JP7004447B2 - Connection structure of vertical thatched roof material and vertical thatched material - Google Patents

Description

The present invention relates to a connecting structure of a vertical thatched roof material and a vertical thatched material.

Patent Document 1 discloses a connection structure of a conventional vertical roofing material. The roof structure of the vertical roofing material described in Patent Document 1 includes a face plate portion and a polymerized portion raised from both ends in the width direction of the face plate portion. The vertically adjacent vertical roofing materials are connected by superimposing the overlapping portion (upper polymerization part) of the adjacent vertical roofing material on the polymerization part (lower polymerization part) of one of the vertical roofing materials. ..

Japanese Patent Application Laid-Open No. 2003-184230

By the way, in this conventional connection structure of a vertical roofing material, the tip of the upper polymerized portion is in close contact with the upper surface of the lower polymerized portion. Therefore, due to the capillary phenomenon, when rainwater is sucked from between the tip of the upper polymerized portion and the upper surface of the lower polymerized portion, the rainwater may sneak around to the back side of the vertical roofing material.

The present invention has been made in view of the above circumstances, and an object thereof is a connection structure of a vertical roofing material capable of suppressing infiltration of rainwater at a connecting portion of vertically adjacent vertical roofing materials in the lateral direction and a connection structure of the vertical roofing material. It is to provide vertical roofing material.

In the connection structure of the vertical thatched roofing material of the present invention, each of the pair of vertical thatched roofing materials connected in the horizontal direction is erected on a flat surface portion extending in the eaves direction and both ends in the horizontal direction of the flat surface portion. It is a connection structure of a vertical thatched roofing material having a pair of rising portions, and is provided on at least one of the pair of vertical thatched roofing materials and a fitting portion provided on the other of the pair of vertical thatched roofing materials. The fitted portion is provided with a fitted portion that covers the fitting portion from above and is fitted to the fitting portion, and the fitted portion has a pressure contact piece that presses against the flat surface portion. do.

The vertical thatched roof material of the present invention is a vertical thatched roofing material used for a connecting structure of a vertical thatched roofing material in which a plurality of vertical thatched roofing materials are arranged adjacent to each other in the horizontal direction, and is formed along the eaves building direction and horizontally. It is characterized by having the ridge that protrudes toward the flat surface portion of another vertical roofing material adjacent to the direction and presses against the flat surface portion.

According to the connection structure of the vertical roofing material and the vertical roofing material of the present invention, it is possible to suppress the infiltration of rainwater at the connecting portion of the vertical thatched roofing materials adjacent to each other in the horizontal direction.

FIG. 1 is a perspective view of a connection structure of a vertical roofing material according to an embodiment of the present invention. FIG. 2A is an exploded perspective view of the same vertical roofing material. FIG. 2B is a cross-sectional view of a portion B of FIG. 2A. FIG. 3 is a cross-sectional view taken along the line AA of FIG. 2A. FIG. 4 is a cross-sectional perspective view of the portion taken along line AA of FIG. 2A in a state where the eave-side vertical roofing material and the ridge-side vertical roofing material are connected. FIG. 5A is a cross-sectional view of the end portion of the vertical roofing material of the modified example 1 on the ridge side. FIG. 5B is a cross-sectional view of the end portion of the vertical roofing material of the modified example 2 on the ridge side. FIG. 6A is an exploded perspective view of the connection structure of the vertical roofing material according to the embodiment of the present invention. FIG. 6B is a vertical cross-sectional view of the thatched roofing material in FIG. 6A. FIG. 7A is a perspective view of a main part immediately before the eave-side vertical roofing material and the ridge-side vertical roofing material are connected to each other. FIG. 7B is a perspective view of a main part in a state where the eave-side vertical roofing material and the ridge-side vertical roofing material are connected. FIG. 8A is a cross-sectional view showing a lateral connection portion of the same vertical roofing material. FIG. 8B is a cross-sectional view at a position different from that of FIG. 8A at the lateral connection portion of the vertical roofing material of the same as above. FIG. 9A is a perspective view of a main part of the vertical roofing material of the modified example of the above embodiment. 9B is a cross-sectional view of a main part of FIG. 9A. FIG. 10 is a reference cross-sectional view showing a lateral connection structure of a general vertical roofing material connection structure.

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

As shown in FIG. 1, the vertical thatched roof structure of the present embodiment is a roof structure in which a metal vertical roofing material 2 is laid on a roof base 1. The vertical thatched roof structure includes a roof base 1 and a plurality of vertical thatched roofing materials 2 installed so as to be arranged in the horizontal direction. Further, each of the plurality of vertically-roofed roofing materials 2 arranged in the horizontal direction includes a plurality of vertically-thatched roofing materials 3 vertically joined in the direction of the eaves.

Here, the "eave-building direction" means a direction along the roof slope, and is a direction parallel to the so-called water flow direction. Further, the "horizontal direction" means a direction on the horizontal plane among the directions orthogonal to the eaves building direction, and corresponds to the girder direction in the present embodiment.

The roof base 1 is a portion that serves as a base for the vertical roofing material 2. The vertical roof structure of the present embodiment is made of a steel frame structure, and the roof base 1 includes a plurality of horizontal members 11, a field board 12, and a lower roof material 13.

The plurality of horizontal members 11 are structural materials that are bridged along the horizontal direction, and are composed of, for example, a purlin, a beam, a girder, and the like. Each horizontal member 11 extends in the lateral direction. The plurality of horizontal lumbers 11 are arranged at a constant pitch in the direction of the eaves building, and are arranged so as to be located above the horizontal lumbers 11 on the ridge side.

The field board 12 is arranged above the plurality of horizontal members 11. The field board 12 is composed of, for example, a sandwich panel in which a core material such as a resin foam material is sandwiched between metal plates, a wood board, or the like. The field board 12 is arranged over the entire surface of the portion corresponding to the roof surface.

The underlaying material 13 is waterproof and prevents water from entering the indoor side. The underlaying material 13 is laid over the entire surface of the field board 12. The under-roofing material 13 is composed of, for example, a waterproof sheet such as asphalt roofing or modified rubber asphalt roofing.

For example, when the building is made of wood, the roof base 1 includes a plurality of rafters that support the field board 12 from below. The plurality of rafters are arranged in the longitudinal direction parallel to the eaves building direction, and are arranged at regular intervals in the lateral direction, and are arranged between the field board 12 and the horizontal member (main building). ..

The plurality of vertically-roofed roofing materials 2 are laid on the roof base 1. Each vertical roofing material 2 is continuous over the entire length in the direction of the eaves. The plurality of vertical roofing materials 2 are installed side by side in the horizontal direction. In the present embodiment, each of the plurality of vertical roofing materials 2 has the same structure, and the vertically adjacent vertical roofing materials 2 that are adjacent to each other in the lateral direction are all connected by the same structure. Therefore, in the following, the adjacent vertical thatched roofing materials 2 are referred to as a first vertical thatched roofing material 2a and a second vertical thatched roofing material 2b, and these first vertical thatched roofing material 2a and a second vertical thatched roofing material 2a. The roofing material 2b will be mainly described.

Each vertical roofing material 2 is configured by vertically joining a plurality of vertical roofing materials 3 in the direction of the eaves. Each of the plurality of vertical roofing materials 3 is formed to, for example, 1.0 to 4.0 m, and is excellent in portability. The ends of the vertical roofing members 3 adjacent to each other in the direction of the eaves building are not only overlapped with each other, but are connected to each other as described below.

In the present embodiment, each vertical roofing material 2 is composed of three or more vertical roofing materials 3, but all of them are composed of the vertical thatched material 3 having the same structure. Therefore, in the explanation of the vertical joint structure, among the vertical roofing materials 3 adjacent to each other in the eaves building direction, the vertical roofing material 3 arranged on the eaves side is referred to as the eaves side vertical roofing material 3a, and the vertical roofing material 3a on the eaves side is used on the ridge side. The adjacent vertical roofing material 3 will be described as a ridge-side vertical roofing material 3b.

[Vertical joint structure]
Each vertical roofing material 3 is formed by bending a metal plate, and is molded by, for example, using roll forming. The metal plate constituting the vertical roofing material 3 is composed of, for example, a painted steel plate, a galvanized steel plate, a stainless steel plate, a galvalume steel plate (registered trademark), SGL (registered trademark), or the like. As shown in FIG. 2, the vertical roofing material 3 includes a main body portion 31, a lower folded portion 45, and an upper folded portion 46.

The main body portion 31 is a portion constituting the main body of the vertical roofing material 3. The main body portion 31 extends in the eaves building direction, and is formed in a substantially rectangular shape in a plan view whose longitudinal direction is parallel to the eaves building direction. The main body portion 31 includes a flat surface portion 32 and a pair of rising portions 33.

The flat surface portion 32 is a portion formed in a flat shape, and is installed so as to be placed on the roof base 1. The plane portion 32 has a longitudinal direction parallel to the eaves building direction and a width direction parallel to the lateral direction. The flat surface portion 32 constitutes a flow path through which rainwater flows in a state where a plurality of vertical roofing materials 3 are installed on the roof base 1.

The pair of rising portions 33 are raised from both ends in the width direction of the flat surface portion 32. Each rising portion 33 is formed parallel to the longitudinal direction of the flat surface portion 32. Of the pair of rising portions 33, one rising portion 33 constitutes the fitting portion 34, and the other rising portion 33 constitutes the fitted portion 37. The vertical roofing members 3 adjacent to each other in the lateral direction are connected by fitting the fitting portion 34 and the fitted portion 37. The connecting structure between the vertical roofing materials 3 adjacent to each other in the horizontal direction will be described in detail in [Connecting structure in the horizontal direction] described later.

An eaves-side notch 43 is formed at the eaves-side end of the fitting portion 34. The eaves-side notch 43 is configured by notching the end of the fitting portion 34 on the eaves side in the longitudinal direction. Further, a ridge-side notch 44 is formed at the ridge-side end of the fitted portion 37. The ridge-side notch 44 is configured by notching the ridge-side end of the fitted portion 37 in the longitudinal direction. As described above, the vertical roofing material 3 of the present embodiment is provided with the eaves side notch 43 and the ridge side notch 44, so that the vertical roofing material 3 can be stacked and waterproofed when the vertical roofing material 3 is vertically joined in the eaves direction. It is possible to improve the sex.

Here, when the eaves side notch 43 and the ridge side notch 44 are not provided, if the vertical roofing material 3 is vertically joined in the direction of the eaves, the bent parts overlap each other, so that there is a gap. Is likely to occur. On the other hand, the vertical roofing material 3 of the present embodiment is provided with the eaves-side notch 43 and the ridge-side notch 44, so that the number of overlapping bending-processed portions can be reduced and the occurrence of gaps is suppressed. can do.

The lower folded portion 45 extends from the end of the flat surface portion 32 on the eave side to the ridge side, and overlaps the lower side of the flat surface portion 32. That is, the lower folded portion 45 is folded back toward the ridge on the lower side of the flat surface portion 32. The lower folded portion 45 is inclined so that both sides in the lateral direction are located closer to the center side in the lateral direction toward the ridge side, whereby the lower folded portion 45 is formed to be narrower toward the ridge side. .. The lower folded portion 45 is formed only on the flat surface portion 32, and is not formed on the rising portion 33.

Further, as shown in FIG. 4, the tip portion 451 of the lower folded portion 45 is bent upward at the base end and is inclined so as to approach the flat surface portion 32 toward the tip end. As a result, when the lower folding portion 45 is inserted between the upper folding portion 46 and the flat surface portion 32, the edge of the tip portion 451 of the lower folding portion 45 is rubbed against the flat surface portion 32, and the flat surface portion 32 is scratched. It can be prevented from sticking.

As shown in FIG. 2, the upper folded portion 46 extends from the end portion of the flat surface portion 32 on the ridge side to the eaves side, and overlaps the flat surface portion 32 above. That is, the upper folded portion 46 is folded back toward the eaves on the upper side of the flat surface portion 32. The length of the upper folding portion 46 in the eaves direction is longer than the length of the lower folding portion 45 in the eaves direction.

The upper folded portion 46 is inclined so that the side of the end portion on the fitted portion 37 side of the lateral end portions of the upper folded portion 46 is located toward the center side in the lateral direction toward the eaves side. The upper folded portion 46 is formed to be narrower toward the eaves side. Further, as shown in FIG. 2B, the upper folded portion 46 has an upright piece 47 extending upward from the end portion on the fitting portion 34 side among the lateral ends of the upper folded portion 46. There is. The erection piece 47 is formed along the fitting portion 34, and the ridge-side end portion of the erection piece 47 is integrally formed with the ridge-side end portion of the fitting portion 34 by bending. .. Therefore, even if the rainwater that has entered between the flat surface portion 32 and the upper folded portion 46 moves to the standing piece 47 side, the standing piece 47 and the fitting portion 34 are connected to each other, so that the roof base 1 It can prevent leakage to the side. Further, since the upper folded portion 46 is formed to be narrower toward the eaves side, the lower folded portion 45 can be easily inserted between the upper folded portion 46 and the flat surface portion 32.

The ridge-side vertical roofing material 3b is arranged so that the eave-side vertical roofing material 3a overlaps the ridge-side end of the eaves-side vertical roofing material 3a from above. At this time, the lower folding portion 45 of the ridge-side vertical roofing material 3b is locked to the upper folding portion 46 of the eaves-side vertical roofing material 3a. As a result, the eaves-side end of the ridge-side vertical roofing material 3b in the installed state is interconnected with the ridge-side end of the eaves-side vertical roofing material 3a.

Further, in the vertical roofing material 3 of the present embodiment, protrusions 48 are provided on both the ridge-side end of the main body 31 and the upper folded portion 46. The protrusion 48 is composed of a plurality of protrusions 49 extending in the lateral direction, and prevents the flat surface portion 32 of the main body portion 31 and the upper folded portion 46 from being in close contact with each other in a planar manner.

FIG. 3 shows a cross section taken along line AA in FIG. As shown in FIG. 3, a lower ridge 492 as a ridge 49 is provided at a portion of the main body 31 on the ridge side that overlaps the upper folded portion 46 in a plan view (hereinafter referred to as a covering region 9). The upper ridge 46 is provided with an upper ridge 491 as a ridge 49. The lower protrusion 492 projects toward the upper folded portion 46. The apex of the lower ridge 492 is in contact with or away from the upper folded portion 46, that is, is opposed to the upper folded portion 46. Further, the upper protrusion 491 projects toward the flat surface portion 32. The apex of the upper ridge 491 is in contact with or separated from the flat surface portion 32, that is, is opposed to the upper folded portion 46. The upper ridge 491 is arranged on the ridge side of the lower ridge 492, and is formed at a position away from the lower ridge 492.

By providing the upper protrusion 491 and the lower protrusion 492, it is possible to prevent the flat surface portion 32 and the upper folded portion 46 from coming into contact with each other in a planar manner, and the flat surface portion 32 and the upper folded portion 46 Can be prevented from coming into close contact with each other. As a result, it is possible to suppress the drawing of rainwater between the flat surface portion 32 and the upper folded portion 46 due to the capillary phenomenon that occurs between the flat surface portion 32 and the upper folded portion 46, and the lower folded portion 45 during construction. Can be improved in workability when the flat surface portion 32 and the upper folded portion 46 are inserted.

The reference numeral 71 in the figure is a ridge portion 71 as a third water stop portion 7 described later, and will be described in detail in [Drainage structure] described later.

When the eaves-side end of the ridge-side vertical roofing material 3b is connected to the ridge-side end of the eaves-side vertical roofing material 3a, as shown in FIG. 4, the tip of the lower folded portion 45 of the ridge-side vertical roofing material 3b is connected. Contact the lower ridge 492. As a result, the ridge-side vertical roofing material 3b can be positioned when it is arranged with respect to the eaves-side vertical roofing material 3a, and the ridge-side vertical roofing material 3b can be arranged at an appropriate position. The tip of the lower folded portion 45 of the ridge-side vertical roofing material 3b and the lower protrusion 492 do not have to be in contact with each other.

The portion where the protrusion 49 is provided as the protrusion 48 may be, for example, the position shown in FIGS. 5A and 5B. Hereinafter, the embodiment shown in FIG. 5A is referred to as a modification 1 and the embodiment shown in FIG. 5B is referred to as a modification 2.

As shown in FIG. 5A, the ridge 49 of the first modification is composed of an upper ridge 491 protruding from the upper folded portion 46 toward the flat surface portion 32. That is, the protrusion 48 of the vertical roofing material 3 of the modified example 1 is composed of the ridge 49 provided in the upper folded portion 46.

As shown in FIG. 5B, the ridge 49 of the modified example 2 is composed of a lower ridge 492 protruding from the flat surface portion 32 toward the upper folded portion 46. That is, the protrusion 48 of the vertical roofing material 3 of the modification 2 is composed of the ridges 49 provided on the flat surface portion 32.

Even in such modifications 1 and 2, it is possible to suppress the drawing of rainwater between the flat surface portion 32 and the upper folded portion 46, and at the time of construction, the lower folded portion 45 is formed on the flat surface portion. Workability when inserting between 32 and the upper folded portion 46 can be improved.

[Drainage structure]
In the roof structure of the present embodiment, the eaves side vertical roofing material 3a and the ridge side vertical roofing material 3b are vertically joined in the direction of the eaves building, and the vertical joint portion has a water blocking structure. As shown in FIG. 6, the water-stopping structure has a first water-stopping portion 5, a second water-stopping portion 6, and a third water-stopping portion 7. Further, the roof structure of the present embodiment has a drainage structure capable of effectively draining the rainwater stopped by the water blocking portions 5, 6 and 7. This drainage structure penetrated between the flat surface portion 32 of the eaves side vertical roofing material 3a and the upper folded portion 46, and between the upper folded portion 46 of the eaves side vertical roofing material 3a and the flat surface portion 32 of the ridge side vertical roofing material 3b. Rainwater can be drained.

The first water stop portion 5 is configured by a locking structure of an upper folded portion 46 and a lower folded portion 45 integrally formed over substantially the entire length of the flat surface portion 32 in the width direction. That is, if the flat surfaces 32 of the vertical roofing materials 3 adjacent to each other in the eaves building direction are simply overlapped with each other, rainwater is drawn in, but in the present embodiment, the water blocking property is improved by adopting the locking structure. be able to.

The second waterproof portion 6 is composed of the waterproof material 61. The water blocking material 61 is provided at a plurality of locations. Of the plurality of water blocking materials 61, one water blocking material 61a is continuously provided over the fitted portion 37 and the flat surface portion 32, and is a corner portion between the fitted portion 37 and the flat surface portion 32. It is possible to prevent inundation from. The water blocking material 61a can also prevent rainwater that travels on the fitted portion 37 and moves to the ridge side from infiltrating to the roof base side. Further, the other water blocking material 61b is continuously provided over the upper folded portion 46 and the fitting portion 34, and the corner of the upper folded portion 46 facing the flat surface portion 32 and the standing piece 47. It is possible to prevent water from entering from the part. The water blocking material 61b can also prevent rainwater that travels on the fitting portion 34 and moves to the ridge side from infiltrating to the roof base side. The water blocking material 61 is made of packing, hot melt, or the like.

The third water stop portion 7 is composed of a plurality of ridge portions 71 protruding upward from the upper surface of the upper folded portion 46. The ridges 71 extend laterally and are formed at regular intervals in the eaves direction. By any chance, the plurality of ridges 71 pass through the locking structure between the upper folded portion 46 and the lower folded portion 45, and the flat portion 32 of the upper folded portion 46 of the eaves side vertical roofing material 3a and the ridge side vertical roofing material 3b. Even if rainwater infiltrates between and, the rainwater can be blocked so as not to infiltrate the roof base 1 side. The rainwater blocked by the third water stop portion 7 can be drained to the eaves by the drainage structure.

The drainage structure includes a water passage portion 81 and a drainage gutter 83. The water passage portion 81 is provided at the end of the eaves side vertical roofing material 3a on the ridge side. The water passage portion 81 laterally passes rainwater that has entered between the flat surface portion 32 and the upper folded portion 46, and between the upper folded portion 46 of the eaves side vertical roofing material 3a and the flat surface portion 32 of the ridge side vertical roofing material 3b. It is a part to be distributed to the drainage gutter 83 of the vertical roofing material 3 adjacent to the above. The water passage portion 81 is composed of the above-mentioned ridge-side notch portion 44 and the penetration portion 82.

As described above, the ridge-side notch 44 is configured by notching the ridge-side end of the fitted portion 37. The dimension of the ridge-side notch 44 in the eaves direction is shorter than the dimension of the overlapping portion of the eaves-side vertical roofing material 3a and the ridge-side vertical roofing material 3b. Therefore, when the eaves-side end of the ridge-side vertical roofing material 3b is connected to the ridge-side end of the eaves-side vertical roofing material 3a, the ridge-side notch 44 is covered with the ridge-side vertical roofing material 3b.

The penetrating portion 82 penetrates the flat surface portion 32 in the vertical direction. The penetration portion 82 is adjacent to the ridge side notch 44. The penetrating portion 82 is located above the drainage gutter 83 of the other vertical roofing material 3 adjacent in the lateral direction.

The drainage gutter 83 can receive rainwater that has passed through the water passage portion 81 in a state where a plurality of vertical roofing materials 2 are installed on the roof base 1, and further drains the received rainwater toward the eaves. be able to. The drainage gutter 83 of the present embodiment is composed of a laying piece 36 laid under the adjacent vertical roofing material 3.

The laying piece 36 is formed in a plate shape. The laying piece 36 is formed in the width direction of the main body portion 31 on the side opposite to the side where the water passage portion 81 is provided, that is, extends outward from the fitting portion 34. The laying piece 36 is formed over the entire length of the fitting portion 34 in the eaves direction. At the outer end of the laying piece 36, a water blocking material 40 continuous over the entire length of the laying piece 36 in the longitudinal direction is arranged.

When the eaves-side vertical roofing material 3a and the ridge-side vertical roofing material 3b are vertically joined, the laying piece 36 of the eaves-side vertical roofing material 3a and the ridge-side vertical roofing material 3b are continuous in the eaves-side direction. And be connected. Specifically, the ridge-side end of the ridge-side vertical roofing material 3a laying piece 36 overlaps the ridge-side end of the ridge-side vertical roofing material 3b from above, and the ridge-to-eave Rainwater can be distributed.

Here, as shown in FIG. 7, a tongue piece 41 extending toward the eaves is provided at the end of the ridge-side vertical roofing material 3b on the eaves side. The tip of the tongue piece 41 is located closer to the eaves than the ridge-side edge of the eaves-side notch 43. Further, a positioning portion 42 for positioning the tip of the tongue piece 41 is provided at the ridge-side end of the laying piece 36 of the eaves-side vertical roofing material 3a. As shown in FIG. 7B, the positioning portion 42 is composed of protrusions, and overlaps with the tip of the tongue piece 41 in a plan view in a state where the eave-side vertical roofing material 3a and the ridge-side vertical roofing material 3b are vertically joined. Placed in position. At this time, the ridge-side end of the rising portion 33 of the eaves-side vertical roofing material 3a and the edge of the eaves-side notch 43 of the ridge-side vertical roofing material 3b are abutted and joined (butting portion 91).

As a result, when the eaves side vertical roofing material 3a and the ridge side vertical roofing material 3b are vertically joined, the positions of the positioning portion 42 and the tip of the tongue piece 41 match, so that the lower folding portion 45 and the upper folding portion It can be confirmed that 46 is properly connected.

Further, as shown in FIG. 6A, the upper surface of the end portion of the eaves-side vertical roofing material 3a of the present embodiment on the ridge side is inclined downward toward the water passage portion 81 side. That is, the upper surface of the upper folded portion 46 as the upper surface of the end portion of the eaves side vertical roofing material 3a on the ridge side is located above the other portion in the lateral direction of the upper folded portion 46 on the side opposite to the water passage portion 81. As a result, the water passage portion 81 is inclined so as to be located downward. As a result, when rainwater adheres to the upper folded portion 46 of the eaves-side vertical roofing material 3a, the rainwater can be circulated toward the water passage portion 81.

Further, the upper surface of the covering region 9 of the vertical roofing material 3 of the present embodiment (that is, the portion of the flat surface portion 32 located below the upper folded portion 46) faces the water passage portion 81 side as shown in FIG. 6B. It is sloping down. That is, the upper surface of the covering region 9 is inclined so as to be located downward toward the water passage portion 81 side. As a result, when rainwater intrudes between the upper folded portion 46 and the flat surface portion 32 of the eaves-side vertical roofing material 3a, the rainwater can be circulated toward the water passage portion 81.

[Horizontal connection structure]
The first vertical roofing material 2a and the second vertical thatched roofing material 2b that are adjacent to each other in the lateral direction are connected by fitting the fitting portion 34 and the fitted portion 37. Here, FIGS. 8A and 8B show cross-sectional views of a state in which the fitting portion 34 of the first vertical roofing material 2a and the fitted portion 37 of the second vertical roofing material 2b are fitted.

The fitting portion 34 has an inner plate portion 341 raised from one end of the widthwise ends of the flat surface portion 32 and a top plate portion extending laterally from the upper end portion of the inner plate portion 341. A 342 and an outer plate portion 343 extending downward from the outer end portion of the top plate portion 342 are provided, and the inner plate portion 341, the top plate portion 342, and the outer plate portion 343 are integrally formed. Further, the fitting portion 34 has a fitting piece 35 screwed to the top plate portion 342.

The fitting piece 35 has a horizontal plate portion 351 and a pair of hooking portions 352 that project diagonally downward from both ends of the horizontal plate portion 351 in the lateral direction, and is formed in an inverted U shape. The horizontal plate portion 351 is a portion screwed to the top plate portion 342. The pair of hooking portions 352 are formed so that the distance between the facing portions increases toward the lower side. A plurality of fitting pieces 35 of the present embodiment are partially provided with respect to the longitudinal direction of the top plate portion 342.

The fitting piece 35 is fixed to the top plate portion 342 via the fixing tool 92. The fixing tool 92 also serves to fix the fitting piece 35 to the fitting portion 34 and to fix the vertical roofing material 3 to the roof base 1. The fastener 92 is driven from above to below the top plate portion 342. The fixing tool 92 is composed of screws, nails, or the like.

The above-mentioned laying piece 36 extends from the lower end of the outer plate portion 343.

The fitted portion 37 is configured to fit into the fitting portion 34 by covering the fitting portion 34 from above. The fitted portion 37 covers the fitting portion 34 from above. The fitted portion 37 is provided on the side of the lateral end portion of the flat surface portion 32 opposite to the end portion on the side where the fitting portion 34 is provided. The fitted portion 37 includes an inner plate portion 371 that is raised upward from one end of the flat surface portion 32 in the lateral direction, and a top plate portion 373 that extends laterally from the upper end portion of the inner plate portion 371. It is provided with an outer plate portion 374 extending downward from the outer end portion of the top plate portion 373.

The inner plate portion 371 has an inner locking portion 372 in an intermediate portion in the vertical direction. The inner locking portion 372 is formed in a stepped shape so that the upper side is located inside, and the hooking portion 352 of the fitting piece 35 is configured to be hookable. Further, the outer plate portion 374 has an outer locking portion 375 in an intermediate portion in the vertical direction. The outer locking portion 375 is formed in a stepped shape so that the upper side is located on the outside, and the hooking portion 352 of the fitting piece 35 is configured to be hookable.

A pressure contact piece 38 extending outward is provided at the lower end of the outer plate portion 374. The pressure contact piece 38 is configured to be elastically deformable, and is inclined so as to be positioned downward toward the tip side in a state where the vertical roofing material 3 is not installed. As a result, in the state where the vertical thatched roofing material 2 is installed, the flat surface portion 32 of the adjacent vertical thatched roofing material 2 (first vertical thatched roofing material 2a) is pressed against the flat surface portion 32.

The pressure contact piece 38 has a plurality of water stop protrusions 39. The plurality of water stop protrusions 39 project from the main surface (flat surface) facing below the pressure contact piece 38. The water stoppage 39 of the present embodiment has a first water stoppage 391 provided in the middle of the extension direction of the pressure contact piece 38 and a second water stoppage 392 provided at the tip of the pressure contact piece 38. And have. The first water stop protrusion 391 and the second water stop protrusion 392 are formed so as to be spaced apart from each other in the extending direction (horizontal direction in the installed state) of the pressure contact piece 38.

The first water stop protrusion 391 is arranged at an intermediate portion in the extending direction of the pressure contact piece 38. The first water stop protrusion 391 is composed of a protrusion formed by bending downward. The first water stop protrusion 391 protrudes downward from the lower surface of the portion of the pressure contact piece 38 excluding the second water stop protrusion 392. The longitudinal direction of the first water stop ridge 391 is parallel to the eaves building direction, and is formed over substantially the entire length in the eaves building direction.

The second water stop protrusion 392 is provided at the tip of the pressure contact piece 38. The second water stop protrusion 392 projects downward from the lower surface of the portion of the pressure contact piece 38 excluding the first water stop protrusion 391. The second water stop protrusion 392 of the present embodiment is formed by folding the tip of the metal plate downward. The longitudinal direction of the second water stop tip 392 is parallel to the eaves building direction, and is formed over substantially the entire length in the eaves building direction.

The water stoppage portion 39 projects toward the flat surface portion 32 in a state where the vertical roofing material 2 is installed. At this time, since the pressure contact piece 38 is in pressure contact with the flat surface portion 32, the water stop protrusion 39 is also in pressure contact with the flat surface portion 32. Therefore, in a state where the fitting portion 34 and the fitted portion 37 are fitted, it is possible to prevent rainwater from entering between the flat surface portion 32 and the pressure contact piece 38.

Further, a gap is interposed between the inner plate portion 341 and the outer plate portion 374, that is, a gap is provided between the fitting portion 34 and the fitted portion 37 on the back side of the pressure contact piece 38. Is intervening. Therefore, even when water intrudes between the pressure contact piece 38 and the flat surface portion 32, it is possible to prevent rainwater from infiltrating between the inner plate portion 341 and the outer plate portion 374. Further, by providing the laying piece 36, it is possible to more reliably prevent flooding into the roof base 1.

In the fitting portion between the fitting portion 34 and the fitted portion 37, the overlapping portion between the eave-side vertical roofing material 3a and the ridge-side vertical roofing material 3b has a structure as shown in FIG. 8B. As shown in FIG. 8B, since the fitting piece 35 is not provided in the portion corresponding to the overlapping portion, in a state where the fitted portion 37 is fitted to the fitting portion 34, the inside is used by using a tool or the like. The locking portion 372 and the outer locking portion 375 are crushed from both sides in the lateral direction, and the first vertical roofing material 2a and the second vertical roofing material 2b are mutually fixed. That is, the fitted portions 37 of the pair of vertical roofing materials 3a and 3b overlapping in the eaves building direction are not only overlapped with each other but also crimped to the fitting portion 34 to which the fitted portion 37 fits. ing.

By the way, in general, for the connecting portion of the vertical roofing material 200 in the horizontal direction, the fitting portion 340 is formed in a stepped shape as shown in FIG. 10, for example, and the fitting portion 35 is not used. It is formed so that the 370 can be fixed. According to this shape, since the fitting portion 340 and the fitted portion 370 are in close contact with each other at the A portion, it is possible to further improve the water stopping property in addition to the water stopping due to the shape.

However, in the present embodiment to which the vertical joint method for connecting a plurality of vertical roofing materials 3a and 3b in the eaves building direction is applied, if the fitting portion 340 is complicatedly formed as shown in FIG. The stackability between the roofing materials deteriorates, and the water stopping property decreases.

Therefore, in the present embodiment, the shape of the fitting portion 34 is simplified to improve the stackability, and the pressure contact piece 38 is provided to ensure waterproofness. That is, according to the roof structure of the present embodiment, it is possible to improve the stackability while maintaining the waterproof property as compared with the general roof structure.

Further, the vertical roofing material 3 of the present embodiment is fixed to the roof base 1 by driving the fixing tool 92 into the top plate portion 342 of the fitting portion 34 (rise portion 33). Therefore, in the vertical roofing material 3, the portion (through hole) penetrated by the fixing tool 92 can be separated from the place where rainwater flows, and the infiltration of water to the roof base 1 side can be suppressed. In particular, by driving the fixing tool 92 into the top plate portion 342 of the rising portion 33, the through hole by the fixing tool 92 can be positioned at a position higher than the drainage gutter 83, so that effective waterproofing is achieved. be able to.

〔application〕
In the above embodiment, the fitted portion 37 is integrally provided with the second vertical roofing material 2b, but the fitted portion 37 is a separate body from the second vertical roofing material 2b. May be good. In this case, the adjacent rising portion 33 of the first vertical roofing material 2a and the second vertical roofing material 2b is used as a fitting portion, and the fitted portion 37 is fitted into the fitting portion. It may be a cap-shaped fitted portion. The fitted portion in this case has a pair of left and right pressure contact pieces 38.

In the above embodiment, the water stoppage 39 provided on the pressure contact piece 38 includes the first water stoppage 391 and the second water stoppage 392, but the first water stoppage 391 and the first water stoppage 391. (2) Only one of the water stop protrusions 392 may be provided, or three or more may be provided. That is, the water stop protrusion 39 may have only a folded portion formed at the tip of the pressure contact piece 38, or may have only a protrusion at an intermediate portion of the pressure contact piece 38. Further, the water stop protrusion 39 may not be provided, and at least the pressure contact piece 38 may be provided.

Further, the pair of vertical roofing materials 3a and 3b that are overlapped and connected in the eaves building direction have a fitted portion 37 that overlaps with each other, whereas the vertically adjacent vertical roofing materials 3a are fitted. It had a fitting portion 34 crimped to the joint portion 37. As shown in FIG. 9A, the fitting portion 34 may have a holding groove 344 formed in the outer plate portion 343 and the inner plate portion 341. The holding groove 344 is provided in the middle portion in the vertical direction and extends in the direction of the eaves. By crimping the fitted portion 37 with respect to the holding groove 344, the fitted portion 34 and the fitted portion 37 are more firmly connected. The holding groove 344 may be provided in either the outer plate portion 343 or the inner plate portion 341.

Further, the connecting portions of the vertical roofing material 2 in the eaves direction were arranged in the horizontal direction in the vertically adjacent vertical roofing materials 2 in the horizontal direction. May be good. That is, in the vertical roofing materials 2 arranged in the horizontal direction, the connecting portions of the vertical roofing materials 3 may be arranged in a staggered manner in the horizontal direction.

Further, in the above embodiment, the pressure contact piece 38 and the flat surface portion 32 are in direct contact with each other, but the pressure contact piece 38 may not be in direct contact with the flat surface portion 32. That is, the phrase "pressing the pressure contact piece 38 against the flat surface portion 32" means that the pressure contact piece 38 is directly or indirectly pressed against the flat surface portion 32.

In addition, the configuration of the above embodiment can be appropriately redesigned as long as it does not deviate from the gist of the present invention.

〔effect〕
As described above, the connection structure of the vertical roofing material 2 of the above embodiment has the following features. In the connection structure of the vertical roofing material 2 of the above embodiment, each of the pair of vertical thatched roofing materials 2 connected in the horizontal direction has a flat surface portion 32 extending in the eaves building direction and both ends in the horizontal direction of the flat surface portion 32. It has a pair of rising portions 33 raised in the portion. The connection structure of the vertical roofing material 2 includes a fitting portion 34 provided on at least one of the pair of vertical roofing materials 2 and a fitted portion 37 provided on the other side of the pair of vertical roofing materials 2. Be prepared. The fitted portion 37 covers the fitting portion 34 from above and fits into the fitting portion 34. The fitted portion 37 has a pressure contact piece 38 that is in pressure contact with the flat surface portion 32. Hereinafter, the connecting structure of the vertical roofing material 2 having this feature is referred to as the connecting structure of the vertical thatched roofing material 2 of the first aspect.

According to the connection structure of the vertical roofing material 2 of the first aspect, the pressure contact piece 38 is in pressure contact with the flat surface portion 32, so that rainwater is suppressed from entering between the fitted portion 37 and the fitting portion 34. can. Further, since the pressure contact piece 38 is in pressure contact with the flat surface portion 32, even if rainwater should enter between the pressure contact piece 38 and the flat surface portion 32, the fitting portion 34 can block the rainwater.

Further, the connecting structure of the vertical thatched roofing material 2 of the present embodiment has the following additional features in addition to the characteristics of the connecting structure of the vertical thatched roofing material 2 of the first aspect. That is, the connecting structure of the vertical thatched roofing material 2 of the present embodiment includes the first vertical thatched roofing material 2a and the second vertical thatched roofing material 2b as a pair of vertical thatched roofing materials 2. In the first vertical roofing material 2a, the rising portion 33 on the second vertical roofing material 2b side of the pair of rising portions 33 is the fitting portion 34. In the second vertical roofing material 2b, the rising portion 33 on the first vertical roofing material 2a side of the pair of rising portions 33 is the fitted portion 37. Hereinafter, the connecting structure of the vertical roofing material 2 having this feature is referred to as the connecting structure of the vertical thatched roofing material 2 of the second aspect.

According to the connection structure of the vertical thatched roofing material 2 of the second aspect, the end portion of the second vertical thatched roofing material 2b on the first vertical roofing material 2a side is the flat surface of the second vertical thatched roofing material 2b. Since it is pressed against the portion 32, it is possible to prevent rainwater from entering from the end portion of the second vertical roofing material 2b on the first vertical roofing material 2a side.

Further, the connecting structure of the vertical thatched roofing material of the present embodiment has the following additional features in addition to the characteristics of the connecting structure of the vertical thatched roofing material 2 of the first or second aspect. That is, in the connection structure of the vertical roofing material 2 of the present embodiment, the pressure contact piece 38 is formed along the eaves building direction and protrudes toward the flat surface portion 32, and the flat surface portion of the first vertical roofing material 2a. It has a water stop protrusion 39 that is in pressure contact with 32. Hereinafter, the connection structure of the vertical roofing material 2 will be referred to as a connection structure of the vertical roofing material 2 of the third aspect.

According to the connection structure of the vertical roofing material 2 of the third aspect, the rainwater can be blocked by the water blocking protrusion 39, so that the water stopping property can be improved.

Further, the connecting structure of the vertical roofing material 2 of the present embodiment has the following additional features in addition to the characteristics of the connecting structure of the vertical thatched roofing material 2 of the third aspect. That is, in the connection structure of the vertical roofing material 2 of the present embodiment, a plurality of water stop protrusions 39 are formed at intervals in the lateral direction. Hereinafter, the connection structure of the vertical thatched roof material is referred to as a connection structure of the vertical thatched roof material of the fourth aspect.

According to the connection structure of the vertical roofing material 2 of the fourth aspect, the rainwater can be blocked by the plurality of water blocking protrusions 39, so that the water stopping property can be further improved.

Further, the connecting structure of the vertical roofing material 2 of the present embodiment has the following additional features in addition to the characteristics of the connecting structure of the vertical thatched roofing material 2 according to any one of the first to third aspects. That is, in the connection structure of the vertical thatched roofing material 2 of the present embodiment, each of the pair of vertical thatched roofing materials 2 has a pair of vertical thatched roofing materials 3 that are connected by overlapping the ends in the eaves direction. The fitted portions 37 of the pair of vertical roofing materials 3 overlap each other and are crimped to the fitting portions 34 of the vertically adjacent vertical roofing materials 3 in the lateral direction. Hereinafter, the connection structure of the vertical thatched roof material is referred to as a connection structure of the vertical thatched roof material according to the fifth aspect.

According to the connection structure of the vertical thatched roofing material 2 of the fifth aspect, even in the connecting structure of the vertical thatched roofing material of the vertical joint method in which a plurality of vertical thatched roofing materials 3 are connected in the direction of the eaves, the vertical thatched roofing materials 3 have good water stopping property. Can be connected.

Further, the connecting structure of the vertical roofing material 2 of the present embodiment has the following additional features in addition to the characteristics of the connecting structure of the vertical thatched roofing material 2 of the fifth aspect. That is, in the connection structure of the vertical roofing material 2 of the present embodiment, the fitting portion 34 has a holding groove 344 formed in a portion where the fitted portions 37 overlapping each other are crimped. Hereinafter, the connection structure of the vertical thatched roof material is referred to as a connection structure of the vertical thatched roof material of the sixth aspect.

According to the connection structure of the vertical roofing material 2 of the sixth aspect, the fitting portion 34 and the fitted portion 37 can be more firmly connected in the vertical joint method.

The vertical roofing material 3 of the above embodiment has the following features. This is a vertical roofing material 3 used for a connecting structure of a vertical roofing material 2 in which a plurality of vertical roofing materials 2 are arranged adjacent to each other in the horizontal direction. The vertical roofing material 3 is formed along the direction of the eaves building and has a water stop protrusion 39 that protrudes toward the flat surface portion 32 side of another vertically adjacent vertical roofing material 3 in the lateral direction and presses against the flat surface portion 32. .. Hereinafter, the vertical roofing material 3 having this feature is referred to as the vertical roofing material 3 of the first aspect.

According to the vertical roofing material 3 of the first aspect, in a state where the vertical roofing material 3 is installed on the roof base 1, the end portion of the adjacent vertical roofing material 2 side is pressed against the flat surface portion 32 of the adjacent vertical roofing material 3. Therefore, it is possible to suppress the infiltration of rainwater from the end portion of the vertical roofing material 3.

2 Vertical thatched roofing material 2a 1st vertical thatched roofing material 2b 2nd vertical thatched roofing material 3 Vertical roofing material 32 Flat surface 33 Standing top 34 Fitting part 344 Holding groove 37 Fitted part 38 Pressure welding piece 39 Stopping part

Claims (2)

Each of the pair of vertical thatched roofing materials connected in the horizontal direction has a flat surface portion extending in the eaves direction and a pair of rising portions raised at both ends in the horizontal direction of the flat surface portion. It is a connection structure of
With the fitting portion provided on at least one of the pair of vertical roofing materials,
It is provided on the other side of the pair of vertical roofing materials, and includes a fitted portion that covers the fitting portion from above and fits into the fitting portion.
As the pair of vertical thatched roofing materials, a first vertical thatched roofing material and a second vertical thatched roofing material are provided.
In the first vertical roofing material, the rising portion on the second vertical roofing material side of the pair of rising portions is the fitting portion.
In the second vertical roofing material, the rising portion of the pair of rising portions on the side of the first vertical roofing material is the fitted portion.
The fitted portion has a pressure contact piece that presses against the flat surface portion of the first vertical roofing material .
The pressure contact piece is formed along the direction of the eaves building, extends from the fitted portion to the side opposite to the flat surface portion of the second vertical roofing material, and is formed of the first vertical roofing material. It is a plate-shaped portion extending along the flat surface portion, and is a plate-shaped portion.
The pressure-welded piece has a first water stop protrusion that projects and press-contacts toward the flat surface portion of the first vertical roofing material in the middle of the extending direction, and the first vertical portion at the tip in the extending direction. It has a second water stop protrusion that protrudes toward the flat surface of the thatched roof material and presses against it.
The second water stoppage portion is a connection structure of a vertical thatched roofing material, characterized in that the tip end portion of the pressure contact piece is folded downward and formed . A vertical thatched roofing material used for the connection structure of vertical thatched roofing materials in which a plurality of vertical thatched roofing materials are arranged adjacent to each other in the horizontal direction.
The flat part extending toward the eaves building and
A pair of rising portions raised at both ends in the horizontal direction of the flat surface portion,
It is formed along the direction of the eaves building and has a plate-shaped pressure contact piece extending from one of the pair of rising portions to the opposite side of the flat surface portion.
The pressure-welded piece has a first water-stopping protrusion that protrudes downward in the middle of the extending direction, and a second water-stopping protrusion that has the tip of the pressure-welding piece folded downward.
The first water stoppage portion and the second water stoppage portion are configured to be in pressure contact with a flat surface portion of another vertically adjacent vertical roofing material in the lateral direction.
A vertical roofing material that is characterized by that.

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