectively bonded to both end portions 645A in the longitudinal direction of the decorative material 645, whereby the end portions 645A are end portions 615A of the decorative materials 615 and 625. , 625A to constitute a corner portion 69 of the roof frame 60 (see FIG. 1). Each corner portion 69 configured in this way is stopped by a dry corner seal member 68.

The roof 50 described above is constructed as follows. First, the upper beam 70 is fixed to the bundle 10 through the roof material 81B, and the side plates 631 and 641 of the side frames 63 and 64 are attached to both ends of the upper beam 70 to form a two-sided frame as shown in FIG. At this time, the rear frame 62 indicated by a two-dot chain line in FIG. 12 is not attached.
Next, a plurality of roofing materials 81 are installed in the two-sided frame. The procedure is as follows. A plurality of roofing materials 81 are arranged in the X-axis direction and placed on the beam 4, and the roofing material 81A located at the left end in FIG. 12 is moved right above in the Z-axis direction. The upper overlapping portion 642 and the lower overlapping piece portion 835 that are overlapped are overlapped on the lower side of the upper overlapping portion 642 of the side plate member 641 and fixed by a fixing screw 87 that is a fixing tool.
Next, the lower overlapping piece 835 of another roofing material 81A is arranged directly below the upper overlapping piece 845 of the fixed roofing material 81A, and the lower roofing material 81A is moved right above, so that the upper overlapping piece 845. The lower overlapping piece 835 is overlaid on the lower side, and the upper overlapping piece 845 and the lower overlapping piece 835 that are overlapped are fixed by a fixing screw 87.
Next, the roof material 81B in which the lower overlapping portion 868 is positioned directly below the upper overlapping piece portion 845 of the roof material 81A is moved right above the bundle 10 and is moved downward to the lower side of the upper overlapping piece portion 845. The overlapping portion 868 is overlapped, and the overlapped upper overlapping piece portion 845 and the lower overlapping portion 868 are fixed by a fixing screw 87.
Next, the lower overlap piece 835 of the roof material 81A is disposed directly below the upper overlap portion 869 of the roof material 81B, the roof material 81A is moved directly above, and the lower overlap piece portion is located below the upper overlap portion 869. 835 are overlapped, and the overlapped upper overlapping portion 869 and the lower overlapping piece 835 are fixed by a fixing screw 87.
Thus, the roof materials 81 or the roof materials 81A and 81B are connected along the X-axis direction.
Finally, the lower overlapping piece 835A of the roofing material 81C (end roofing material) is disposed immediately below the upper overlapping portion 632 of the side plate member 631, and the roofing material 81C is directly below the upper overlapping piece 845 of the roofing material 81A. The lower overlap piece 835 is arranged, the roof material 81C is moved right above, the lower overlap piece 835A of the roof material 81C is superimposed on the lower side of the upper overlap portion 632 of the side plate 631, and the roof material 81A The lower overlapping piece 835 of the roof material 81C is overlapped on the upper overlapping piece 845 of the roof, and the upper overlapping part 632 and the lower overlapping piece 835A that are overlapped are fixed by the fixing screw 87, and the upper overlapping piece 845 overlapped. And the lower overlapping piece 835 is fixed with a fixing screw 87.
In this way, the plurality of roofing materials 81 are arranged side by side in the X-axis direction. Note that a water-stopping material such as butyl rubber is sandwiched between the upper overlapping piece 845 and the upper overlapping parts 632, 642, 869 and the lower overlapping piece 835 and the lower overlapping part 868. The mating part is stopped.
After the plurality of roofing materials 81 are arranged side by side, the end plate material 611 is fixed to the end portions 811 of the plurality of roofing materials 81 with the fixing screws 65 with the dry sealing material 55 sandwiched therebetween, as shown in FIG. By tightening with the screw 65, water is stopped between the end portion 811 and the end plate material 611. Further, the drain end plate member 621 is fixed to the end portions 812 (see FIG. 5) of the plurality of roof members 81. As a result, the end plate material 611, the drain end plate material 621, and the side plate materials 631, 641 are framed around four sides. Subsequently, the decorative materials 635 and 645 are attached to the side plate materials 631 and 641, respectively. At the same time, the both end portions 635 A and 645 A of the decorative materials 635 and 645 are inserted into the peripheral edge extending portion 682 of the corner seal member 68 and bonded to the corner seal member 68. The adhesive is previously applied to the corner seal member 68. In this way, the roof frame 60 formed by framing the front frame 61, the rear frame 62, and the side frames 63 and 64 is configured. The roof 50 is constructed as described above.

In the carport 1 of the first embodiment, as shown in FIGS. 4, 5, 8 and 10, the resin-made resin is installed between the roof material 81B and the bundle 10 described above on the upper surface of the roof material 81B. A water stop structure for stopping water by the water stop member 110 is configured.
The water blocking member 110 includes a cylindrical main body 111 that surrounds the upper opening 92 </ b> A of the insertion opening 92, and a plurality of lower fixing screw holes 121 and a plurality of upper fixing screw holes 122 formed on the inner periphery of the cylindrical main body 111. ing.
The cylindrical main body 111 has a pair of vertical side pieces 112 and 113 and a pair of horizontal side pieces 114 and 115, and is formed in a square shape in plan view. It is formed in a rounded corner shape by the surface.
The plurality of lower fixed screw holes 121 and the plurality of upper fixed screw holes 122 are formed to extend in the axial direction of the cylindrical main body 111. Two lower fixed screw holes 121 are formed with an interval in the X-axis direction with respect to each of the vertical side pieces 112 and 113, and an interval in the Y-axis direction with respect to each of the horizontal side pieces 114 and 115. Four are formed with a gap between them. The above-described upper surface 121A of the lower fixed screw hole 121 is disposed at a position lower than the upper surface 111A of the cylindrical main body 111 by the vertical dimension H (see FIG. 10B) in the Z-axis direction.
Two upper fixed screw holes 122 are formed with an interval in the X-axis direction with respect to each of the vertical side pieces 112 and 113, and between the two upper fixed screw holes 122, the vertical side pieces 112, Each of the two lower fixing screw holes 121 formed in 113 is arranged. One upper fixing screw hole 122 is formed for each of the lateral side pieces 114 and 115, and is arranged at the center position of the lateral side pieces 114 and 115 in the Y-axis direction. Two lower fixing screw holes 121 formed in the lateral side pieces 114 and 115 are arranged on each side of the upper fixing screw holes 122 formed in the lateral side pieces 114 and 115 in the Y-axis direction.
The water blocking member 110 is fixed to the upper surface portion 861 of the roof material 81B by fixing screws 123 screwed into the plurality of lower fixing screw holes 121, and the upper beam is fixed by fixing screws 123 screwed into the plurality of upper fixing screw holes 122. 70 is fixed to a lower surface portion 71 (see FIG. 5). Here, between the lower surface 111B of the cylindrical main body 111 and the upper surface 861A of the upper surface portion 861 of the roof material 81B, a dry sealing material 125 having a rectangular shape in plan view along the lower surface 111B of the cylindrical main body 111 is interposed. In addition, the fixing member 123 is screwed to the lower surface 111B of the cylindrical main body 111 and the upper surface 861A of the roofing material 81B to stop water between the waterstop member 110 and the roofing material 81B. Further, a dry sealing material 125 is also interposed between the upper surface 111A of the cylindrical main body 111 and the lower surface 71A of the upper beam 70 (see FIG. 5), and the upper surface 111A of the cylindrical main body 111 is screwed by fixing screws 123. The space between the water stop member 110 and the upper beam 70 is stopped by being pressure-bonded to the lower surface 71 </ b> A of the upper beam 70.

[Effect of the first embodiment]
(1-1) For the purpose of producing a floating feeling of the roof 50, the carport 1 is composed of a pair of columns 3 and beams 4 fixed to the pair of columns 3 and arranged in parallel. The frame 10 includes two frames 2A and 2B, a bundle 10 erected on the beam 4, and a roof 50 supported by the bundle 10, and the bundle 10 has a peripheral portion (periphery of the roof 50 in the longitudinal direction of the beam 4). It is characterized in that it is arranged inside the roof frame 60) constituting the part. Since it has the said structure, according to the vertical dimension of the bundle 10, the roof 50 can be arrange | positioned away from the beam 4 upwards. Further, since the bundle 10 is arranged on the inner side of the side frames 63 and 64 of the roof frame 60 that constitutes the peripheral portion of the roof 50 in the X-axis direction, even if the roof 50 is looked up from the column 3 side, the bundle 10 However, it is possible to construct an inconspicuous appearance that is hidden to some extent by the beam 4. In this way, by arranging the roof 50 away from the beam 4 and making the bundle 10 inconspicuous, a floating feeling that the roof 50 is floating above the beam 4 is produced. be able to.
(1-2) The roof 50 includes a roof frame 60 that forms a peripheral portion of the roof 50, upper beams 70 that are attached to the roof frame 60 at both ends, and a roof material 81 that is attached to the roof frame 60. The upper beam 70 is attached to the upper end portion 11 of the bundle 10, and the longitudinal direction of the upper beam 70 is parallel to the longitudinal direction of the beam 4. For this reason, compared with the case where the longitudinal direction of the upper beam 70 and the beam 4 is orthogonal, for example, the attachment position with respect to the upper beam 70 and the beam 4 of the bundle 10 can be freely set at a position along the longitudinal direction of the upper beam 70 and the beam 4. Can be set to
(1-3) The roof 50 includes a roof frame 60 that forms a peripheral portion of the roof 50, upper beams 70 that are attached to the roof frame 60 at both ends, and a roof material 81 that is attached to the roof frame 60. The roof material 81 is arranged below the upper beam 70. For this reason, by arranging the roof material 81 below the upper beam 70, it is possible to configure a simple appearance in which the upper beam 70 cannot be seen even when the roof 50 is looked up from below.
(1-4) The roof 50 is configured by a roof material 81 having a hollow portion 871, and through-holes 91 and 92 communicating with the hollow portion 871 are formed in the roof material 81. , 92 is inserted through the upper end 11 of the bundle 10. For this reason, since the upper end part 11 of the bundle 10 can be arrange | positioned in the hollow part 871 of the roof material 81, even if the upper end part 11 of the bundle 10 is attached to the roof 50, it can be arranged so that an attachment part is not exposed outside. Thus, the upper end part 11 of the bundle 10 can be hidden by the roof material 81, and when the roof 50 is looked up from the lower side, the simple external appearance which the attachment part of the roof 50 and the bundle 10 is not exposed can be comprised.
(1-5) The vertical dimension L1 of the pair of support columns 3 in one of the two frames 2A and 2B is different from the vertical dimension L2 of the pair of support columns 3 in the other of the two frames 2A and 2B. For this reason, even when the vertical dimension of the bundle 10A standing on the frame 2A and the bundle 10B standing on the frame 2B are the same, the vertical dimension L1 between the column 3 of the frame 2A and the column 3 of the frame 2B By making L2 different, it is possible to set the roof gradient in the direction in which the frames 2A and 2B are juxtaposed, and it is possible to adopt the common one for the bundles 10A and 10B standing on the frames 2A and 2B, respectively.
(1-6) The roof 50 includes a roof frame 60 that constitutes a peripheral portion of the roof 50, an upper beam 70 having both ends attached to the roof frame 60, and the both ends of the roof 50 that are arranged in parallel. A plurality of metal roof members 81 attached to the roof frame 60, and the longitudinal direction of the upper beam 70 and the beam 4 is parallel, and the longitudinal direction of the plurality of roof members 81 is the longitudinal direction of the upper beam 70. It is orthogonal to the direction. For this reason, when an external force along the longitudinal direction of the upper beam 70 is applied to the roof 50, this external force can be received by the upper beam 70, and an external force along the longitudinal direction of the plurality of roof materials 81. Is applied to the roof 50, this external force can be received by the plurality of roofing materials 81. As described above, in the present invention, in addition to the upper beam 70, the plurality of roof materials 81 can function as the structural material of the roof 50, and the rigidity of the roof 50 can be increased.
When various carports 1 having different frontage dimensions are configured, the roof 50 corresponding to the frontage dimensions of the various carports 1 can be set by appropriately setting the number of roofing materials 81 arranged in the X-axis direction. Can be configured.
(1-7) An upper light 510 as an upper illuminator that illuminates the lower surfaces 822A and 862A of the roof 50 is installed in a region of the beam 4 that faces the lower surfaces 822A and 862A of the roof 50 in the Z-axis direction. ing. Therefore, by illuminating the lower surfaces 822A and 862A of the roof 50 with the upper light 510 installed on the beam 4, the floating feeling of the roof 50 spaced upward from the beam 4 can be illuminated. Further, compared to the case where the upper light 510 is mounted at a position protruding from the beam 4 by an attachment arm or the like, for example, the upper light 510 is accommodated in a region of the beam 4 facing the lower surfaces 822A and 862A of the roof 50. 510 can be made inconspicuous in appearance.

(2-1) When a horizontal force is applied to the roof 50 or the frames 2A and 2B by wind, earthquake, or the like, a horizontal shearing force perpendicular to the axial direction may be applied to the bundle 10 in some cases. It is desirable to improve the horizontal shear strength of the bundle 10. For the purpose of improving the shear strength in the horizontal direction, the bundle 10 is arranged in a rectangular tube-shaped bundle member 20 and in the hollow portion 25 of the bundle member 20 while being formed in a rectangular tube shape. The bundle member 20 intersects the pair of first bundle piece portions 21 and 22 and the pair of first bundle piece portions 21 and 22, and the corner portions 261 to 264 (thick portions). And the corner portions 261 to 264 have a dimension T1 (thickness in the Y-axis direction where the pair of first bundle pieces 21 and 22 face each other. The dimension T2 (thickness dimension) in the X-axis direction in which the pair of second bundle pieces 23 and 24 face each other is larger than the thickness dimension T4 of the first bundle pieces 21 and 22. It is made larger than thickness dimension T3 of the 2nd bundle piece parts 23 and 24, and it is that of each corner | angular part 261-264. Reniwa, wherein the fixing hole 27 along the axial direction of the Tabazai 20 is drilled. In order to have the above configuration, a fixing tool such as the fixing bolt 7 is fastened to the fixing holes 27 of the corners 261 to 264 via the lower structures such as the beams 4 of the frames 2A and 2B at the lower end 29 of the bundle member 20. When the fixing body 40 described above is provided, the bundle 10 can be fixed to the lower structure by attaching the attachment pieces 44A, 44B, 45A, 45B of the fixing body 40 to the lower structure with the fixing screws 8. The upper structure is joined to the bundle 10 by fastening a fixing tool such as a fixing bolt 7 to the fixing holes 27 of the corners 261 to 264 via the upper structure such as the upper beam 70 of the roof 50 at the upper end 28 of the roof 20. Can be fixed. Further, the vertical load of the upper structure can be supported by the reinforcing member 30 disposed in the hollow portion 25 of the bundle member 20. Further, as described above, the fixing holes 27 are formed in the respective corner portions 261 to 264 having dimensions T1 and T2 larger than the thickness dimensions T3 and T4 of the first bundle pieces 21 and 22 and the second bundle pieces 23 and 24. Since, for example, a screw hole connected to the hollow portion 25 of the bundle member 20 is formed in the first corner portion 261 to the fourth corner portion 264 of the bundle member 20, the bundle member 20 is horizontal. The shear strength in the direction can be improved.
The bundle 10 can be used not only as the bundle 10 that supports the roof 50 of the roof structure like the carport 1 described above but also as the bundle 10 that supports the floor, the deck, the terrace roof, and the like. Also in the case of being used in the horizontal shearing strength of the bundle 10 can be improved. Examples of the structure including the bundle 10 include a floor structure such as a carport 1 and a floor, a balcony, a terrace, and an approach.
(2-2) The second bundle piece portions 23 and 24 of the bundle 10 are formed with contact convex portions 231 and 241 protruding toward the reinforcing material 30. For this reason, when an external force in the out-of-plane direction (X-axis direction) of the second bundle pieces 23 and 24 of the bundle 20 is applied to the bundle 10 due to wind, earthquake, or the like, the above-described contact projections 231, When 241 contacts the reinforcing member 30, the shear strength of the bundle in the X-axis direction can be improved.
(2-3) The bundle 10 includes a fixed body 40 fixed to the lower end 29 of the bundle material 20, and the fixed body 40 is fixed to the bundle material 20 by a fixing tool such as a fixing bolt 7 fastened to the fixing hole 27. A fixed piece portion 41A fixed to the lower end 29 of the A, a pair of hanging piece portions 42A and 43A hanging from the fixed piece portion 41A, and a pair of mounting piece portions 44A continuous to the lower edge 47 of the hanging piece portions 42A and 43A, 45A. For this reason, since the fixing piece part 41A can be fixed to the lower end 29 of the bundle member 20 by fastening the fixing bolt 7 from the lower end 29 of the bundle member 20 to the fixing hole 27, an insertion hole or the like for inserting the fixing bolt 7 is provided. It is possible to save the trouble of previously processing the lower structure such as the beam 4 of the frames 2A and 2B, and it is possible to eliminate the lowering of the strength of the lower structure due to the formation of the insertion hole. In this case, the bundle 10 is fixed to the lower structure by bringing the pair of attachment pieces 44A and 45A of the fixed body 40 into surface contact with the lower structure, and the attachment screw 9 is connected to the lower structure from the pair of attachment pieces 44A and 45A. This is done by screwing into things. Further, the fixing piece portion 41A is arranged at a position higher than the mounting piece portions 44A and 45A by the hanging piece portions 42A and 43A, so that the head of the fixing bolt 7 fastened to the fixing hole 27 (part of the fixing tool). ) Protrudes from the lower surface of the fixed piece portion 41A, the protruding portion can be stored between the fixed piece portion 41A and the lower structure.
(2-4) The fixed body 40 of the bundle 10 includes fixing pieces 41A and 41B, a pair of hanging pieces 42A, 42B, 43A, and 43B and a pair of attachment pieces 44A, 44B, 45A, and 45B. One fixing member 40A and a second fixing member 40B are provided, and the pair of hanging pieces 42A, 43A and the pair of attachment pieces 44A, 45A in the first fixing member 40A are a pair of hanging pieces in the second fixing member 40B. The fixing pieces 41 </ b> A of the first fixing member 40 </ b> A are superposed on the parts 42 </ b> B and 43 </ b> B and the pair of attachment pieces 44 </ b> B and 45 </ b> B. The fixing piece 41B of the second fixing member 40B is fixed to the fixing piece 41A of the first fixing member 40A at an interval in the vertical direction (Z-axis direction). For this reason, the strength of the fixed body 40 is increased by configuring the fixed body 40 by superimposing the first fixed member 40A and the second fixed member 40B, for example, compared to the case where the fixed body 40 is configured by one fixed member. Can be improved. Further, the head of the fixing bolt 7 (a part of the fixing tool) can be disposed between the fixing pieces 41A and 41B of the first fixing member 40A and the second fixing member 40B. For example, the fixing bolt 7 is loosened and falls downward. Even if it comes, since the fixing bolt 7 contacts the fixing piece portion 41B of the second fixing member 40B, the fixing bolt 7 can be prevented from falling off.
(2-5) Piping openings 471 are formed in the fixed piece 41A (41B), and a pair of hanging pieces 42A, 43A (42B, 43B) and a pair of mounting pieces 44A, 45A (44B, 45B), and in the first embodiment, both hanging pieces 42A, 43A (42B, 43B) and both mounting pieces 44A, 45A (44B, 45B) A notch 472 is formed. For this reason, the conduit 100 or the like can be passed through the hollow portion 25 of the bundle 20 and the piping notch 472 can be passed through the piping opening 471, and the conduit 100 can be passed through the lower structure such as the beam 4. Therefore, it is possible to eliminate the need to process the opening and notch for the piping, and it is possible to eliminate a decrease in strength of the substructure due to this processing.
(2-6) On the fixed body 40 of the bundle 10, the reinforcing ribs 46 along the opposing direction (X-axis direction) of the pair of hanging pieces 42A, 43A (42B, 43B) are provided with a pair of hanging pieces 42B, 43B. It is formed continuously. For this reason, the strength of the fixed body 40 in the X-axis direction can be improved by the reinforcing rib 46. In addition, when the fixing body 40 does not include the second fixing member 40B and is configured by the first fixing member 40A, the reinforcing rib 46 is formed continuously with the pair of hanging piece portions 42A and 43A.
(2-7) Since the bundle member 20 has the second bundle pieces 23 and 24 having a width dimension W1 larger than the width dimension W2 of the first bundle pieces 21 and 22, the shear strength in the Y-axis direction is larger. Also, the shear strength in the X-axis direction is increased. As described above, the bundle member 20 has the X-axis direction as the strong axis direction. However, when the bundle member 20 receives a large external force in the X-axis direction, the bundle member 20 may be slightly distorted. In this case, the bundle member 20 can be reinforced by the first corner portion 261 to the fourth corner portion 264 coming into contact with the reinforcement member 30.
(2-8) When the upper beam 70 is fixed to the bundle 10 erected on the beam 4, the beam 4 is reinforced by the upper beam 70, and the beam 4 bends downward due to its own weight. This can be suppressed. For this reason, the shape in which the beam 4 extends straight in the X-axis direction can be maintained, and, for example, an impression that is slim in appearance can be given compared to a beam that is bent downward by its own weight. In addition, the upper light 510 installed on the beam 4 can be kept in a predetermined irradiation direction.

(3-1) Although it is desirable to perform a water-stop treatment on the joint portion between the bundle 10 and the roof 50, for example, it is troublesome for the water-stop operation for directly applying a wet sealant or the like to the joint portion between the roof 50 and the bundle 10. Cost. For the purpose of simplifying the water stopping operation between the roof 50 and the bundle 10, the gap between the roof material 81 having the insertion openings 91 and 92 and the bundle 10 inserted through the insertion openings 91 and 92 is stopped. The water stop structure for water is as follows. A water blocking member 110 is installed on the upper surface 861A of the roofing material 81. The water blocking member 110 is formed on the cylindrical main body 111 surrounding the upper opening 92A of the insertion port 92 and the inner periphery of the cylindrical main body 111. The water-stopping member 110 is fixed to the roof material 81 by fixing screws 123 screwed into the plurality of lower fixing screw holes 121. Since it has the above-described configuration, the insertion openings 91 and 92 of the roof material 81 through which the bundle 10 is inserted are surrounded by the cylindrical main body 111 of the water stop member 110, and the water stop member 110 is screwed to the roof material 81 to A weir can be formed around the insertion openings 91 and 92 of the material 81, and thus the water between the roof material 81 and the bundle 10 can be stopped. As described above, since the water stop structure can be configured simply by installing the water stop member 110 from above with respect to the roof material 81, for example, the labor of directly applying the wet sealing material to the joint portion between the roof material 81 and the bundle 10 can be saved. The water stop operation can be simplified. Moreover, since the water stop member 110 can be fixed to the roof material 81 in advance in a factory or the like, when the water stop member 110 and the roof material 81 are pressure-bonded, or where the water stop member 110 and the roof material 81 are joined. In any case where a wet sealant, a dry seal, or the like is used, the water stop work at the construction site such as the roofing material 81 can be simplified.
(3-2) A dry seal material 125 may be interposed between the upper surface 861A of the roof material 81 and the lower surface 111B of the water blocking member 110. According to such a configuration, by screwing the fixing screw 123 into the lower fixing screw hole 121 of the water stopping member 110, the dry sealing material 125 can be crimped to the lower surface 111B of the water stopping member 110 and the upper surface 861A of the roof material 81. Thus, the water stoppage between the upper surface 861A of the roofing material 81 and the lower surface 111B of the waterstop member 110 can be improved.
(3-3) On the upper surface 861A of the roof material 81, a saddle portion 867 having a concave cross section having two rising surfaces 866A is formed, and the insertion opening 92 is opened at the saddle portion 867. An upper beam 70 is fixed to the upper end, and the water stop member 110 has a plurality of upper fixing screw holes 122 formed on the inner periphery of the cylindrical main body 111. It is fixed to the upper beam 70 by a fixing screw 123 screwed into the fixing screw hole 122. For this reason, by fixing the water stop member 110 to the upper beam 70 with a screw, the water between the water stop member 110 and the upper beam 70 can be stopped. For example, the water level flowing through the flange 867 of the roof material 81 is increased. In addition, it is possible to prevent water from entering between the water stop member 110 and the upper beam 70 and flowing down from the insertion port 92.
(3-4) The upper surfaces 121A of the plurality of lower fixed screw holes 121 are disposed at a position lower than the upper surface 111A of the cylindrical main body 111. For this reason, even if the fixing screw 123 is screwed from above the lower fixing screw hole 121 and the water blocking member 110 is fixed to the roof material 81, the fixing screw 123 can be stored at a position lower than the upper surface 111A of the cylindrical main body 111. . As described above, the fixing screw 123 screwed into the lower fixing screw hole 121 does not protrude upward from the water stopping member 110. Therefore, the fixing screw 123 is screwed into the upper fixing screw hole 122 to fix the water stopping member 110 to the upper beam 70. However, it does not interfere with the fixing of the upper beam 70.

(4-1) In the case where at least two side frames 63 and 64 (frame material) are framed, and a plurality of roofing materials 81 are arranged in parallel in the two-side frame, and there is almost no play space in the two-side frame. If the purpose is to easily construct a plurality of roofing materials 81 even if not, the plurality of roofing materials 81 are a hollow frame-shaped panel material 82 having a pair of side surface portions 833 and 843 (863, 864). 86), an upper overlapping portion 846 (869) extending outward from one side surface portion 843 (864) of the pair of side surface portions 833, 843 (863, 864), and a pair of side surface portions 833, 843 One of the plurality of roofing materials 81 having a lower overlapping portion 836 (868) located inside the other side surface portion 833 (863) of (863, 864). Overlapping portion 846 (869) of material 81 On the lower side, characterized in that the lower overlapping portion 836 of the other roofing materials 81 adjacent to each other among the plurality of roofing material 81 (868) are superposed. Since it has the said structure, the lower side overlap part 836 (868) of the other roof material 81 is arrange | positioned under the upper side overlap part 846 (869) of one roof material 81, and either of these roof materials 81 is Z-axis. The lower overlapping portion 836 (868) can be easily superimposed on the lower side of the upper overlapping portion 846 (869) simply by moving in the direction, and the upper overlapping portion 846 (869) and the lower overlapping portion 836 ( 868) is fixed by a fixing screw 87, and a plurality of roofing materials 81 can be arranged side by side.
Further, for example, even if there is a ridge extending from the side surface portions 833, 843 (863, 864) of the roof material 81, the upper overlapping portion 846 (869) located outside the side surface portion 843 (864) of the roof material 81. ) Is superimposed on the lower overlapping portion 836 (868) located inside the side surface portion 833 (863) of the roofing material 81, for example, one of the upper overlapping portion and the lower overlapping portion and the flange portion. The upper overlap portion 846 (869) and the lower overlap portion 836 (868) are simply overlapped by simply moving the roofing material 81 in the vertical direction as described above. Can do.
Furthermore, even if there is no play in the dimension between the two side frames 63 and 64 of the roof frame 60 in the direction in which the plurality of roof materials 81 are arranged, the plurality of roof materials 81 can be easily arranged.
(4-2) In the roof material 81 </ b> A, the upper overlapping portion 846 extends upward from the panel material 82, and extends from the rising piece 844 toward the outside of the panel material 82. The lower overlapping portion 836 includes a rising piece portion 834 raised upward from the panel member 82, and the rising piece portion 834 toward the inside of the panel member 82. And an extended lower overlapping piece 835. For this reason, since the lower overlapping portion 836 and the upper overlapping portion 846 are raised from the panel material 82 by the rising pieces 834 and 844, a flange portion can be formed between the rising pieces 834 and 844. For this reason, it is not necessary to install the eaves member on the roofing material 81A, the number of parts can be reduced, construction of the eaves can be simplified, and a simple appearance in which the eaves portion is not conspicuous in the roofing material 81A can be configured.
Further, in the roofing material 81C, since the lower overlapping portions 836 and 836A are raised from the panel material 82 by the rising pieces 834 and 834A, a collar portion can be formed between the rising pieces 834 and 834A. The same effect as described above can be exhibited.
(4-3) The upper beam 70 is provided along the direction in which the plurality of roofing materials 81 are arranged, and the panel member 82 projects upward from the upper overlapping portion 846 and the lower overlapping portion 836 (836A). An attachment portion 821A is formed, and the attachment portion 821A is attached to the upper beam 70. Therefore, even if the lower overlapping portion 836 (836A) and the upper overlapping portion 846 are raised upward by the rising piece portions 834 (834A) and 844, the mounting portion 821A positioned above the upper overlapping portions 834 (834A) and 844 70 can be attached.
(4-4) The panel member 82 includes an upper surface portion 821 and a lower surface portion 822 that are continuous to the pair of side surface portions 833 and 843, and two upper surfaces 821 and 822 that are continuous to the upper surface portion 821 and the lower surface portion 822 between the pair of side surface portions 833 and 843. And a hollow portion 829 is formed by the upper surface portion 821, the lower surface portion 822, and the two vertical piece portions 823, and between the two vertical piece portions 823 of the upper surface portion 821. The portion to be positioned is configured as a mounting portion 821A. For this reason, the strength of the panel member 82 can be increased by configuring the box portion 88 by the mounting portion 821A, the lower surface portion 822, and the two vertical piece portions 823, and the mounting portion 821A is formed at such a high strength portion. Can be attached to the upper beam 70.
(4-5) A roof frame 60 having at least side frames 63 and 64 as two frame members facing each other in the direction in which the plurality of roof materials 81 are arranged, and a roof in the direction in which the plurality of roof materials 81 are arranged in parallel. A roof material 81C (end roof material) disposed between the frame 60 and the plurality of roof materials 81A and 81B, and the roof material 81C has a hollow frame shape having a pair of side surface parts 833 and 843. Panel member 82 (end panel member) and two lower overlapping portions 836, 836A extending inward from each of the pair of side surface portions 833, 843. Of the side frames 63 and 64, the side frame 63 adjacent to the roof material 81 </ b> C is formed with an upper overlapping portion 632 extending from the side frame 63 to the roof material 81 </ b> C side. The upper overlap of the roof material 81A adjacent to the material 81C A lower overlapping portion 836 of the roof material 81C is overlapped below the portion 846, and a lower overlapping portion 836A of the roof material 81C is overlapped below the upper overlapping portion 632 of the side frame 63. Yes. For this reason, since the roof material 81C has the two lower overlapping portions 836 and 836A located on the inner side of the both side surface portions 833 and 843 in the width direction, the roof material 81C is used as the roof material 81A and the side frame 63. On the other hand, by simply moving the roof material 81C in the vertical direction, the two lower overlapping portions 836 and 836A of the roof material 81C are connected to the upper overlapping portion 846 of the roof material 81A adjacent to the roof material 81C and the upper overlapping portion 632 of the side frame 63. The roof material 81C can be easily overlapped with each other, and the overlapped lower overlapping portions 836, 836A and upper overlapping portions 846, 632 are fixed to each other by a fixing screw 87, so that the roof material 81C is attached to the roof frame 60 and the roof material 81A. It can be arranged in between. Further, since it is not necessary to move the roof material 81C in the direction in which the plurality of roof materials 81 are arranged, there is play in the dimension between the two side frames 63 and 64 of the roof frame 60 in the direction in which the plurality of roof materials 81 are arranged. Even if it is not, it can be installed only by moving the roofing material 81C in the vertical direction.
(4-6) Moreover, since the lower overlapping portion 836 (868) of the plurality of roofing materials 81 is located on the inner side of the side surface portion 833 (863) as described above, for example, the side surface portion 833 (863). Compared with the lower overlapping portion extending outward from the roof, the vertical load applied from the upper overlapping portion 846 (869) of the adjacent roof material 81 can be supported at a position where the strength of the roof material 81 is high, and the adjacent roof The interval between the materials 81 can be reduced.

(5-1) When the end 811 of the plurality of hollow frame-shaped roof materials 81 is intended to stop water, the roof 50 configured by arranging the plurality of hollow frame-shaped roof materials 81 side by side, Openings 811A are respectively formed at end portions 811 in the longitudinal direction of the plurality of roof materials 81, and end plate members 611 that cover the openings 811A are disposed at the end portions 811 in the longitudinal direction of the plurality of roof materials 81. In addition, a sheet-shaped dry sealing material 55 extending in the direction in which the plurality of roof materials 81 are arranged in parallel (X-axis direction) is disposed between the end portions 811 and the end plate materials 611 in the longitudinal direction of the plurality of roof materials 81. In the dry sealing material 55, a fixing screw 65 having a screw shaft portion 65A along the longitudinal direction (Y-axis direction) of the roof material 81 is screwed from the end plate material 611 into the end portion 811 in the longitudinal direction of the roof material 81. Be , Characterized in that closes the opening 811A of the plurality of roofing material 81. Since it has the above-described configuration, when fixing the end plate material 611 to the end portions 811 in the longitudinal direction of the plurality of roof materials 81, the sheet-like dry seal material 55 is replaced with the end portions 811 and end plate materials in the longitudinal direction of the roof material 81. The screw shaft portion 65A of the fixing screw 65 is screwed into the end portion 811 of the roof material 81 from the end plate material 611, so that the end portion 811 and the end plate material 611 in the longitudinal direction of the hollow frame-shaped roof material 81 The water can be stopped between. For this reason, for example, it is not necessary to form a stagnation groove or the like in the front frame and squeeze the end portion 811 of the roofing material 81 into the stagnation groove, and the construction is easy.
Further, since the screw shaft portion 65A of the fixing screw 65 along the Y-axis direction is screwed from the end plate material 611 to the end portion 811 of the roof material 81, the dry sealing material 55 is pressed against the end portions 811 of the plurality of roof materials 81. Thus, the water stoppage can be improved.
Furthermore, since the end portion of the presser material that presses the roof material 81 from the top is not partially pressed against the dry seal material 55, for example, it is not necessary to stop the pressure contact portion with the wet seal material and Water work can be simplified.
(5-2) The plurality of roofing materials 81A to 81C include a pair of side surface portions 833 (863) and 843 (864) and a top surface portion 821 (861) continuous to the pair of side surface portions 833 (863) and 843 (864). ) And the lower surface portion 822 (862) and two vertical piece portions 823 (865) continuous to the upper surface portion 821 (861) and the lower surface portion 822 (862) between the pair of side surface portions 833 (863) and 843 (864). ), And the box portion 88 (89) is configured by the upper surface portion 821 (861), the lower surface portion 822 (862), and the two vertical piece portions 823 (865). Screw holes 85 along the longitudinal direction of the roofing material 81 are formed at the respective corners, and screw shaft portions 65A of fixed screws 65 are screwed into the screw holes 85. Therefore, the box portion 88 (89) is formed by connecting the upper surface portion 821 (861) and the lower surface portion 822 (862) with the two vertical piece portions 823 (865) between the pair of side surface portions 833 (863) and 843 (864). ), The strength of the hollow frame-like roofing material 81 can be increased, and the screw holes 85 are formed at the respective corners of the box portion 88 (89) whose strength is increased in this way. Therefore, the end plate material 611 can be firmly fixed by screwing the fixing screw 65 into the portion of the end portion 811 in the longitudinal direction of the roof material 81 where the strength is increased. The space between the plate members 611 can be stopped more densely. For this reason, the hollow part 829 (871) formed by the box part 88 (89) can be suitably used as a space for arranging the conduit 100 and the like.
(5-3) The end plate material 611 extends over the end portions 811 of the plurality of roof materials 81 in the juxtaposition direction of the plurality of roof materials 81. For this reason, one end plate material 611 can be fixed to the end portions 811 of the plurality of roof materials 81, for example, when separate end plate materials 611 are fixed to the end portions 811 of the plurality of roof materials 81, respectively. The workability can be improved compared to the above. In addition, since the end portions 811 of the plurality of roof materials 81 are connected by one end plate material 611, the end plate material 611 can be configured as a frame material of the roof 50, and in addition to the end plate material 611, the end plate material 611 is connected to the end plate material 611. It is possible to eliminate the need to separately provide a frame material along the line.
(5-4) A decorative material 615 covering the end plate material 611 is attached to the end plate material 611. For this reason, compared with the case where the end plate material 611 and the decorative material 615 are integrally formed, for example, the end plate material 611 is exposed to the outside before the decorative material 615 is attached. The fixing screw 65 can be inserted, and the end plate material 611 can be easily fixed to the end portions 811 of the plurality of roof materials 81.
(5-5) A decorative material 615 (first decorative material) along the juxtaposed direction of the plurality of roof materials 81 and a decorative material 635 (645) (second decorative material) along the longitudinal direction of the plurality of roof materials 81 ), The end portion 615A of the decorative material 615 and the end portion 635A (645A) of the decorative material 635 (645) are abutted to form a corner portion 69, and the end portion 615A of the decorative material 615 is The corner seal member 68 is fixed by a fixing screw 67, and the corner seal member 68 is bonded to the end 635A (645A) of the decorative material 635 (645). For this reason, by fixing the corner seal member 68 to the end 615A of the decorative material 615 in advance in a factory or the like, the corner seal member 68 is bonded to the end 635A (645A) of the decorative material 635 (645) at the construction site. Only by doing, the corner part 69 which faced the decorative material 635 and the decorative material 635 (645) can be water-stopped, and the water-stop operation can be simplified.
(5-6) The upper surface 821B (861A) of the plurality of roofing materials 81 is formed with flange portions 831, 841, 867 along the longitudinal direction, and the plurality of roofing materials 81 are arranged in one of the longitudinal directions. The end portion 811 is inclined with respect to the horizontal direction so as to be positioned above the other end portion 812, and the end plate material 611 and the dry seal material 55 are fixed to the end portions 811 of the plurality of roof materials 81. A drainage end plate member 621 in which drainage grooves 622 are formed at positions corresponding to the flange portions 831, 841, 867 is fixed to the end portions 812 of the plurality of roofing materials 81. For this reason, since the opening of the edge part 811 of the some roofing material 81 is block | closed with the dry-type sealing material 55, the penetration | invasion of rain water into the some roofing material 81 can be suppressed. In addition, rainwater flowing through the flanges 831, 841, 867 of the plurality of roofing materials 81 can be drained through the drainage grooves 622 of the drainage end plate material 621, and rainwater can accumulate in the flanges 831, 841, 867. Can be suppressed.
(5-7) An operator inserts the screw shaft portion 65A of the fixing screw 65 in the Y-axis direction from the outer surface side of the end plate material 611 and screws the end plate material 611 into the screw hole 85 of the roof material 81. It can be fixed to the end portion 811 of the roof material 81. For this reason, in order to fix the end plate material 611, it is not necessary for an operator to climb on the roof material 81 and to perform a work such as screwing a fixing screw from above the roof material 81, and workability can be improved.

(6-1) When the lighting device (upper light 510) that illuminates the roof 50 and illuminates the roof 50 by illuminating the lower surfaces 822A and 862A of the roof 50 is designed to be inconspicuous in appearance, The port 1 includes at least two frames 2A and 2B that are arranged side by side at a distance from each other, and a roof 50 supported by the frames 2A and 2B. The frames 2A and 2B include the column 3 and the column 3. And the roof 50 is spaced apart from the beam 4 and is arranged in the Z-axis direction with respect to the lower surfaces 822A and 862A of the roof 50 of the beam 4. An upper light 510 is installed as an upper illuminating tool for illuminating the lower surfaces 822A and 862A of the roof 50 in the facing region. Since the upper light 510 illuminates the lower surfaces 822 </ b> A and 862 </ b> A of the roof 50, the floating effect of the roof 50 spaced upward from the beam 4 can be illuminated.
Further, since the upper light 510 is accommodated in a region of the beam 4 that faces the lower surfaces 822A and 862A of the roof 50, the upper light 510 is compared with the case where the upper light 510 is mounted at a position protruding from the beam 4 by a mounting arm or the like. 510 can be made inconspicuous in appearance.
(6-2) At least two bundles 10 are erected on the beam 4 at an interval in the X-axis direction, a roof 50 is fixed to the two bundles 10, and the upper light 510 is It is arranged between the two bundles 10. For this reason, the two bundles 10 can be more stably supported by arranging the two bundles 10 apart from each other in the X-axis direction. For example, the position of the end of the beam 4 relative to the two bundles 10 can be improved. In the upper light 510 disposed in the upper light 510, the light irradiated from the upper light 510 is blocked by the bundle, and it is difficult to illuminate the lower surfaces 822A and 862A of the roof 50 in a wide range between the two bundles 10. In the present embodiment, since the upper light 510 is disposed between the two bundles 10, the irradiation of the upper light 510 can illuminate the lower surfaces 822 </ b> A and 862 </ b> A of the roof 50 in a wide range between the two bundles 10. it can.
(6-3) The upper lights 510 are arranged at equal intervals (distance L3) from the two bundles 10 in the X-axis direction. For this reason, the irradiation light from the upper light 510 arranged between the two bundles 10 can be similarly spread on both sides in the X-axis direction.
(6-4) The irradiation range of the upper light 510 in the X-axis direction is set to the entire range between at least two bundles 10 (between 10A, 10A, 10B, 10B) among the lower surfaces 822A, 862A of the roof 50. Yes. For this reason, by illuminating the entire range between the two bundles 10 with the upper light 510, it is possible to eliminate the dark part from the portion located between the two bundles 10 among the lower surfaces 822A and 862A of the roof 50. 50 floating feelings can be produced.
(6-5) On the upper surface 405 of the beam 4 (the surface formed by the upper surface 424 of the side frame portions 422 and 423, the concave bottom surface 421A and the concave side surfaces 422A and 423A), the concave portion 4A opened at the top is formed. The upper light 510 is disposed in the recess 4A. For this reason, since the upper light 510 is disposed in the concave portion 4A, the upper light 510 is not conspicuous in appearance as compared with the case where the upper light 510 is mounted and mounted without forming the concave portion 4A on the upper surface 405 of the beam 4, for example. Can be configured.
(6-6) The recess 4A is formed to extend in the X-axis direction, and an upper cover material 5A that covers the opening of the recess 4A is attached to the beam 4, and the upper cover material 5A includes an upper light. An illumination opening 523 through which the irradiation light from 510 passes is formed. For this reason, even if the conduit 100 or the like is stored in the recess 4A of the beam 4, the conduit 100 or the like stored in the recess 4A is not exposed to the outside by covering the opening of the recess 4A with the upper cover material 5A. . On the other hand, even when the upper cover material 5A is attached to the beam 4, the irradiation light from the upper light 510 passes through the illumination opening 523 formed in the upper cover material 5A, so that the lower surfaces 822A and 862A of the roof 50 can be illuminated. .
(6-7) The roof 50 is inclined obliquely upward with respect to the virtual horizontal plane 52 as it goes from the rear side to the front side of the roof 50. Therefore, by irradiating the lower surfaces 822A and 862A of the roof 50 with the upper light 510, the reflected light reflected on the lower surfaces 822A and 862A of the roof 50 can be directed forward with respect to the roof 50. Thereby, the road ahead etc. with respect to the carport 1 can be illuminated by reflected light, and it is possible to eliminate the need to separately install a downlight for illuminating the road.

[Second Embodiment]
Hereinafter, a carport 1 according to a second embodiment of the present invention will be described with reference to the drawings.
The carport 1 according to the second embodiment is substantially the same as the first embodiment, but instead of a water stop structure that stops water between the roof material 81 and the bundle 10 by a water stop member 110, FIG. The water stop structure shown is configured, and the insertion port 91 has an opening size through which a water stop member 130 described later can be inserted.
In the water stop structure shown in FIG. 15, a resin water stop member 130 is installed between the roof material 81 and the bundle 10. As shown in FIG. 16, the water stop member 130 includes a first member 130A and a second member 130B each having two butting surfaces 131 and 132 that can be butted against each other.

  The first member 130 </ b> A and the second member 130 </ b> B are each formed by a halved body having a common shape, and a U-shaped concave portion 133 opened between the two butted surfaces 131 and 132, and a concave portion And a semi-annular flange 134 extending from the outer surface of 133. A ridge 131A is formed on the butting surface 131, and a recess 132A is formed on the butting surface 132. The first member 130A and the second member 130B were combined by abutting and abutting the butted surfaces 131 and 132 while fitting the protruding portion 131A of the first member 130A to the recessed portion 132A of the second member 130B. One water stop member 130 is configured.

In this water stop member 130, a rectangular tube-shaped water stop tube portion 135 and a guide tube portion 136 are constituted by the concave portions 133 of the first member 130A and the second member 130B, and the first member 130A and the second member 130B. A rectangular plate-shaped water-stop main body 137 is configured by the flange 134.
The water blocking cylinder portion 135 is a portion that protrudes upward from the water blocking main body portion 137 and is disposed so as to surround the outer peripheral surface 101 of the bundle 10. A plurality of water bottles 135 are formed along the circumferential direction. The guide tube portion 136 is a portion that protrudes downward from the water stop main body portion 137 and surrounds the outer peripheral surface 101 of the bundle 10. The inner peripheral surface 136 A of the guide tube portion 136 is the outer peripheral surface of the bundle 10. 101 abuts.
An attachment hole 139 for attaching to the upper surface portion 861 of the roofing material 81B is formed in the water stop main body portion 137.

The water stop member 130 described above is constructed as follows. First, the wet seal material 56 is attached to the inner and outer concave surface portions 138 and the upper surface of the flange portion 134 in the concave portion 133 of the first member 130A and the second member 130B.
Next, as shown in FIG. 17, the water stop member 130 surrounding the outer peripheral surface 101 of the bundle 10 is configured by combining the first member 130A and the second member 130B. At this time, a seal material reservoir space 57 in which the wet seal material 56 is stored is formed between the concave surface portion 138 on the inner peripheral surface 135A of the water blocking cylinder portion 135 and the outer peripheral surface 101 of the bundle 10.
Next, the water stop member 130 is moved from the lower side to the upper side along the axial direction of the bundle 10 while being guided using the guide tube portion 136, inserted through the insertion port 91 of the roof material 81 </ b> B, and the water stop tube portion 135. Is inserted into the insertion opening 92 and brought into contact with the upper surface portion 861 of the roofing material 81B and the bundle 10, and the upper surface 137A of the water stop main body portion 137 is brought into contact with the lower surface 861B of the upper surface portion 861. At this time, a seal material reservoir space 57 in which the wet seal material 56 is stored is formed between the concave surface portion 138 on the outer peripheral surface 135B of the water blocking cylinder portion 135 and the peripheral surface forming the insertion port 92 of the upper surface portion 861. The
Next, the water stop member 130 is attached to the upper surface portion 861 of the roof material 81B by screwing the fixing screw 140 into the attachment hole 139 of the water stop main body portion 137. The space between the upper surface portion 861 and the water blocking cylinder portion 135 and the space between the bundle 10 and the water blocking cylinder portion 135 are stopped by the wet seal material 56 stored in each seal material reservoir space 57. Further, between the upper surface portion 861 and the water stop main body portion 137, the wet sealing material 56 attached to the upper surface 137A of the water stop main body portion 137 adheres to the lower surface 861B of the upper surface portion 861 to stop water.
In addition, the insertion port 91 of the lower surface part 862 of the roofing material 81 </ b> B is closed with the plate-shaped decorative material 141 after the waterproofing member 130 is attached.

[Effects of Second Embodiment]
(1) Although it is desirable to perform a water-stop treatment on the joint between the bundle 10 and the roof 50, for example, a water-stop operation for directly applying a wet sealant or the like to the joint between the roof 50 and the bundle 10 requires labor. For the purpose of simplifying the water stopping operation between the roof 50 and the bundle 10, the gap between the roof material 81 having the insertion openings 91 and 92 and the bundle 10 inserted through the insertion openings 91 and 92 is stopped. The water stop structure for water is as follows. A water stop member 130 is installed between the roof material 81 and the bundle 10, and the water stop member 130 protrudes upward from the water stop main body portion 137 and the water stop main body portion 137 and the outer peripheral surface of the bundle 10. 101, and the water stop tube portion 135 is in contact with the bundle 10 and the roof material 81 at the insertion port 92, and the upper surface 137A of the water stop main body portion 137 is It is in contact with the roof material 81 from below. Since it has the said structure, by moving the water stop member 130 from the downward direction along the axial direction of the bundle 10, the water stop cylinder part 135 is inserted in the insertion port 92, and is made to contact | abut to the bundle 10 and the roof material 81. And the water stop structure which water-stops between the roof material 81 and the bundle | flux 10 by the water stop member 130 by making the upper surface 137A of the water stop main body part 137 contact | abut to the lower surface 861B of the upper surface part 861 of the roof material 81. Can be configured. In addition, since the water stop member 130 is moved from below to above along the axial direction of the bundle 10 to form a water stop structure, a wet sealant is directly applied to the joint between the roof 50 and the bundle 10. The work of water stop work can be saved and the water stop work can be simplified.
(2) The sealing material 56 (wet sealing material in the present embodiment) is attached to the inner peripheral surface 135A and the outer peripheral surface 135B of the water blocking cylinder portion 135 and the upper surface 137A of the water blocking main body portion 137. For this reason, the sealing material 56 attached to the inner peripheral surface 135 </ b> A of the water blocking cylinder portion 135 adheres to the outer peripheral surface 101 of the bundle 10 and stops water between the water stopping member 130 and the bundle 10. Further, the sealing material 56 attached to the outer peripheral surface 135B of the water-stop cylinder portion 135 and the upper surface 137A of the water-stop main body portion 137 is attached to the edge portion constituting the insertion port 92 of the roof material 81, and the water-stop member 130 and the roof Water is stopped between the materials 81.
Further, as described above, the water-stopping member 130 attached with the sealing material 56 is moved upward from below and disposed between the bundle 10 and the roofing material 81, so that the water-stopping treatment by the sealing material 56 is performed as described above. Therefore, the water stop operation can be simplified as compared with the case where the sealing material 56 is directly attached to the joint portion between the roof material 81 and the bundle 10 without using the water stop member 130, for example.
(3) The water stop member 130 has a guide tube portion 136 that protrudes downward from the water stop main body portion 137 and is disposed so as to surround the outer peripheral surface 101 of the bundle 10. The peripheral surface 136A is in contact with the outer peripheral surface 101 of the bundle 10, and the concave surface portion that forms the seal material reservoir space 57 between the inner peripheral surface 135A of the water blocking cylinder portion 135 and the outer peripheral surface 101 of the bundle 10. 138 is formed. Thus, since the inner peripheral surface 136A of the guide tube portion 136 is in contact with the outer peripheral surface 101 of the bundle 10, the water stop tube portion is moved when the water stop member 130 is moved upward from below along the axial direction of the bundle 10. The sealing material 56 in the sealing material reservoir space 57 formed between the concave surface portion 138 of the 135 and the outer peripheral surface 101 of the bundle 10 can be prevented from leaking downward from the water stop member 130.
(4) The water stop member 130 includes a first member 130A and a second member 130B each having two butting surfaces 131 and 132 that can be butted against each other. The first member 130A and the second member 130B are It has the concave part 133 opened between the two abutting surfaces 131 and 132, and the collar part 134 extended from the outer surface of the concave part 133, and two abutting surfaces of the first member 130A and the second member 130B In a state in which 131 and 132 are abutted with each other, the concave portion 133 of the first member 130A and the second member 130B constitutes the water blocking cylinder part 135 and the guide cylinder part 136, and the flange of the first member 130A and the second member 130B. The part 134 constitutes the water stop main body part 137. For this reason, the water stop member 130 surrounding the outer peripheral surface 101 of the bundle 10 can be configured by butting the two butted surfaces 131 and 132 of the first member 130A and the second member 130B, and the roofing material 81 It is not necessary to pass the water-stopping member 130 through the bundle 10 before inserting the bundle 10 through the insertion openings 91 and 92, and the water-stopping member 130 even after the bundle 10 is inserted through the insertion openings 91 and 92. Can be installed easily.
(5) Since the first member 130A and the second member 130B are configured by a halved body having a common shape, manufacturing costs can be reduced by manufacturing the first member 130A and the second member 130B with the same shape. Moreover, construction becomes easy by sharing the first member 130A and the second member 130B.

[Third Embodiment]
Hereinafter, a carport 1 according to a third embodiment of the present invention will be described with reference to the drawings.
The carport 1 according to the third embodiment is substantially the same as that of the second embodiment, but includes a water stop member 150 integrally formed as shown in FIG. 18 instead of the water stop member 130.
The water stop member 150 does not have a configuration corresponding to the guide tube portion 136 of the water stop member 130 described above, and is not divided into the first member 130A and the second member 130B unlike the water stop member 130. It is integrally formed as one member, and is formed in the same manner as the water blocking member 130 except for these points.
The vertical dimension H1 in the Z-axis direction of the water blocking member 150 is made smaller than the vertical dimension H2 in the Z-axis direction of the hollow portion 871 of the roof material 81B. Can be inserted into the hollow portion 871.
The water stop member 150 described above is constructed as follows. First, the wet seal material 56 is attached to the inner and outer concave surface portions 138 of the water stop cylinder portion 135 of the water stop member 150 and the upper surface 137A of the water stop main body portion 137.
Next, as shown in FIG. 19, the water stop member 150 is moved in the Y-axis direction and inserted into the hollow portion 871 from the small opening of the roofing material 81B, and then the water stop member 150 is moved upward to stop the water stop cylinder portion. 135 is inserted into the insertion opening 92, the water blocking cylinder portion 135 is brought into contact with the upper surface portion 861 of the roof material 81 </ b> B, and the upper surface 137 </ b> A of the water stopping main body portion 137 is brought into contact with the lower surface 861 </ b> B of the upper surface portion 861. In this state, the fixing screw 140 is screwed into the mounting hole 139 of the water stop main body 137 to attach the water stop member 150 to the upper surface portion 861 of the roof material 81B.
Next, the bundle 10 is inserted through the insertion openings 91 and 92 of the roof material 81 </ b> B, and the bundle 10 is inserted into the water blocking cylinder portion 135 of the water blocking member 150. As a result, the water between the upper surface portion 861 and the water stop tube portion 135 and between the bundle 10 and the water stop tube portion 135 is stopped by the wet seal material 56 stored in each seal material reservoir space 57. Further, between the upper surface portion 861 and the water stop main body portion 137, the wet sealing material 56 attached to the upper surface 137A of the water stop main body portion 137 adheres to the lower surface 861B of the upper surface portion 861 to stop water.
According to the third embodiment, it is possible to exert the same effect as the effect in the second embodiment, and furthermore, the water stop member 150 can be inserted from the small opening without passing through the insertion port 91 of the roof material 81B, so that the construction site Therefore, it is not necessary to pass the bundle 10 through the water stop member 150 in advance. For this reason, the water stop member 150 can be previously attached to the roofing material 81B in a factory, and the burden of site construction can be reduced.
Moreover, since it is not necessary to pass the water stop member 150 through the insertion port 91, each dimension of the insertion port 91 in the X and Y axis directions can be made smaller than each dimension of the water stop member 150 in the X and Y axis directions. It is possible to make a shape in which almost no gap is formed between the outer peripheral surface 101 of the bundle 10 inserted through 91. For this reason, the structure of the decorative material 141 (member for closing the insertion port 91) in 2nd Embodiment can be abbreviate | omitted.

[Modification]
For example, in the first embodiment, the two frames 2A and 2B are provided, but two or more frames may be provided. In this case, the bundle 10 is erected on the beam 4 of each frame.
In the first embodiment, the longitudinal direction of the upper beam 70 is parallel to the longitudinal direction of the beam 4, but may be orthogonal.
In the first embodiment, since the roof material 81 is formed of an aluminum extruded profile, the upper end portion 11 of the bundle 10 may be fixed to the roof material 81 instead of the upper beam 70. In this case, the bundle 10 may be fixed inside the roof material 81, and may be fixed to the lower surface of the roof material 81 when the insertion holes 91 and 92 are not formed in the roof material 81. .
In the first embodiment, the roof material 81 is disposed below the upper beam 70, but may be disposed above the upper beam 70.
In the first embodiment, the roof material 81 is configured to have hollow portions 829, 839, 849, 871, 872, and 873, but is configured of a plate material that does not have such a hollow portion. Also good.
In the first embodiment, the slope 50 is inclined with respect to the Y-axis direction on the roof 50 by making the vertical dimensions L1 and L2 of the columns 3 of the frames 2A and 2B different from each other. The gradient of the roof 50 may be set by changing the vertical dimension of 10B. Further, the support columns 3 and the bundles 10A and 10B may have the same vertical dimension. In this case, the vertical dimension L1 of the plurality of bundles 10A erected on the beam 4 of the frame 2A is made different, and the frame A slope inclined with respect to the X-axis direction may be set on the roof 50 by making the vertical dimension L2 of the plurality of bundles 10B erected on the 2B beam 4 different.

In the first embodiment, the fixing holes 27 are formed in the corner portions 261 to 264 of the bundle 10, but instead of the fixing holes 27, screw holes communicating with the hollow portion 25 are formed through slits. Also good.
In the first embodiment, the thickness dimensions T1 and T2 of the corner portions 261 to 264 of the bundle member 20 are larger than the thickness dimensions T3 and T4 of the first bundle piece portions 21 and 22 and the second bundle piece portions 23 and 24. Although it is enlarged, the same dimension may be sufficient.
In the first embodiment, the second bundle piece portions 23 and 24 of the bundle member 20 are formed with contact protrusions 231 and 241 that contact the second reinforcement piece portions 33 and 34 of the reinforcement member 30. This configuration may be omitted.
In the first embodiment, the fixed body 40 of the bundle 10 is configured by the first fixed member 40A and the second fixed member 40B, but the configuration of the second fixed member 40B may be omitted.
In the first embodiment, the bundle 20 is fixed to the beams 4 of the frames 2 </ b> A and 2 </ b> B via the fixed body 40, but the configuration of the fixed body 40 is omitted, and the fixing bolt 7 is inserted into the fixing hole 27 of the bundle 20. May be fixed to the beam 4 by fastening.
In the first embodiment, a pipe opening 471 and a pipe notch 472 are formed in the bundle 10, but these configurations may be omitted.
In the first embodiment, the fixing body 40 is provided with the reinforcing rib 46, but this configuration may be omitted.
In the first embodiment, the bundle member 20 and the reinforcing member 30 have four sides and are formed in a rectangular tube shape, but are not limited thereto, and are formed in a rectangular tube shape such as a triangular shape, a pentagonal shape, a hexagonal shape, etc. It may be formed or may be formed in a cylindrical shape. When the bundle member 20 is formed in a cylindrical shape, the corner portion is not formed. Therefore, the portion where the fixing hole 27 is formed may be configured as a thick portion.

In the first embodiment, the water stop member 110 is installed on the upper surface 861A of the roof material 81. However, when it is not necessary to stop the water between the roof material 81 and the bundle 10, the structure of the water stop member 110 is provided. May be omitted.
In the first embodiment, the water stop member 110 includes both the lower fixed screw hole 121 and the upper fixed screw hole 122, but may not include the upper fixed screw hole 122 when not fixed to the upper beam 70. .
In the first embodiment, the dry sealing material 125 is interposed between the upper surface 861A of the roof material 81 and the lower surface 111B of the water stop member 110, but a wet sealing material may be applied instead. . Moreover, when the part which contact | abuts the upper surface 861A of the roof material 81 among the water stop members 110 is comprised by soft resin etc., the water seal member 110 and the roof material are not used without using the dry-type seal material 125 or the wet seal material. Water may be stopped by pressure bonding with 81.
In addition, the dry sealing material 125 is interposed between the lower surface 71A of the upper beam 70 and the upper surface 111A of the water blocking member 110, but a wet sealing material may be applied instead. Further, when the portion of the water stop member 110 that is in contact with the lower surface 71A of the upper beam 70 is made of a soft resin or the like, the water stop member 110 and the upper beam are not used without using the dry seal material 125 or the wet seal material. Water may be stopped by pressure bonding with 70.
In the first embodiment, the collar portion 867 is formed on the upper surface 861A of the roof material 81B, but the configuration of the collar portion 867 may be omitted.
In the first embodiment, the upper surface 121A of the lower fixing screw hole 121 of the water stop member 110 is disposed at a position lower than the upper surface 111A of the cylindrical main body 111. However, when the water stop member 110 is not fixed to the upper beam 70, The upper surface 121A of the lower fixing screw hole 121 may be disposed at the same height as the upper surface 111A of the cylindrical main body 111 or at a position higher than the upper surface 111A.

In the first embodiment, the lower overlapping portions 836 and 868 of the roof material 81 are located on the inner side of the side surface portions 833 and 863, but there is a margin in the dimension in the X-axis direction between the side frames 63 and 64. In some cases, it may have a lower overlapping portion extending outward with respect to the side surface portions 833 and 863.
In the first embodiment, the lower overlapping portion 836 (836A) and the upper overlapping portion 846 of the roof materials 81A and 81C are raised upward by the rising pieces 834 (834A) and 844, but the panel member 82 is used. In the case where it is not necessary to configure the flange portion, the configuration of the rising piece portions 834 (834A) and 844 may be omitted. In this case, the lower overlapping portion 836 (836A) is constituted by a part of the upper surface portion 821 of the panel material 82.
In the first embodiment, the panel member 82 is formed with a mounting portion 821A protruding above the lower overlapping portion 836 (836A) and the upper overlapping portion 846, but there is no such mounting portion 821A. If the panel member 82 can be attached to the upper beam 70, the configuration of the attaching portion 821A protruding upward may be omitted.
In the first embodiment, two vertical piece portions 823 continuous with the upper surface portion 821 (861) and the lower surface portion 822 (862) between the pair of side surface portions 833, 843 (863, 864) of the panel material 82 (86). (865) to form the box portion 88 (89) and increase the strength of the panel member 82 (86), but there is sufficient strength even if the box portion 88 (89) is not formed. The configuration of the two vertical piece portions 823 (865) may be omitted.
In the first embodiment, the roof material 81C (end roof material) fixed to the side frame 64 is provided. However, even when the side frame 64 is the roof material 81A, 81B, the roof material 81C can be fixed. May be provided with a roofing material 81A or a roofing material 81B instead of the roofing material 81C.

In the first embodiment, the space between the front frame 61 and the ends 811 of the plurality of roofing materials 81 is stopped by the dry sealing material 55, but in addition to or instead of this, a sealing process using a wet sealing material May be applied.
In the first embodiment, the end plate material 611 is configured by a single member extending in the X-axis direction and is used as the structure of the front frame 61. A plurality of end plate members fixed to one or a part of the end portions 811 may be provided. In this case, a frame material serving as a structure of the front frame 61 may be separately provided.
In 1st Embodiment, although the screw hole 85 is formed in each corner | angular part of the box part 88 (89) of the some roofing material 81, these screw holes 85 are lost and other different from the box part 88 (89) A screw hole 85 may be formed at the location. Further, a hole into which the fixing screw 65 can be screwed may be formed instead of the screw hole 85 having a slit.
In the first embodiment, if the end plate material 611 and the decorative material 615 are separate, the end plate material 611 and the decorative material 615 are integrated as long as the end plate material 611 can be fixed to the end portion 811 of the roof material 81. It may be formed.
In the first embodiment, the corner seal member 68 is screwed to the end 615A (625A) of the decorative material 615 (625) and bonded to the end 635A (645A) of the decorative material 635 (645). On the contrary, it may be screwed to the end portion 635A (645A) of the decorative material 635 (645) and adhered to the end portion 615A (625A) of the decorative material 615 (625), or to both May be.
In the first embodiment, the drain end plate material 621 is fixed to the end portion 812 of the roof material 81, but this configuration may be omitted. In this case, a frame material serving as a structure of the rear frame 62 may be provided separately.

In the first embodiment, the beam 4 is provided with the upper light 510 for illuminating the lower surfaces 822A and 862A of the roof 50. However, when the roof 50 does not need to be illuminated, the configuration of the upper light 510 is omitted. May be. Further, the downlight 530 is installed on the beam 4, but the downlight 530 installed on the beam 4 is omitted when sufficient illumination is obtained by installing the downlight 530 on the roofing material 81, for example. May be.
In the first embodiment, the beams 4 are arranged below the roof 50 as shown in FIG. 2, but for example, the roof structure 1B shown in FIG. The beam 4 </ b> B extending to the outside may be provided, and the column 3 may be fixed to the end of the extended portion 401 that is the extended portion of the beam 4 </ b> B. Further, a plurality of bundles 10 (four bundles in FIG. 20) may be arranged at intervals in the X-axis direction, and the upper light 510 may be installed between the bundles 10 on the beam 4B. One or a plurality of downlights 530 may be installed in the exit portion 401. According to such a configuration, for example, when the downlight 530 is installed on the roof 50, the downlight 530 cannot be installed at a place where the roof 50 does not exist. However, in this embodiment, the extended portion of the beam 4B is provided. Since the downlight 530 is installed at 401, the downlight 530 can be installed at a place where the roof 50 does not exist, and the downlight 530 can illuminate the lower side from the beam 4B side. In addition, such a roof structure 1 </ b> B uses a region where the roof 50 is provided for a carport or the like illuminated by the upper light 510, and a region where the beam 4 </ b> B extends outside the roof 50 is illuminated by the downlight 530. It can be used for approaches.
In the first embodiment, the frames 2A and 2B are configured such that the beam 4 is supported by a pair of support columns 3. However, one of the support columns 3 is omitted and the beam 4 is cantilevered within a range in which strength can be secured. It may be configured to.
In the first embodiment, one upper light 510 is arranged between two bundles 10 arranged at an interval in the X-axis direction, but a plurality of upper lights 510 are arranged in the X-axis direction. It may be arranged. In this case, among the plurality of upper lights 510, the interval between the upper lights 510 and the one bundle 10 on one end side, and the upper lights 510 and the other bundle 10 on the other end side among the plurality of upper lights 510 are arranged. By setting the interval to be equal, the irradiation light from the plurality of upper lights 510 can be similarly spread on both sides in the X-axis direction.
In the first embodiment, the upper lights 510 are arranged at equal intervals with respect to the two bundles 10 sandwiching the upper lights 510, but the intervals with respect to the two bundles 10 may be different.
In the first embodiment, the upper light 510 is disposed between the two bundles 10 that are spaced apart from each other in the X-axis direction, but instead of or in addition to this, between the two bundles 10. Instead, an upper light 510 arranged at a position closer to the end of the beam 4 than the bundle 10 may be provided.
In the first embodiment, the upper surface 405 of the beam 4 is formed with a recess 4A that is open at the top. However, this configuration may be omitted, and in this case, the upper light 510 is connected to the side frame of the beam 4. It is installed at a position protruding upward from the upper surface 424 of the portions 422 and 423.
In the first embodiment, the beam 4 includes the upper cover member 5A that covers the recess 4A, but this configuration may be omitted. In the first embodiment, the illumination light of the upper light 510 passes through the illumination opening 523 formed in the upper cover material 5A. For example, a part of the upper light 510 is directed upward from the illumination opening 523. You may arrange | position by making it protrude.
In the first embodiment, the roof 50 is inclined upward as it goes from the rear side to the front side of the roof 50 in the Y-axis direction. May be.

In the second embodiment, the concave surface portion 138 for forming the seal material reservoir space 57 is formed on the inner peripheral surface 135A and the outer peripheral surface 135B of the water blocking cylinder portion 135, but the configuration of the concave surface portion 138 is omitted. Also good.
In the second embodiment, the first member 130 </ b> A and the second member 130 </ b> B constituting the water stop member 130 are formed by a halved body having a common shape, but may have different shapes within a range that can be combined with each other. Good.
In the second embodiment, the wet seal material 56 is attached to the water stop member 130, but instead of this, a dry seal material such as sponge may be used.

  DESCRIPTION OF SYMBOLS 1 ... Carport (roof structure), 2A, 2B ... Frame, 3 ... Post, 4 ... Beam, 10 (10A, 10B) ... Bundle, 110, 130, 150 ... Water stop member, 111 ... Cylindrical main body, 121 ... lower fixed screw hole, 122 ... upper fixed screw hole, 135 ... water stop cylinder part, 136 ... guide cylinder part, 137 ... water stop main body part, 20 ... bundle material, 21, 22 ... first bundle piece part, 23, 24 ... first Two bundle pieces, 261 to 264 ... corner (thick part), 27 ... fixing hole, 30 ... reinforcing material, 31, 32 ... first reinforcing piece, 33, 34 ... second reinforcing piece, 40 ... fixed Body 50 ... Roof 510 Upper light (upper lighting) 530 Downlight (lower lighting) 55, 125 Dry sealing material 60 Roof frame 61 Front frame 611 End plate material 615 , 625, 635, 645 ... cosmetics, 616B, 833, 843 63,864 ... side face part, 62 ... rear frame, 621 ... drainage end plate material, 63, 64 ... side frame, 631, 641 ... side plate material, 632, 642, 864, 869 ... upper overlapping part, 70 ... upper beam, 81 (81A, 81B, 81C) ... roofing material, 82, 86 ... panel material, 836, 868 ... lower overlapping part, 91, 92 ... insertion port.

Claims (7)

A pair of columns and beams fixed to the pair of columns; and at least two frames arranged side by side; a bundle standing on each of the beams; and a roof supported by the bundle. And
The said bundle is arrange | positioned inside the peripheral part of the said roof in the longitudinal direction of the said beam. The roof structure characterized by the above-mentioned. In the roof structure according to claim 1,
The roof includes a roof frame that constitutes a peripheral portion of the roof, an upper beam having both ends attached to the roof frame, and a roof material attached to the roof frame,
The upper beam is attached to the upper end of the bundle;
The longitudinal direction of the said upper beam is parallel to the longitudinal direction of the said beam. The roof structure characterized by the above-mentioned. In the roof structure according to claim 1,
The roof includes a roof frame that constitutes a peripheral portion of the roof, an upper beam having both ends attached to the roof frame, and a roof material attached to the roof frame,
The roof material is disposed below the upper beam.
A roof structure characterized by that. In the roof structure according to any one of claims 1 to 3,
The roof is constituted by a roof material having a hollow portion,
In the roof material, an insertion port communicating with the hollow portion is formed,
The roof structure body, wherein an upper end portion of the bundle is inserted through the insertion opening. In the roof structure according to any one of claims 1 to 4,
The roof structure according to claim 1, wherein a vertical dimension of the pair of support columns in one of the two frames is different from a vertical dimension of the pair of support columns in the other of the two frames. In the roof structure according to any one of claims 1 to 5,
The roof has a roof frame that constitutes a peripheral edge of the roof, an upper beam having both ends attached to the roof frame, and both ends are attached to the roof frame in parallel with the roof frame. And a roof material composed of a plurality of metal panel materials,
The upper beam and the longitudinal direction of the beam are parallel;
The roof structure according to claim 1, wherein a longitudinal direction of the plurality of panel members is orthogonal to a longitudinal direction of the upper beam. In the roof structure according to any one of claims 1 to 6,
An upper lighting tool for illuminating the lower surface of the roof is installed in a region of the beam facing the lower surface of the roof in the vertical direction.