JP2019218824A - Roof structure and roof plate - Google Patents

Abstract

To provide a roof structure and a roof plate which can prevent discharge water from staying and can prevent water from infiltrating to a substrate even when wind is blown along a roof surface.SOLUTION: A roof structure includes a first roof plate 5, and a second roof plate 8 which is arranged in one direction to the first roof plate 5 and is connected to the first roof plate 5. The first roof plate 5 includes a first body part 61 constituting a part of the roof surface 1, a holding body 66 which is connected to an end in one direction of the first body part 61 and is folded back to above the end, and a gutter part 67 which is connected to the one direction to a hooking part. The second roof plate 8 includes a second body part 91 constituting a part of the roof surface 1, and a hook body 92. The hook body 92 is connected to an end opposite to the end in the one direction of a second body part 91, is folded back to below the end, and the holding body 66 is hooked thereto. The gutter part 67 has a standing wall 676 projecting above the upper end of the holding body 66.SELECTED DRAWING: Figure 8

Description

  The present invention relates to a roof structure and a shingle.

  Patent Literature 1 discloses a conventional vertical roofing material (fitting type roofing material). The fitting type roofing material described in Patent Literature 1 includes an upper goby and a lower goby at an end in the width direction. The upper gob and the lower gob protrude upward from the plate-like body constituting the roof surface.

  The fitting type roof materials adjacent in the width direction are connected by fitting the upper goby to the lower goby.

JP-A-2006-205120

  By the way, the fitting type roofing material described in Patent Document 1 described above has a problem that, when used for a gentle slope roof, for example, the drainage is easily blocked by the wind blowing from below the water along the roof surface to above the water. . When the drainage is stopped on the roof surface, the liquid level of the drainage rises.

  The present invention has been made in view of the above circumstances, and an object of the present invention is to provide a roof structure and a roof slab that can prevent drainage from being clogged even when wind blows along a roof surface and can suppress inundation into a groundwork. .

A roof structure according to an aspect of the present invention includes a first shingle and a second shingle disposed in one direction with respect to the first shingle and connected to the first shingle. The first shingle, a first main body that constitutes a part of a roof surface, a holding body that is connected to an end of the first main body in the one direction, and is folded over the end, A gutter part connected to the holding body in the one direction,
Having. The second shingle is connected to an end of the second main body constituting a part of the roof surface and an end opposite to the end in the one direction of the second main body, and below the end. And a hook body on which the holding body is hooked. The gutter portion includes a standing wall protruding above an upper end of the holding body.

  A roof plate according to one aspect of the present invention includes a main body, a holding body connected to one end of the main body in one direction, and a folded back above the end, and the holding body in the one direction. A gutter portion connected thereto, and a hook connected to an end of the main body opposite to the end in the one direction and folded back below the end. The gutter has a standing wall protruding above the upper end of the holder.

  The above-mentioned roof structure and shingle have the advantage that even when wind blows along the roof surface, drainage can be made less likely to be clogged and flooding of the groundwork can be suppressed.

FIG. 1 is a perspective view of a connection structure for a vertical roofing material according to one embodiment of the present invention. FIG. 2 is a perspective view in which the building board is partially omitted. FIG. 3A is a perspective view of the building board of the above. FIG. 3B is a longitudinal sectional view of the building board. FIG. 3C is an enlarged view of a portion A in FIG. 3B. FIG. 4 is a cross-sectional view of a water return piece of the building board. FIGS. 5A to 5C are plan views when connecting the above-described connecting portions. FIG. 5D is a sectional view taken along line AA of FIG. 5A. FIG. 5E is a sectional view taken along line BB of FIG. 5B. FIG. 5F is a cross-sectional view taken along line CC of FIG. 5C. FIG. 6 is a plan view of the connecting portion of the above. 7A to 7C are plan views when connecting the first roof slat and the second roof slab in the above. FIG. 7D is a sectional view taken along line DD of FIG. 7A. FIG. 7E is a sectional view taken along line EE of FIG. 7B. FIG. 7F is a sectional view taken along line FF of FIG. 7C. FIG. 8A is a cross-sectional view in which the first roof panel and the second roof panel are connected to each other. FIG. 8B is an enlarged view of a portion G of FIG. 7A. FIG. 9A is a cross-sectional view illustrating a drainage state. FIG. 9B is a cross-sectional view illustrating a drainage state when the drainage is stopped. FIG. 10 is a perspective view showing a different example of use of the above-mentioned building board, which is used as a roofing material. FIG. 11A is a cross-sectional view of the roof structure according to the first modification. FIG. 11B is a perspective view of a building board used for the roof structure according to the first modification. FIG. 12 is a perspective view of a connection structure of a vertical roofing material according to another modification.

(1) Embodiment (1.1) Outline The roof structure according to the present embodiment includes a first shingle 5 and a second shingle 8, as shown in FIG. The second shingle 8 is arranged in one direction with respect to the first shingle 5, and is connected to the first shingle 5.

  As shown in FIG. 3, the first shingle 5 is connected to a first main body 61 that forms a part of the roof surface 1 and an end in one direction of the first main body 61, and is located above the end. It has a folded holder 66 and a gutter portion 67 connected to the holder 66 in one direction.

  As shown in FIGS. 8A and 8B, the second shingle 8 has a second main body 91 that forms a part of the roof surface 1 and a hook 92. The hook 92 is connected to an end of the second main body 91 opposite to the end in one direction, is folded below the end, and is hooked on the holder 66. The gutter portion 67 has a standing wall 676 protruding above the upper end of the holding body 66.

  In the present embodiment, as shown in FIGS. 9A and 9B, even if the wind blows from below the water along the roof surface 1 and the flow of water on the first main body 61 is interrupted, the water is drained through the gutter 67. be able to. The gutter portion 67 is covered with the second roof plate 8 and is less susceptible to wind, so that smooth drainage can be realized. In addition, even if the liquid level in the gutter part 67 rises, the standing wall 676 can prevent the base from being flooded.

(1.2) Details Hereinafter, the connection structure of the roofing material 60 according to the present embodiment will be described in detail based on the roof structure of a building. The building according to the present embodiment is a non-residential building. Examples of the non-residential building include a store, a warehouse, a factory, a meeting place, and the like. However, the building according to the present disclosure is not limited to a non-residential building, and may be a residential building or a complex building.

  The roof structure is formed at the top of the building. The “upper part of the building” here includes, for example, the upper part of the first floor of a two-story building. In short, the “roof structure” referred to in the present disclosure includes the structure of a shed.

  The roof structure has at least one roof surface 1. The “roof surface 1” in the present disclosure is one of the top surfaces of the roof and has a constant roof slope. As the roof structure, for example, in the case of a roof structure relating to a one-way roof, the roof structure has one roof surface 1, and in the case of a roof structure relating to a gable roof, the roof structure has two roof surfaces 1. In the present disclosure, three or more roof surfaces 1 may be provided like a composite roof. In the present embodiment, a roof structure corresponding to one roof surface 1 will be mainly described.

  FIG. 1 is a perspective view of one roof surface 1 of the roof structure, and a part thereof is broken. As shown in FIG. 1, the roof structure according to the present embodiment is a roof structure obtained by applying a repair method to an existing roof. However, in the present disclosure, the roof structure does not need to be a structure to which the repair method is applied, and may be a newly constructed roof structure. The roof structure according to this embodiment includes a roof base 2 (base), a plurality of existing shingles 3, a plurality of shingles 4 arranged on the existing shingles 3, the existing shingles 3 and the shingles 4. And an underlaying material (not shown) disposed between them. Although the illustration of the underlaying material is omitted in FIGS. 1 and 2, it actually covers the existing roof plate 3. The underlaying material is, for example, asphalt roofing.

  In the present disclosure, a member below the shingle 4 may be referred to as a “under roof member”. In the present embodiment, the “under-roof member” is the existing shingle 3 and the underlaying material, but when the existing shingle 3 is not provided, the “under-roof member” is, for example, the roof foundation 2.

  Here, in the present disclosure, the highest part on one roof surface 1 is defined as “above water”, and the lowest part is defined as “under water”. In addition, the direction of the drainage from the water surface to the water surface, which is designed, on the roof surface 1 is defined as a “water flow direction”. In the present embodiment, the water is a ridge, the water is an eave, and the water flow direction is parallel to the eave ridge direction. In addition, a direction orthogonal to the water flow direction and along the roof surface 1 is defined as a “lateral direction”.

  The roof structure according to the present embodiment has a plurality of shingles 4. Each shingle 4 extends in the water flow direction, that is, the longitudinal direction of each shingle 4 is parallel to the water flow direction. In this embodiment, each roof plate 4 is composed of a plurality of building boards 6 (here, vertical roofing members 60) or a plurality of building boards 9 (here, vertical roofing members 60). It is formed over the entire length to the bottom. The plurality of shingles 4 are arranged side by side in the horizontal direction, and adjacent ends are connected to each other. In the following description, the relationship between two adjacent shingles 4 (first shingles 5 and second shingles 8) will be mainly described as the plurality of shingles 4. The plurality of shingles 4 are formed by the relationship between the first shingles 5 and the second shingles 8.

(1.2.1) Roof base Roof base 2 is the base of the existing roof slat 3 or the plurality of roof slats 4. In the present embodiment, the roof base 2 includes a base plate 21, a roofing material 22 laid on the upper surface of the base plate 21, and a drainer 23. The underlaying material 22 is asphalt roofing in the present embodiment. The upper surface of the roofing material 22 constitutes the upper surface of the roof base 2. A plurality of existing shingles 3 are laid on the upper surface of the lowering material 22.

  The drainer 23 is attached to the lower edge of the baseboard 21. The drainer 23 is arranged between the baseboard 21 and the underlaying material 22. The water that travels through the roofing material 22 flows in the direction of the water flow, and is discharged down the eaves through the drainer 23.

(1.2.2) Existing roof slab A plurality of existing roof slabs 3 are attached to a roof base 2, as shown in FIG. The plurality of existing shingles 3 are shingles that have been constructed in advance before the first shingles 5 and the second shingles 8 are attached, and in the present embodiment, are shingles to be repaired. In the present embodiment, the existing roof shingle 3 is configured by a metal flat roof shingle. However, in the present disclosure, the existing roofing sheet 3 is not limited to the flat roofing roofing sheet, and may be a tiled roofing sheet, a corrugated roofing, or a horizontal roofing sheet.

  In the present embodiment, the existing roof plate 3 is formed of a metal plate. In the present disclosure, examples of the metal plate include a galvalume steel plate (registered trademark), a galvanized steel plate, a coated steel plate, an SGL (registered trademark) steel plate, a stainless steel plate, an aluminum alloy plate, and a titanium plate. However, the existing roof plate 3 is not limited to metal, and may be non-metal such as FRP (Fiber-Reinforced Plastics) or polycarbonate.

  In the present embodiment, the existing roof panel 3 is a vertical roofing material. The longitudinal direction of the existing shingle 3 is parallel to the water flow direction. In the present embodiment, each existing roof panel 3 is continuous from below the water to above the water. However, in the present disclosure, a plurality of existing roof plates 3 may be connected in the water flow direction.

  Existing roof panels 3 that are adjacent in the horizontal direction are connected at a connection end 31. The connection end 31 is configured by connecting the ends of the existing roof plate 3 in the lateral direction. In the present embodiment, the connection end 31 protrudes upward from the main surface (roof surface) of the existing shingle 3. The connection between the existing roof slats 3 at the connection end 31 is realized by a "split method" in which the ends are fastened to each other, or a "fitting method" in which the ends are fitted.

  The connection end 31 extends in the flow direction. In the present embodiment, the connection end 31 is formed over the entire length from below water to above water. In addition, the plurality of connection ends 31 are apart from each other at a constant interval in the horizontal direction.

(1.2.3) First shingle 5 The first shingle 5 is arranged above the existing shingle 3, as shown in FIG. The first shingle 5 is the shingle 4 that is connected from one end to the other end of the roof surface 1, and is formed from below water to above water in the present embodiment. The first shingle 5 includes a plurality of building boards 6 connected in the water flow direction.

  The building board 6 according to the present embodiment is a vertical roofing material 60. In this embodiment, each building plate 6 is formed by bending a metal plate, and more specifically, is formed by rolling. In the present disclosure, examples of the metal plate include a galvalume steel plate (registered trademark), a galvanized steel plate, a coated steel plate, an SGL (registered trademark) steel plate, a stainless steel plate, an aluminum alloy plate, and a titanium plate.

  As shown in FIGS. 3A and 3B, each building board 6 includes a first main body 61, a hook 65, a holder 66, and a gutter 67. In short, the first roof panel 5 includes the first main body 61, the holder 66, the gutter 67, and the hook 65. In the present embodiment, the first main body 61, the holder 66, the gutter 67, and the hook 65 are formed integrally.

  Here, in the present disclosure, the direction in which the holding body 66, the first main body part 61, the hook body 65, and the gutter part 67 are arranged in the building board 6 is referred to as a "first direction D1", and is orthogonal to the first direction D1 and The direction along the upper surface of the first main body 61 is defined as “second direction D2”. Further, a direction orthogonal to the first direction D1 and the second direction D2 is defined as a “height direction D3”.

  The term “along” in the present disclosure means that two straight lines on the same plane (or two planes of space, or one straight line and one plane) are parallel to each other, and the two straight lines are within a certain distance in the longitudinal direction. Means to continue. "Along" includes the relationship between a straight line and a non-linear line. The term “parallel” includes a case where an angle formed by two straight lines on the same plane (or two planes of a space, or one straight line and one plane) is, for example, 0 ° or more and 10 ° or less.

  The first main body 61 is a part that constitutes the main body of the building board 6. The first main body portion 61 is a portion constituting the roof surface 1 in the building board 6, and is exposed in a state where most of the building surface 6 is constructed. The first main body 61 includes a face plate 62, a rising part 63, and a falling part 64. In the present embodiment, the face plate portion 62, the rising portion 63, and the falling portion 64 are formed by bending, and the face plate portion 62, the rising portion 63, and the falling portion 64 are integrated.

  The face plate portion 62 is arranged along the upper surface of the under roof member. In the present embodiment, the face plate portion 62 is parallel to the roof surface (main surface) of the existing roof plate 3. In this embodiment, the face plate portion 62 rests on the roof surface of the existing roof material. As shown in FIG. 3A, the face plate portion 62 includes a pair of long sides 621 and 622 and a pair of short sides 623 and 624, and is formed in a rectangular shape when viewed in the height direction D3 (in plan view). .

  The face plate portion 62 has a first long side 621 and a second long side 622 as a pair of long sides 621 and 622. The first long side 621 and the second long side 622 are orthogonal to the first direction D1 and are separated from each other in the first direction D1. The face plate portion 62 has a first short side 623 and a second short side 624 as a pair of short sides 623 and 624. The first short side 623 and the second short side 624 are orthogonal to the second direction D2 and are separated from each other in the second direction D2. In the present embodiment, the first short side 623 is disposed on the upper side in the water flow direction, and the second short side 624 is disposed on the lower side in the water flow direction.

  The rising portion 63 rises from one end (second long side 622) of the face plate portion 62. In the present embodiment, the rising portion 63 is formed in a rectangular shape when viewed in a direction orthogonal to the upper surface of the rising portion 63 (the upper surface in the thickness direction of the rising portion 63). As shown in FIG. 3B, the rising portion 63 goes upward from the second long side 622 of the face plate portion 62 toward the side (outside) away from the face plate portion 62 in the first direction D1. It is inclined. As shown in FIG. 3C, an angle θ1 between the rising portion 63 and the face plate portion 62 is 90 ° or more and less than 180 °, and more preferably 140 ° or more and less than 170 °.

  Here, in the present disclosure, the rising portion 63 rising from one end of the face plate portion 62 means that the rising portion 63 is located above the face plate portion 62 in the height direction D3. Therefore, in the present disclosure, the rising portion 63 may be inclined with respect to the face plate portion 62 or may be perpendicular to the face plate portion 62.

  A lower end surface (a base end surface 631) of the rising portion 63 faces the lower roof member. In the present embodiment, the base end surface 631 rests on the roof surface of the existing shingle 3. In the height direction D3, the dimension H between the back surface 641 (inset corner portion) of the connection portion between the rising portion 63 and the falling portion 64 and the base end surface 631 is formed to be 20 mm or more. Preferably, it is formed to be 25 mm or more.

  The falling portion 64 extends downward from the upper end of the rising portion 63 (the upper side in the rising direction of the rising portion 63). Here, “extend downward” means that the extending direction of the falling portion 64 has a downward component in the height direction D3. In short, if the falling portion 64 is located below the upper end of the rising portion 63 in the height direction D3, the falling portion 64 may be parallel to the vertical surface or may be inclined with respect to the vertical surface. The falling portion 64 according to the present embodiment is inclined from the upper end of the rising portion 63 so as to go downward as it goes outside in the first direction D1.

  In the present embodiment, the falling portion 64 is formed in a rectangular shape when viewed in a direction perpendicular to the upper surface of the falling portion 64 (the upper surface of both surfaces in the thickness direction). In the present embodiment, the lower end of the falling part 64 is located above the face plate part 62 in the height direction D3.

  Packings 69a and 69b are provided on the upper surface of the water-side end of the first main body 61 in the second direction D2 and on the lower surface of the water-side end. The packing 69a is disposed below the water return piece 68 in the second direction D2 of the water-side end portion. In addition, the packing 69b is disposed above the below-described folded piece 70 in the second direction D2 in the water-side end portion. In the present embodiment, the packing 69a is formed over the entire length of the first main body 61 in the first direction D1. In the present embodiment, the packing 69b is formed at a position corresponding to at least the face plate 62 in the first direction D1 of the first main body 61.

  However, in the present disclosure, regarding the length of the packings 69a and 69b in the first direction D1, the packing 69b is formed over the entire length in the first direction D1, and the packing 69a corresponds to at least the face plate portion 62 in the first direction D1. It may be formed at a position where it does. Further, in the present embodiment, the portions corresponding to the corners between the face plate portion 62 and the rising portion 63 are wider than the other portions in the packings 69a and 69b, but may have the same width over the entire length. .

  In the present embodiment, the packings 69a and 69b are bonded to the building board 6 at the time of manufacturing. However, in the present disclosure, the packings 69a and 69b may not be provided at the time of manufacturing. For example, the packings 69a and 69b may be attached to the building board 6 by on-site work at the time of construction.

  The hook 65 is hooked on the holder 66 of the building board 6 (second roof plate 8) on the hook 65 side of the building boards 6 adjacent to the first direction D1, and in the second direction D2. It is hooked on the adjacent building board 6 (first roof board 5). The hook body 65 protrudes inward in the first direction D1 from the end of the first main body 61 in the first direction D1, and is positioned in the height direction with respect to the first main body 61 (here, the falling part 64). It is located below (here below) D3. The hook 65 includes an inclined portion 651 and a tip portion 652.

  The inclined portion 651 is caught by the holding body 66 of the adjacent building board 6, and restricts the first main body 61 from moving upward in the height direction D3 with respect to the holding body 66. The inclined portion 651 is inclined so as to go inward in the first direction D1 (to the face plate portion 62 side) from the lower end of the falling portion 64 as going downward. In the present disclosure, the inclined portion 651 may have an angle with respect to the vertical plane in a range greater than 0 ° and 90 ° or less.

  The distal end portion 652 is a portion configured so that the hook 65 can be easily inserted into the corner between the holding body 66 and the first main body 61. The tip 652 protrudes from the lower end of the inclined portion 651 and is formed at the lower end of the hook 65. The tip portion 652 has an angle with respect to the inclined portion 651. However, in the present disclosure, the tip 652 may have the same angle as the inclined portion 651.

  The holder 66 is a portion where the hook 65 of the building board 6 (second roof panel 8) adjacent in the first direction D1 is hooked. The holding body 66 is connected to an end of the first main body 61 in the first direction D1. The holding body 66 is inclined so as to go inward in the first direction D1 as it goes upward from one end of the first main body 61 in the first direction D1. The holding body 66 is disposed above the first main body 61 in the height direction D3. In short, the holding body 66 is folded back from the end of the first main body 61. In the present embodiment, the holding body 66 is formed by bending the distal end of the first main body 61.

  Here, in the present embodiment, the holding body 66 is formed by bending the distal end of the first main body 61, but in the present disclosure, the holding body 66 may be formed by welding. In short, in the present disclosure, “turned back” means that the angle between the first main body 61 and the holding body 66 is an acute angle, and the manufacturing method is intended to be specific to bending. is not.

  The gutter portion 67 is connected to the tip of the holding body 66, receives the rainwater, and flows the rainwater in the water flow direction. In the present embodiment, the gutter portion 67 includes a connecting portion 671, a drain groove 672, an upright wall 676, and a support piece 677.

  The connecting portion 671 is a portion connecting the holding body 66 and the drain groove 672. The connecting portion 671 is inclined so as to go downward as it goes outside in the first direction D1 in the installed state. A drain groove 672 is connected to an outer end of the connecting portion 671 in the first direction D1. Thus, the water attached to the connecting portion 671 flows along the surface to the drain groove 672.

  The drain groove 672 is connected to the connecting portion 671. In this embodiment, the drain groove 672 is formed in a U-shaped cross section. The drain groove 672 has a uniform cross-sectional shape in the water flow direction, and is formed with respect to the first main body 61 over the entire length in the water flow direction. The drain groove 672 includes a first side wall 673 connected to the connecting portion 671, a bottom wall 674, and a second side wall 675 facing the first side wall 673.

  The bottom wall 674 connects the lower ends of the first side wall 673 and the second side wall 675. In the installed state, the bottom wall 674 is attached to the roof foundation 2 via the fixing tool 41 as shown in FIG. In the installed state, the fixing tool 41 may be covered with a waterproof material such as caulking or may not be covered with the waterproof material.

  The upright wall 676 projects upward from the upper end of the second side wall 675. The upright wall 676 is a portion protruding above the upper end of the holding body 66 in the up-down direction. The upright wall 676 is formed over the entire length of the drain groove 672 in the longitudinal direction (water flow direction). In the present embodiment, the upright wall 676 does not have a boundary with respect to the second side wall 675, but in the present disclosure, the space between the second side wall 675 and the upright wall 676 may be formed in a stepped shape.

  The support piece 677 is provided at the upper end of the upright wall 676. As shown in FIG. 8B, the support piece 677 faces the lower surface of the rising portion 63 of the building board 6 adjacent to the first direction D1 in the installed state. In the present embodiment, the support pieces 677 support the lower surface of the rising portion 63 of the building board 6 adjacent in the first direction D1. The support piece 677 is inclined so as to go downward as it goes outside in the first direction D1.

  In the present embodiment, since the upright wall 676 supports the back surface 641 of the connection portion between the rising portion 63 and the falling portion 64, the rising portion 63 or the falling portion 64 is subjected to snowfall, treading force, or the like. Even when a load is applied in the downward direction, the rising portion 63 and the falling portion 64 are not easily deformed. In the present embodiment, since the support piece 677 is provided at the upper end of the standing wall 676, the position of the upper end of the standing wall 676 with respect to the back surface 641 is unlikely to be shifted. In short, in the present embodiment, the support state of the rising wall 63 and the falling wall 64 by the standing wall 676 can be stabilized.

  That is, when the support piece 677 is not provided, if a load is applied to the falling portion 64 in the downward direction, the standing wall 676 is inclined with respect to the falling portion 64, so that the standing wall 676 is It moves to the rising portion 64 side in the direction D1. Thus, the standing wall 676 may not be able to support the rising portion 63 and the falling portion 64.

  On the other hand, in the present embodiment, when a load is applied to the falling portion 64 in the downward direction, the support piece 677 comes into contact with the back surface of the rising portion 64 from below. Movement to the rising portion 64 side is restricted. When a load is applied to the rising portion 63 in the downward direction, the support pieces 677 are elastically deformed with respect to the standing wall 676. At this time, since the movement of the standing wall 676 toward the falling part 64 in the first direction D1 is regulated by the falling part 64, the positional relationship between the upper end of the standing wall 676 and the back surface 641 is hard to change. As a result, in the present embodiment, the support state of the rising wall 63 and the rising wall 63 and the falling wall 64 can be stabilized.

  In the building board 6 according to the present embodiment, as shown in FIG. 3A, the water-side end of the building board 6 in the second direction D2 has a water return piece 68. The water return piece 68 is located on the upper side in the thickness direction of the first main body portion 61 from the edge of the face plate portion 62 and the rising portion 64 on one side in the second direction D2 (here, on the water side) in the second direction D2. It extends toward the other side (here, underwater).

  As shown in FIG. 4, the water return piece 68 can be switched between a position A1 along the roof surface 1 and a position A2 protruding above the roof surface 1 (in short, above the vertical roofing material 60). . The upper end of the water return piece 68 at the position A2 protruding above the roof surface is located on an extension of the upper end of the rising portion 64 in the present embodiment. In the present embodiment, the water return piece 68 at the position A2 protruding above the roof surface 1 extends in the vertical direction.

  In the building board 6 which is arranged most above the water in the water flow direction, the water return piece 68 is switched to a position A2 protruding above the roof surface 1 during construction. Thus, a so-called face door can be configured, and a gap generated between the first main body 61 and, for example, a ridge packet can be covered.

  The water return piece 68 at the position A2 protruding above the roof surface 1 extends in the vertical direction in the present embodiment, but may extend in a direction perpendicular to the roof surface 1 in the present disclosure. . In short, “upper side of the vertical roofing material” means that it is more outdoor than the virtual surface including the upper surface (the roof surface 1) in the thickness direction of the vertical roofing material.

  Further, the upper surface of the water return piece 68 at the position A1 along the roof surface 1 faces the lower surface of the building board 6 adjacent to the upper side in the water flow direction. At this time, the water return piece 68 at the position A1 along the roof surface 1 functions as a secondary water stop. In short, in the first roof plate 5, in the connecting portion 7 described later, the packings 69a and 69b function as the primary water stop, and the water return pieces 68 function as the secondary water stop. Aqueous is ensured.

  In the present embodiment, as shown in FIG. 3A, the lower end of the building board 6 in the second direction D2 has a folded piece 70. The folded piece 70 is a portion formed by performing hemming bending on the underwater end of the building board 6 in the second direction D2. Further, in the building board 6, one end (corner) in the first direction D1 is partially cut out of the water-side end in the second direction D2. By this notch, the number of overlapping metal plates when a plurality of building boards 6 are connected in the horizontal direction and the water flow direction can be suppressed.

(1.2.3.1) Connection Portion As shown in FIGS. 5A to 5F, one construction board 6 having such a configuration is connected to the construction board 6 adjacent in the water flow direction at the connection portion 7. You. In short, the first shingle 5 is configured by connecting a plurality of building boards 6 at the connection portions 7. As shown in FIG. 1, in the present embodiment, the connection portions 7 are not adjacent to each other in the horizontal direction, and the connection portion 7 of the first roofing material 5 and the connection portion 7 of the second roof plate 8 are in the water flow direction. It is shifted (this is called staggered arrangement). 5A, the connection portion 7 includes a first end portion 71 and a second end portion 75.

  The first end 71 is a water-side end of the building board 6 below the water among the building boards 6 connected in the water flow direction. The first end portion 71 includes a lower overlapping portion 72, a lower hooking portion 73, and a lower holding portion 74. Here, in the present disclosure, “end” means a certain range from the end face to a position inside a predetermined dimension in the water flow direction.

  The lower overlapping portion 72 is a portion that is overlapped on the lower surface of the second end 75. The lower overlapping portion 72 is an end on the water side of the first main body 61. When the first end 71 and the second end 75 are connected, the upper surface of the lower overlap portion 72 faces the lower surface of the second end 75.

  The lower hooking portion 73 is a portion that overlaps with the hooking body 65 of the building board 6 adjacent to the upper side in the water flow direction. The lower hooking portion 73 is an end on the water side of the hooking body 65. The lower hooking portion 73 is connected to the lower stacking portion 72.

  The lower holding portion 74 is a portion that overlaps with the holding body 66 of the building board 6 adjacent to the upper side in the water flow direction. The lower holding part 74 is a water-side end of the holding body 66. The lower holding part 74 is connected to the lower overlapping part 72.

  The second end portion 75 is a lower end portion of the building board 6 on the water side among the building boards 6 connected in the water flow direction. The second end 75 is connected to the first end 71. The second end portion 75 includes an upper overlap portion 76, an upper hook portion 77, and an upper holding portion 78.

  The upper overlap portion 76 is a portion that is overlapped with the lower overlap portion 72 of the first end portion 71 (in short, the upper surface of the first end portion 71). The upper overlap portion 76 is an end portion of the first main body portion 61 on the underwater side. The lower surface of the upper overlap portion 76 faces the upper surface of the lower overlap portion 72.

  The upper hooking portion 77 is a portion that overlaps the lower hooking portion 73 of the building board 6 adjacent to the lower side in the water flow direction. The upper hooking portion 77 is an end of the hooking body 65 on the underwater side. The upper hooking portion 77 is connected to the upper overlapping portion 76. The upper hooking portion 77 protrudes inward in the first direction D1 from an end (an end on the first position side described later) of the upper overlapping portion 76 in the first direction D1, and extends below the upper overlapping portion 76. It is located in. The upper hooking portion 77 is hooked by overlapping with the lower hooking portion 73, and the movement inward in the first direction D1 is regulated.

  The upper holding portion 78 is a portion that overlaps with the lower holding portion 74 of the building board 6 adjacent to the lower side in the water flow direction. The upper holding portion 78 is an end portion of the holding body 66 on the underwater side. The upper holding part 78 is connected to the upper overlapping part 76. When the upper holding part 78 and the lower holding part 74 overlap, the lower holding part 74 becomes an end of the second end 75 opposite to the upper hooking part 77 in the first direction D1 (a second position side described later). End).

  To connect the second end 75 to the first end 71, as shown in FIGS. 5B and 5E, the second end 75 is connected to the first end 71 in a lateral direction with respect to the first end 71. (Here, outside the first direction D1). The position of the second end 75 with respect to the first end 71 is referred to as a “first position”. In the first position, at least the upper hooking portion 77 of the second end 75 may be located on the side with respect to the first end 71 in plan view.

  Next, as shown in FIGS. 5C and 5F, the second end 75 at the first position is moved inward in the first direction D1, and the upper portion 76 of the second end 75 is moved to the first end. It overlaps with the lower overlapping part 72 of the part 71. The position of the second end 75 with respect to the first end 71 is referred to as a “second position”. As a result, the upper hooking portion 77 of the second end 75 overlaps the lower hooking portion 73 of the first end 71, and the second end 75 The upper holding portions 78 overlap. At this time, the lower surface of the packing 69b comes into close contact with the upper surface of the packing 69a.

  When connecting the second end 75 to the first end 71, the top end of the hook 65 of the second end 75 rubs against the upper surface of the first end 71, and the first end 71 Even if the upper surface of the is scratched, the scratch is not exposed. For this reason, a decrease in corrosion resistance due to scratches can be suppressed.

  At this time, the upward movement of the second end 75 is restricted relative to the first end 71. Then, as shown in FIG. 6, the second end 75 is movable with respect to the first end 71 in a direction parallel to the water flow direction. Therefore, in the first roof panel 5 according to the present embodiment, the overlapping margin between the first end portion 71 and the second end portion 75 in the connection portion 7 can be adjusted.

  In addition, since the second end portion 75 can be attached and detached by moving the second end portion 75 in the lateral direction with respect to the first end portion 71, after the roof surface 1 is roofed by the plurality of vertical roofing members 60, However, it is easy to remove only the one thatch 60.

(1.2.4) Second shingle The second shingle 8 is arranged above the existing shingle 3, as shown in FIG. The second shingle 8 is arranged laterally with respect to the first shingle 5. The second shingle 8 is connected to the first shingle 5. The second shingle 8 is the shingle 4 that is connected from one end to the other end of the roof surface 1, and is formed from below water to above water in the present embodiment. The second shingle 8, like the first shingle 5, includes a plurality of building boards 9 connected in the water flow direction.

  The building board 9 according to the present embodiment is a vertical roofing material 60. The building board 9 of the second shingle 8 has the same structure as the building board 6 of the first shingle 5. However, in the following description, in order to distinguish the building board 9 of the second roofing board 8 from the building board 6 of the first roofing board 5, the first main body 61 is referred to as a "second main body 91" and held. The body 66 is referred to as a “holding body 93”, the gutter section 67 is referred to as a “gutter section 94”, and the hook body 65 is referred to as a “hook body 92”.

  The second shingle 8 is attached to the first shingle 5 as follows. In the present embodiment, the first direction D1 is arranged parallel to the lateral direction and the second direction D2 is arranged parallel to the water flow direction in the first roof plate 5 and the second roof plate 8. As shown in FIGS. 7A to 7F, the hook 92 of the second shingle 8 is inserted into the corner between the holder 66 of the first shingle 5 and the first main body 61 (FIG. 7B). , 7E). Then, the hook 92 of the second shingle 8 is hooked on the holder 66 of the first shingle 5.

  In this state, as shown in FIGS. 7C and 7F, the second main body portion 91 of the second roof plate 8 rests on the support piece 677 of the first roof plate 5. As a result, the hook 92 of the second roof plate 8 is hooked up and down with respect to the holder 66 of the first roof plate 5, and the rising portion 63 and the falling portion of the second main body portion 91. 64 is supported by the support pieces 677 of the first roof plate 5.

  Here, a state in which the first roof panel 5 and the second roof panel 8 are connected is shown in FIGS. 8A and 8B. FIG. 8B is an enlarged view of a portion G of FIG. 8A.

  As shown in FIG. 8A, when the first shingle 5 and the second shingle 8 are attached above the existing shingle 3, the face plate portion 62 rests on the roof surface of the existing shingle 3 and the bottom wall of the gutter portion 67. 674 is placed on the roof surface of the existing shingle 3. In addition, as shown in FIG. 8B, the upright wall 676 and the second side wall 675 of the gutter portion 67 are disposed along one side in the first direction D1 with respect to the connection end 31 of the existing roof plate 3. In the present embodiment, the support piece 677 is disposed above the connection end 31. In this state, the bottom wall 674 of the gutter portion 67 is attached to the roof foundation 2 via the fixing tool 41.

  At this time, the connection end 31 of the existing roof panel 3 is accommodated in the space below the rising section 911 and the falling section 912 of the second roof panel 8. In the present embodiment, there is a gap between the connection end 31 and the rising portion 911 and the falling portion 912.

  However, in the present disclosure, the connection end 31 only needs to be accommodated in a space below the rising part 911 and the falling part 912, and the rising part 911 and the falling part 912 with respect to the connection end 31. May be listed. Further, the fact that the connection end 31 is accommodated in the space below the rising portion 911 and the falling portion 912 means that the connection end 31 is located below one of the rising portion 911 and the falling portion 912. 31 is located.

  In the present embodiment, rainwater flows on the upper surface of the first main body 61 in the water flow direction. For example, when the roof surface 1 of the present embodiment has a gentle slope (for example, 2 mm or less), as shown in FIG. 9A, drainage may be blocked on the upper surface of the first main body 61. In this case, when the water level of the drainage is equal to or lower than the upper end of the holder 66, the rainwater flows over the first main body 61.

  In this state, when the water level of the drainage further rises, the water level exceeds the upper end of the holder 66. Then, as shown in FIG. 9B, the rainwater flows into the gutter portion 67. The rainwater flowing into the gutter portion 67 is drained in the water flow direction along the gutter portion 67.

  Even if the water level of the drainage rises further than in this state, in the present embodiment, it is possible to prevent rainwater from flooding the roof foundation 2. That is, since the first roof panel 5 according to the present embodiment has the upright wall 676 protruding above the upper end of the holding body 66, even if the level of rainwater exceeds the upper end of the holding body 66, it is received by the gutter 67. be able to. As a result, it is possible to prevent rainwater from infiltrating into the roof base 2.

(1.3) Example of use (1.3.1) Horizontal roofing In the above embodiment, the building boards 6 and 9 are used as the vertical roofing material 60. However, the building board 6 is configured as shown in FIG. , Can also be used as the horizontal roofing material 600. That is, in the present embodiment, the building board 6 is selectively used for the horizontal roofing material 600 and the vertical roofing material 60.

  As shown in FIG. 10, when the building board 6 is used as the horizontal roofing material 600, the first direction D1 is parallel to the water flow direction and the second direction D2 in the first roofing sheet 5 and the second roofing sheet 8. Are parallel to the lateral direction. Further, in the first direction D1, the first roof plate 5 and the second roof plate 8 are arranged such that the end on the hook 65 side is located below the water, and the end on the side of the holder 66 is located above the water. Is done.

  In other words, in the present usage example, the longitudinal direction of the first roof plate 5 is along the lateral direction, and the face plate portion 62, the rising portion 63, and the falling portion 64 follow the water flow direction in this order. . The longitudinal direction of the second roof plate 8 is along the lateral direction, and the face plate portion 910, the rising portion 911, and the falling portion 912 follow the water flow direction in this order.

  Even when the building boards 6, 9 are used as the horizontal roofing material 600, the building boards 6, 9 can be arranged above the existing roof board 3.

(2) Modifications The above embodiment is merely one of various embodiments of the present disclosure. Various changes can be made to the embodiments according to the design and the like as long as the object of the present disclosure can be achieved. Hereinafter, a modification of the embodiment will be described. The modifications described below can be applied in appropriate combinations.

(2.1) Modification 1
The building board 6 according to the first modification includes a main body 610, a hook 65, and a holder 66, as shown in FIGS. 11A and 11B. The main body 610 includes a face plate 62, a rising part 63, and a falling part 64. The main body 610 corresponds to the “first main body 61” and the “second main body 91” in the above embodiment. The configuration of the hook 65 and the holder 66 is the same as that of the first embodiment.

  The face plate portion 62 is arranged along the upper surface of the existing roof plate 3. In this modification, the face plate portion 62 is inclined with respect to the roof surface of the existing roof plate 3. The end of the face plate portion 62 on the hook 65 side in the first direction D1 is located higher than the end on the opposite side.

  The rising portion 63 rises from the end of the face plate portion 62 opposite to the hook 65. The rising portion 63 stands along a vertical plane. The falling section 64 is connected to the upper end of the rising section 63. The falling part 64 is parallel to the face plate part 62 and has the same size as the face plate part 62. The falling part 64 is along the upper surface of the existing roof plate 3.

  In the building board 6 according to the modification, the connection end 31 is accommodated in the space below the rising portion 63 and the falling portion 64.

  Even in the first modification, since a plurality of building boards 6 can be connected in the water flow direction at the connection portion 7, the overlap margin between the first end portion 71 and the second end portion 75 can be adjusted. In addition, it is easy to remove a part of the plurality of building boards 6 in the water flow direction after the construction. Further, by moving the second end portion 75 in the lateral direction with respect to the first end portion 71, the building boards 6 are connected to each other. In connecting the building boards 6 in the water flow direction, the surface of the building board 6 is connected. Can be prevented from being damaged.

  Further, in the building board 6 of the first modification, since the rising portion 63 is formed in the middle portion in the first direction D1, the strength against wind pressure can be increased.

(2.2) Other Modifications Modifications of the embodiment will be listed below. The modifications described below can be applied in appropriate combinations.

  In the connection structure of the roofing material 60 according to the embodiment, the staggered arrangement in which the connection portions 7 are arranged so as not to be adjacent to each other is adopted. However, as shown in FIG. Good. Also, in the case of the horizontal roof, the staggered arrangement may be used as in the structure described in “(1.3.1) Horizontal roof”, or the connection portions 7 may be adjacent to each other.

  In the above embodiment, the first roof plate 5 is constituted by a plurality of building plates 6, but may be constituted by one building plate 6 continuous in the water flow direction. Similarly, the second roof panel 8 may also be constituted by one building panel 9 continuous in the water flow direction.

  In the above embodiment, the roofing plate 4 can be selectively used as the horizontal roofing material 600 and the vertical roofing material 60. However, in the present disclosure, a roofing roof dedicated to vertical roofing material may be used, It may be a shingle dedicated to horizontal roofing.

  In the present disclosure, the connection end 31 may be a bolt that fixes a corrugated sheet or the like to a roof foundation and protrudes upward from a roof surface. The connection end 31 does not have to extend in one direction.

  In the above embodiment, the underwater end of the second end 75 may be bent toward the first end 71. In this case, the underwater edge of the second end portion 75 faces the upper surface of the first end portion 71, but may be in contact with the upper surface of the first end portion 71 or may be apart therefrom. Good.

(3) Mode As described above, the roof structure according to the first mode is disposed in one direction with respect to the first shingle (5) and the first shingle (5). ) Is connected to the second shingle (8). The first shingle (5) is connected to a first main body (61) constituting a part of the roof surface (1) and an end in one direction of the first main body (61), and is located above the end. And a gutter portion (67) connected to the holder (66) in one direction. The second shingle (8) has a second main body (91) constituting a part of the roof surface (1), and a hook (92). The hook (92) is connected to an end of the second main body (91) on the opposite side to the one-direction end, is folded down below the end, and the holder (66) is hooked. The gutter part (67) has a standing wall (676) protruding above the upper end of the holder (66).

  According to this aspect, even if the flow of water on the first main body (61) is interrupted by the wind along the roof surface (1), the water can be drained through the gutter (67). The gutter part (67) is covered with the second roof plate (8) and is not easily affected by wind, so that smooth drainage can be realized. Also, even if the liquid level rises in the gutter section (67), the standing wall (676) can prevent the base from being flooded.

  In the roof structure according to the second aspect, in the first aspect, at least a portion of the second main body (91) rests on the upper end of the upright wall (676).

  According to this aspect, in the installed state, the shape of the second main body (91) can be stabilized.

  In the roof structure according to the third aspect, in the first or second aspect, the first shingle (5) and the second shingle (8) are vertical roofing members (60).

  According to this aspect, in the vertical roofing material (60), it is possible to suppress infiltration into the base.

  In the roof structure according to the fourth aspect, in the first or second aspect, the first shingle (5) and the second shingle (8) are horizontal roofing materials. The direction opposite to the one direction is a water flow direction.

  According to this aspect, in the horizontal roofing material, it is possible to suppress infiltration into the base.

  The shingle (4) according to the fifth aspect includes a main body (first main body 61), a holder (66), a gutter (67), and a hook (65). The holding body (66) is connected to one end of the main body in one direction, and is folded over the end. The gutter (67) is connected to the holder (66) in one direction. The hook body (65) is connected to an end opposite to the one-direction end of the main body, and is folded back below the end. The gutter part (67) has a standing wall (676) protruding above the upper end of the holder (66).

  According to this aspect, even if the flow of water on the main body (first main body 61) is interrupted by the wind along the roof surface (1), the water can be drained through the gutter (67). The gutter part (67) is covered with the second roof plate (8) and is not easily affected by wind, so that smooth drainage can be realized. In addition, even if the liquid level rises in the gutter part (67), the standing wall (676) can prevent the base from being flooded.

  The configurations according to the second to fourth aspects are not essential to the roof structure and can be omitted as appropriate.

1 Roof surface 2 Roof base (base)
4 Roof panel 5 First roof panel 60 Roofing material 61 First main body (main body)
65 Hook 66 Holder 67 Gutter 676 Standing Wall 8 Second Roof 91 Second Body

Claims (5)

With the first shingle,
A second shingle disposed in one direction with respect to the first shingle and connected to the first shingle,
A roof structure with
The first shingle is
A first main body that forms part of the roof surface,
A holder connected to the one-direction end of the first main body, and folded back above the end;
A gutter portion connected to the holder in the one direction;
Has,
The second shingle is
A second main body that forms part of the roof surface,
A hook that is connected to an end of the second main body opposite to the end in the one direction, is folded back below the end, and the holding body is hooked,
Has,
The gutter portion includes a standing wall protruding above an upper end of the holding body,
Roof structure. At least a portion of the second main body rests on the upper end of the upright wall,
The roof structure according to claim 1. The first shingle and the second shingle are vertical roofing materials,
The roof structure according to claim 1. The first shingle and the second shingle are horizontal roofing materials,
The direction opposite to the one direction is a water flow direction,
The roof structure according to claim 1. The main body,
A holder connected to one end of the main body in one direction, and folded back above the end;
A gutter portion connected to the holder in the one direction;
A hook that is connected to an end of the main body opposite to the end in the one direction and that is folded back below the end;
With
The gutter portion has a standing wall protruding above an upper end of the holding body,
Shingles.

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