JP7640070B2 - Cover and roof structure - Google Patents

Description

The present invention relates to a cover for covering a roofing material and a roof structure.

For buildings used as residences, etc., there are known techniques that use architectural structures such as wooden frame construction, wooden framework construction, reinforced concrete construction, and the like. In addition, for such buildings, roof structures formed by roofs with flat roof surfaces are known. As such a roof structure, for example, there is known a technique in which multiple plate-shaped roofing materials are fastened to sheathing boards with fastening nails (see, for example, Patent Document 1).

JP 2016-089541 A

The appearance of the above-mentioned roofing materials deteriorates with age. For example, there is a known technology for improving the appearance of the roofing materials by covering them with decorative covers that improve the appearance. Such covers have a top plate, side plates, and bottom plate for covering the top, end, and bottom surfaces of the roofing materials. Furthermore, because a cover is provided for each of the vertically adjacent roofing materials, there is a risk that rainwater will seep into the gaps between the vertically adjacent covers due to pressure head, capillary action, etc.

In addition, the cover is formed with drainage holes to drain any rainwater that has seeped in, but there is a risk that water may seep into the cover through these drainage holes. Rainwater that seeps into the cover then moves through the gap between the cover and the roofing material due to pressure head, capillary action, etc.

The present invention aims to provide a cover for covering roofing materials and a roof structure that can prevent rainwater from entering.

According to one aspect of the present invention, the cover comprises a top plate covering at least a portion of the upper surface of the roofing material which is fastened to the sheathing board, a side plate formed integrally with the top plate and covering the eaves side of the roofing material and having a surface that follows the surface direction of the top plate and an inclination angle set at an acute angle relative to a direction perpendicular to the surface direction of the top plate, and a bottom plate formed integrally with the side plate and having an inclination angle with the side plate set at an acute angle, covering at least a portion of the underside of the roofing material.

According to one aspect of the present invention, a roof structure comprises a sheathing board, roofing materials fastened to the sheathing board and arranged in multiple rows from the ridge of the sheathing board toward the eaves, and arranged along a direction perpendicular to the direction from the ridge toward the eaves, a top plate covering at least a portion of the upper surface of the roofing material, a side plate formed integrally with the top plate and covering the side surface of the roofing material toward the eaves, and having an acute angle inclined relative to a surface along the surface direction of the top plate and a direction perpendicular to the surface direction of the top plate, and a bottom plate formed integrally with the side plate and having an acute angle inclined relative to the side plate, and covering at least a portion of the underside of the roofing material, and being provided across a single roofing material or multiple roofing materials.

The present invention provides a cover for covering roofing materials and a roof structure that can prevent rainwater from entering.

FIG. 1 is a perspective view showing a configuration of a roof structure according to an embodiment of the present invention. FIG. FIG. FIG. FIG. 2 is an enlarged cross-sectional view showing the configuration of the roof structure. FIG. 2 is a perspective view showing the configuration of the roof material, cover, and joints of the roof structure. FIG. FIG. FIG. FIG. FIG. 11 is an explanatory diagram showing an example in which a cover according to a comparative example is used. FIG. 13 is an explanatory diagram showing a schematic diagram of the penetration distance of rainwater into the gap between two inclined boards. An explanatory diagram showing the relationship between two vertically adjacent inclined plate materials and rainwater, as well as the pressure head at the opening of the gap between the two plate materials. FIG. 13 is an explanatory diagram showing the capillary water level in the vertical gap when two plate materials are arranged vertically. FIG. 11 is a perspective view showing a configuration of a joint according to another embodiment. FIG. 11 is a perspective view showing a configuration of a joint according to another embodiment.

The configuration of a roof structure 1 using a cover 150 according to one embodiment will be described below with reference to Figures 1 to 10. In addition, for the purpose of explanation, the configuration is enlarged, reduced, or omitted in each figure as appropriate.

Figure 1 is a perspective view showing the configuration of a roof structure 1 according to one embodiment of the present invention. Figure 2 is a perspective view showing the configuration of the roof structure 1 with a portion of the cover 150 and a portion of the joint 160 omitted, and Figure 3 is a perspective view showing the configuration of the roof structure 1 with a portion of the cover 150 and the joint 160 omitted. Figure 4 is a cross-sectional view showing the configuration of the roof structure 1. Figure 5 is a cross-sectional view showing an enlarged view of the configuration of the roof structure 1.

Figure 6 is a perspective view showing the configuration of the roof material 130, cover 150, and joint 160 of the roof structure 1, showing an example in which one joint 160 is provided on one roof material 130 and two covers 150 are arranged. Figure 7 is a perspective view showing the configuration of the roof material 130 and cover 150, showing an example in which one cover 150 is arranged on one roof material 130. Figure 8 is a perspective view showing an enlarged partial cross section of the configuration of the cover 150 and joint 160. Figure 9 is a perspective view showing the configuration of the cover 150, and Figure 10 is a perspective view showing the configuration of the joint 160.

Next, the roof structure 1 will be described using Figures 1 to 5. The roof structure 1 slopes from the ridge 11 to the eaves 12. The roof structure 1 may have ridges 13, ridge posts, and valleys as appropriate, depending on the shape of the building. Figures 1 to 3 show the configuration of a roof structure 1 with ridges 13 as an example.

As shown in Figures 1 to 5, the roof structure 1 comprises a sheathing board 110, an underlayment 120, a number of roofing materials 130, a number of fastening nails 140, a number of covers 150, joints 160, an eaves edge water drain 170, a gable water drain 180, an end cover 200, and a ridge cover 220. Note that the underlayment 120 is omitted in Figures 1 to 3.

The roof structure 1 may have other components between the sheathing board 110 and the roofing material 130, such as a heat shield sheet or a ventilation material other than the underlayment material 120.

The sheathing board 110 is fastened to the rafters with nails or the like. The sheathing board 110 is formed, for example, from structural plywood. The sheathing board 110 may be MDF (medium density fiberboard), particle board, OSB (oriented strand board), or a single piece of board material such as solid cedar.

The underlayment material 120 is a so-called roofing sheet that has waterproof properties. For example, the underlayment material 120 is formed by impregnating and/or applying asphalt to a base material. The underlayment material 120 is fastened to the sheathing board 110, for example. As a specific example, the underlayment material 120 is provided on the top plate of the sheathing board 110.

The multiple roofing materials 130 are arranged in multiple rows in a first direction, which is the inclination (vertical direction) of the sheathing boards 110 from the ridge 11 toward the eaves 12, and in a second direction, which is the width direction (horizontal direction) perpendicular to or intersecting the first direction. For example, joints 160 are arranged between adjacent roofing materials 130 in the horizontal direction. Note that there may be some locations that are not inclined.

The multiple roofing materials 130 are partially stacked in the direction of an incline from the ridge 11 toward the eaves 12, and are fastened by fastening nails 140 onto the sheathing boards 110 to which the underlayment materials 120 are fastened.

The roofing material 130 is formed in a plate or tile shape. The roofing material 130 has, for example, a plurality of pilot holes 131 at the center in the inclination direction of the sheathing board 110, in a direction perpendicular to the inclination direction. The pilot holes 131 are formed with a smaller diameter than the outer diameter of the head 141 of the fastening nail 140, and a larger diameter than the outer diameter of the nail portion 142 of the fastening nail 140. In other words, the pilot holes 131 are openings through which the nail portions 142 of the fastening nails 140 are inserted.

As shown in FIG. 4, the fastening nails 140 are used in the roof structure 1, for example, to fasten the roof material 130 to the sheathing board 110.

The fastening nails 140 are driven into the sheathing board 110, for example, in the thickness direction of the sheathing board 110, in other words, in a direction perpendicular to the surface direction of the main surface of the sheathing board 110. Note that the driving direction of the fastening nails 140 is not limited to the thickness direction of the sheathing board 110.

The fastening nail 140 has, for example, a head portion 141 and a nail portion 142.

The head 141 is formed in a disk shape.

The nail portion 142 is molded integrally with one of the main surfaces of the head portion 141. The nail portion 142 is formed in a cylindrical shape. The nail portion 142 also has, for example, a plurality of ring-shaped protrusions 142a formed at equal intervals in the axial direction (longitudinal direction) of the nail portion 142.

The multiple protrusions 142a improve the fastening force that fastens the roofing material 130 to the sheathing board 110 when the fastening nail 140 is driven into the sheathing board 110. In other words, the multiple protrusions 142a improve the tensile strength, which is the holding force in the direction in which the fastening nail 140 is pulled out of the sheathing board 110 when it is driven into the sheathing board 110. The multiple protrusions 142a are provided at least in the area that is arranged in the sheathing board 110, for example, so that the fastening force between the sheathing board 110 and the roofing material 130 can be improved. The number and shape of the protrusions 142a can be set appropriately as long as the fastening force can be improved.

As shown in Figures 4 and 5, the cover 150 covers one or more of the multiple roofing materials 130 (multiple roofing materials 130 arranged in the width direction) that are at the same height. For example, the cover 150 is a decorative cover that improves the appearance of the roofing material 130 by covering it when the appearance of the roofing material 130 is reduced due to aging or the like. In this embodiment, the cover 150 does not cover the roofing material 130 located at the eaves 12, and a configuration is described in which the end cover 200 covers the roofing material 130 located at the eaves 12 as shown in Figure 4.

As shown in Figs. 5 to 9, the cover 150 includes a top plate 151, a side plate 152, and a bottom plate 153. The cover 150 is formed by, for example, bending a steel plate, so that the top plate 151, the side plate 152, and the bottom plate 153 are integrally formed. In addition, the cover 150 has a plurality of rectangular drain holes 154 formed at the ridge between the side plate 152 and the bottom plate 153, or on the bottom plate 153 side of the side plate 152. The cover 150 is water-resistant and weather-resistant, and is painted or the like to obtain a beautiful appearance. The cover 150 is, for example, bonded to one or more roof materials 130 with an adhesive. Note that the cover 150 adjacent to each other in the vertical direction may be bonded to each other with an adhesive.

The top plate 151 covers at least the area of the upper surface of the roofing material 130 that is exposed to the outside. The width dimension of the top plate 151 is set to be larger than the width dimension of one roofing material 130. The depth dimension of the top plate 151 is set to be the same as or slightly smaller than the depth dimension of one roofing material 130. Specifically, the depth dimension of the top plate 151 can be set appropriately as long as the ridge side end of the top plate 151 is covered by the upper roofing material 130 when the cover 150 is placed on the lower roofing material 130 among the roofing materials 130 stacked in the inclined direction from the ridge 11 to the eaves 12. Note that here, the depth means the direction from the underwater (eaves 12) side to the abovewater (ridge 11) side in the roof structure 1.

The side panel 152 is integrally continuous with the top panel 151 and the bottom panel 153. The side panel 152 covers the side surface of the roof material 130 on the eaves 12 side. The width dimension of the side panel 152 is set to, for example, the same dimension as the width dimension of the top panel 151. The side panel 152 is arranged on the eaves 12 side of the top panel 151. The side panel 152 is inclined at an acute angle, for example, 45°, with respect to the surface along the surface direction of the top panel 151 and the direction perpendicular to the top panel 151 so that the bottom panel 153 side is closer to the eaves 12 side than the top panel 151 side.

In other words, the side plate 152 is inclined at an obtuse angle, for example 135°, with respect to the lower surface of the top plate 151 (the main inner surface of the cover 150). Note that the surface along the surface direction of the top plate 151 here refers to an imaginary plane F that extends along the surface direction of the top plate 151 from the end of the top plate 151 on the side plate 152 side, as shown in FIG. 5.

The bottom plate 153 is set parallel or nearly parallel to the top plate 151. Therefore, the inclination angle of the side plate 152 with respect to the bottom plate 153 is set to an acute angle, for example, 45°. The bottom plate 153 covers at least the underside of the roof material 130 on the eaves 12 side. The distance between the top plate 151 and the bottom plate 153 is set to a distance at which the roof material 130 can be arranged. The width dimension of the bottom plate 153 is set to the same dimension as the width dimension of the top plate 151. The depth dimension of the bottom plate 153 is set to be shorter than the depth dimension of the top plate 151. More specifically, the depth dimension of the bottom plate 153 is set to a dimension that is closer to the eaves side than the ridge side end of the top plate 151 of the cover 150 attached to the lower roof material 130. The bottom plate 153 may have a folded portion at the edge opposite to the side plate 152, where the plate material is folded back to form a double structure.

The drainage holes 154 are provided at multiple locations in the width direction of the cover 150. The drainage holes 154 are holes that drain water that has entered the cover 150.

As shown in FIG. 6, the joint 160 is provided between adjacent covers 150 in the width direction. As shown in FIGS. 2, 3, 6 to 8, and 10, the joint 160 is disposed above the roof material 130 and below the cover 150. As shown in FIGS. 8 and 10, the joint 160 includes, for example, a top plate 161 and a side plate 162. The top plate 161 faces the end of the top plate 151 of the adjacent cover 150 in the width direction. The side plate 162 faces the end of the side plate 152 of the adjacent cover 150.

The dimension of the side panel 162 in a direction perpendicular to the width direction is set smaller than the same dimension of the side panel 152 of the cover 150. Preferably, the side panel 162 is set to a dimension that does not overlap with the drainage hole 154 of the cover 150 in the inclined direction from the ridge 11 toward the eaves 12.

For example, the angle of the side plate 162 relative to the top plate 161 of the joint 160 is set to an angle different from the angle of the side plate 152 relative to the top plate 151 of the cover 150. In this embodiment, when the angle of the side plate 152 relative to the top plate 151 of the cover 150 is 135° (the angle of the side plate 152 relative to the imaginary plane F along the surface direction of the top plate 151 is 45°), for example, the angle of the side plate 162 relative to the top plate 161 of the joint 160 is set to 90°.

The eaves edge water drain 170 is provided, for example, along the width direction (second direction) of the eaves edge 12. The eaves edge water drain 170 has, for example, a base 171 arranged between the sheathing board 110 and the underlayment material 120 at the eaves edge 12, and a water drain board 172 hanging downward from the end of the base 171 on the eaves edge 12 side. The water drain board 172 has a return portion on the sheathing board 110 side of the lower end.

The gable skirting 180 is arranged, for example, on each gable 13. The gable skirting 180 is fastened to the sheathing board 110, for example, via a coping. The gable skirting 180 has a skirting board that hangs downward from the gable 13.

As shown in FIG. 4, the end cover 200 covers the roofing material 130 arranged at the eaves 12. For example, as shown in FIG. 4, two roofing materials 130 are arranged at the eaves 12 in a stacked manner, so the end cover 200 covers two roofing materials 130. In addition, the end cover 200 covers one or more sets of stacked roofing materials 130 out of the multiple stacked roofing materials 130 arranged in the width direction at the eaves 12.

For example, the end cover 200 is a decorative cover that improves the appearance of the roof material 130 by covering it when the appearance of the roof material 130 deteriorates due to aging or the like.

As shown in FIG. 4, the end cover 200 includes a top plate 201, a side plate 202, and a bottom plate 203. The end cover 200 is formed by, for example, bending a steel plate, with the top plate 151, the side plate 202, and the bottom plate 203 integrally formed. The end cover 200 may also have one or more rectangular drain holes formed at the ridge between the side plate 202 and the bottom plate 203, or on the bottom plate 203 side of the side plate 202. The end cover 200 is water-resistant and weather-resistant, and is painted or the like to obtain a beautiful appearance. The end cover 200 is, for example, bonded to one or more roof materials 130 with an adhesive. Note that the cover 150 and the end cover 200 adjacent in the vertical direction may be bonded with an adhesive.

The ridge liner 220 is provided on the ridge 11. The ridge liner 220 covers, for example, the ridge 11 and the end of the roofing material 130 arranged on the ridge 11 on the ridge 11 side. For example, the ridge liner 220 is fastened to the sheathing board 110 via a coping.

According to the cover 150 configured in this manner and the roof structure 1 using the cover 150, if the roof material 130 deteriorates or its appearance deteriorates due to aging or other reasons, the appearance can be improved by covering the roof material 130 with the cover 150.

The side panels 152 are inclined at an acute angle with respect to the surface along the surface direction of the top panel 151 and the direction perpendicular to the top panel 151 so that the bottom panel 153 side is closer to the eaves 12 than the top panel 151 side. Therefore, rainwater on the cover 150 flows in a direction along the inclination direction of the top panel 151 of the cover 150 and also flows along the inclination direction of the side panels 152.

In addition, the top plate 151 and the side plate 152 are inclined downward toward the eaves side in a direction perpendicular to the surface direction of the top plate 151. That is, the side plate 152 is inclined at an acute angle to the surface (imaginary plane F, bottom plate 153) along the surface direction of the top plate 151. Therefore, the cover 150 can suppress the occurrence of edge beads on the edge of the side plate 152 side of the top plate 151. In particular, by setting the inclination angle of the side plate 152 to the bottom plate 153 at 45°, the occurrence of edge beads can be prevented. Therefore, it is possible to suppress rainwater from penetrating between the covers 150 of the stacked roof materials 130 and from flowing back upward between the top plate 151 and the bottom plate 153 of the stacked covers 150.

Next, the effects of the cover 150 of this embodiment will be described in detail in comparison with the cover 150A of the comparative example. As shown in FIG. 11, the cover 150A of the comparative example is configured such that the side plate 152A extends in a direction perpendicular to the surface direction of the top plate 151, but the other configurations are the same as those of the cover 150 of this embodiment.

First, an example of rainwater 500 flowing on the cover 150A of the comparative example will be described. As shown in FIG. 11, when rainwater 500 flows over the cover 150A during rainfall, an edge bead 510 is generated in the flowing rainwater 500 at the edge of the side plate 152A side of the top plate 151 of the cover 150A (the edge on the end side of the roof material 130). Then, when a certain amount of edge bead 510 accumulates at the edge of the side plate 152A side of the top plate 151, it flows downward, so that the rainwater 500 flowing down from the top plate 151 is subjected to a pressure head, and between the top plate 151 and the bottom plate 153 of the adjacent covers 150A, the water is pushed up between the bottom plate 153 and the underside of the roof material 130 by the water that is the amount of water sucked up by capillary action and the amount of water by the pressure head including the edge bead 510.

When rainwater 500 moves along the side plate 152A and onto the top plate 151 of the lower cover 150A, the water branches off and moves so as to spread in the surface direction of the top plate 151, as shown by the arrows in FIG. 11. Therefore, some of the rainwater 500 flows over the top plate 151 of the lower cover 150A, but the other part of the rainwater 500 gets into the gap between the top plate 151 and the bottom plate 153 of the cover 150A, which overlap in the vertical direction. In addition, in the drainage hole 154, the water is pushed up between the bottom plate 153 and the underside of the roof material 130 by the water volume that is sucked up by capillary action and the water volume due to the pressure head including the edge bead 510.

This point will be explained in more detail with reference to Figs. 12 to 14. Figs. 12 and 13 are explanatory diagrams showing the relationship between two inclined plate materials 600 that are adjacent to each other in the vertical direction, similar to roof material 130 and cover 150A, and rainwater 500. The penetration distance LT of rainwater 500 that penetrates the gap between two inclined plate materials 600 shown in Fig. 12 is expressed by the following mathematical formula (1).

Here, Ls is the penetration distance of the rainwater 500 due to the pressure head of the flow layer, Lc is the penetration distance of the rainwater 500 due to the capillary action of the gap, and Lw is the penetration distance of the rainwater 500 due to the action of wind pressure.

And Ls is expressed by formula (2).

Here, Hs is the pressure head at the gap opening between two vertically adjacent inclined plate materials 600, and is expressed by mathematical formula (3). As shown in Fig. 13, the pressure at point 1, which is the upper end position of the rainwater 500 at the lower end edge of the upper surface of the plate material 600, is _P1 , the velocity is _v1 , and the position is _h1 . Also, the pressure at point 2, which is the center position in the height direction of the gap opening between two vertically adjacent plate materials 600, is _P2 , the velocity is _v2 , and the position is _h2 . Also, the density of water is ρ, and the gravitational acceleration is g.

Furthermore, as is clear from equation (3), when an edge bead 510 is formed on the edge of the upper plate material 600, the pressure head Hs at point 2 increases.

Lc is expressed by formula (4).

Here, Hc is the capillary water level in the vertical gap when two plates 600 are arranged vertically with a gap between them, as shown in Figure 14.

Lw is expressed by formula (5).

As shown in FIG. 12, ΔP can be calculated by P0=Pi+ΔP, where P0 is the atmospheric pressure and Pi is the pressure inside the plate material 600, in other words, the pressure inside the roof material 130 within the roof structure 1.

The above-mentioned formulas (1) to (5) can be used to calculate the rainwater infiltration distance in the gap between adjacent plate materials 600 in the vertical direction, such as roof material 130 and cover 150A. As is clear from these formulas, they can be applied to calculate the rainwater infiltration distance in the gap between two members, such as roof material 130 and cover 150A, that are adjacent in the vertical direction, inclined, and have a gap.

As is clear from the above formula, it can be seen that rainwater 500 is pushed up by capillary action, pressure head, etc. between the top plate 151 and bottom plate 153 of the vertically adjacent covers 150A, and between the underside of the roof material 130 and the bottom plate 153 of the cover 150A. Therefore, as described above, when the cover 150A of the comparative example is used, water is pushed up between the bottom plate 153 and the underside of the roof material 130 by the water amount that is obtained by adding the water amount due to the pressure head including the edge bead 510 to the water amount sucked up by capillary action.

In contrast, in the case of the cover 150 of this embodiment, the side plate 152 is inclined at an acute angle to the surface along the surface direction of the top plate 151 and to the direction perpendicular to the top plate 151, in other words, at an acute angle to the bottom plate 153 parallel to the top plate 151. In addition, the inclination angle of the side plate 152 to the surface along the surface direction of the top plate 151 and to the direction perpendicular to the top plate 151 (to the bottom plate 153) is preferably set to about 45°.

By using such a cover 150, the generation of edge beads 510 can be prevented, and the pressure head is reduced. In addition, the flow velocity increases at the side plate 152 as the rainwater 500 flows downward. Moreover, the inclination of the side plate 152 guides the flow direction of the rainwater 500 to flow downward.

Therefore, the rainwater 500 that flows through the cover 150 and is near the gap openings and drain holes 154 of the top plate 151 and bottom plate 153 of the adjacent cover 150 is not subjected to an upward pressure head, or the pressure head is small, so the rainwater 500 is unlikely to infiltrate through the gap openings and drain holes 154. Even if the rainwater 500 infiltrates through the drain holes 154, the infiltrating rainwater 500 is pulled by the rainwater 500 flowing downward and is discharged from the drain holes 154. In addition, even if the rainwater infiltrates through the gap openings and drain holes 154, the edge bead 510 is not generated, so the infiltration distance Ls due to the pressure head of the flow layer is small.

As described above, by using the cover 150 of this embodiment, rainwater 500 can be prevented from entering between adjacent covers 150 vertically or between the roof material 130 and the bottom plate 153 of the cover 150 due to pressure head or capillary action, even when compared to the cover 150A of the comparative example.

As described above, with the cover 150 and roof structure 1 according to this embodiment, the side panels 152 are inclined relative to the surface direction of the top panel 151 and in a direction perpendicular to the surface direction, thereby preventing rainwater from entering.

The present invention is not limited to the above-described embodiment. For example, in the above example, the inclination angle of the side plate 152 of the cover 150 relative to the top plate 151 is 135° (the inclination angle relative to the imaginary plane F extending in the surface direction of the top plate 151 is 45°), but the present invention is not limited to this. For example, the inclination angle relative to the imaginary plane F extending in the surface direction of the top plate 151 not only includes errors due to molding, but can also be set to, for example, 30°, 60°, etc.

In other words, the inclination angle of the side plate 152 relative to the top plate 151 of the cover 150 can be set appropriately as long as it is an inclination angle that does not cause an edge bead 510 to form on the edge of the side plate 152 side of the top plate 151 or, if it does form, is small, and/or the flowing rainwater 500 is guided downward and does not move upward or the movement can be suppressed.

This is because, in addition to guiding the flow of rainwater 500 downward, if the edge bead 510 can be reduced, the pressure head can be reduced, and if the upward movement of rainwater 500 can be prevented, the infiltration of rainwater into the gaps between the covers 150 and between the roof material 130 and the cover 150 can be prevented, and as a result, the infiltration distance LT of rainwater 500 into the gaps can be reduced.

In the above example, the cover 150 is provided with drainage holes 154, but the number, size, position, etc. of the drainage holes 154 can be set as appropriate.

In the above example, the joint 160 has an angle of 90° between the side plate 162 and the top plate 161, but is not limited to this. For example, as shown in FIG. 15, the joint 160 may have an obtuse angle between the side plate 162 and the top plate 161. As shown in FIG. 16, the joint 160 may be formed of a corrugated sheet and be uneven in the width direction. For example, by making the joint 160 uneven in this way, the drainage of rainwater 500 is promoted, and a space is created between the roof material 130 and the cover 150, which promotes evaporation of the rainwater 500.

In the above example, the drainage holes 154 are described as being provided across the side plate 152 and the bottom plate 153, but this is not limited thereto, and the drainage holes 154 may be provided in either the side plate 152 or the bottom plate 153. In this case, the drainage holes 154 are provided in the lowest position of the side plate 152 or the bottom plate 153 when the cover 150 is provided on the roof material 130.

The present invention is not limited to the above-mentioned embodiment, and can be modified in various ways without departing from the gist of the present invention. The embodiments may be combined as appropriate, and in that case, the combined effect can be obtained. Furthermore, the above-mentioned embodiment includes various inventions, and various inventions can be extracted by combinations selected from the multiple components disclosed. For example, if the problem can be solved and the effect can be obtained even if some components are deleted from all the components shown in the embodiment, the configuration from which the components are deleted can be extracted as an invention.
The following provides a description equivalent to the invention described in the original claims of this application.
[1] A top plate covering at least a portion of the upper surface of the roof material fastened to the sheathing board;
A side panel formed integrally with the top plate, covering the side surface of the roof material on the eaves side, and having an acute inclination angle with respect to a surface along the surface direction of the top plate and a direction perpendicular to the surface direction of the top plate;
A bottom plate formed integrally with the side plate and covering at least a portion of the lower surface of the roof material;
A cover comprising:
[2] The cover according to [1], wherein the cover has a drainage hole formed in a part of the side panel.
[3] The cover according to [1] or [2], wherein the inclination angle of the side panel with respect to the surface along the surface direction of the top plate and the direction perpendicular to the surface direction of the top plate is set to 45°.
[4] A subfloor board;
A plurality of roofing materials are fastened to the sheathing board, arranged from the ridge of the sheathing board toward the eaves, and arranged along a direction perpendicular to the direction from the ridge toward the eaves;
a top plate covering at least a portion of the upper surface of the roofing material; a side plate formed integrally with the top plate, covering the side surface of the roofing material on the eaves side, and having an acute inclination angle with respect to a surface along the surface direction of the top plate and a direction perpendicular to the surface direction of the top plate; and a bottom plate formed integrally with the side plate, covering at least a portion of the underside of the roofing material, and provided across a single roofing material or multiple roofing materials;
A roof structure comprising:
[5] The roof structure described in [4], wherein the cover has a drain hole formed in a part of the side panel.
[6] A roof structure as described in [4] or [5], wherein the inclination angle of the side panel relative to the surface along the surface direction of the top plate and the direction perpendicular to the surface direction of the top plate is set to 45°.

1...roof structure, 11...ridge, 12...eaves, 13...gables, 110...substrate, 120...underlaying material, 130...roofing material, 131...pilot hole, 140...fastening nail, 141...head, 142...nail portion, 142a...protrusion, 150...cover (embodiment), 150A...cover (comparative example), 151...top plate, 152...side plate, 153...bottom plate, 154...drainage hole, 160...joint, 161...top plate, 162...side plate, 170...eaves drain, 171...base, 172...drain board, 180...gables drain, 200...end cover, 220...ridge cover, 500...rainwater, 510...edge bead, 600...board material, F...virtual plane.

Claims (6)

A top plate covering at least a portion of the upper surface of the roof material fastened to the sheathing board;
A side panel formed integrally with the top plate, covering the side surface of the roof material on the eaves side, and having an acute inclination angle with respect to a surface along the surface direction of the top plate and a direction perpendicular to the surface direction of the top plate;
A bottom plate that is integral with the side plate and has an acute inclination angle with the side plate, and covers at least a portion of the lower surface of the roof material;
A cover comprising: The cover according to claim 1, wherein the cover has a drain hole formed in a part of the side plate. The cover according to claim 1 or 2, in which the inclination angle of the side panels relative to the surface along the surface direction of the top panel and the direction perpendicular to the surface direction of the top panel is set to 45°. Subfloor boards and
A plurality of roofing materials are fastened to the sheathing board, arranged from the ridge of the sheathing board toward the eaves, and arranged along a direction perpendicular to the direction from the ridge toward the eaves;
a top plate covering at least a portion of the upper surface of the roofing material; a side plate formed integrally with the top plate, covering the side surface of the roofing material on the eaves side, and having an acute inclination angle with respect to a surface along the surface direction of the top plate and a direction perpendicular to the surface direction of the top plate; and a bottom plate formed integrally with the side plate, having an acute inclination angle with respect to the side plate, covering at least a portion of the lower surface of the roofing material, and being provided across a single roofing material or multiple roofing materials;
A roof structure comprising: The roof structure according to claim 4, wherein the cover has a drain hole formed in a part of the side panel. The roof structure according to claim 4 or 5, in which the inclination angle of the side panels relative to the surface along the surface direction of the top panel and the direction perpendicular to the surface direction of the top panel is set to 45°.