JP3939413B2 - roof - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a building roof, and more particularly to a roof suitable for use in cold regions.
[0002]
[Prior art]
Generally, in cold districts, a building having a sloped roof, such as a house, often has no eaves installed at the eaves. This is because, during the winter, icy snow can easily be damaged because the ice piles around the eaves are greatly generated due to the snow dripping at the eaves and the melting of snow melt water. For this reason, as shown in the conventional example of FIG. 7, a method of preventing the roof eaves 102 from falling into the eaves 102 even if the roof snow slides down, as shown in FIG. In addition, when the heating wire 104 is extended to the bottom of the eaves wall 102 and the outside air temperature is 0 ° C. or lower, the eaves wall 102 is heated and further covered with a predetermined gap in the length direction. A method for preventing freezing at a low temperature by providing a plate 103 to prevent heat dissipation has been proposed.
[0003]
However, even if the conventional technique shown in FIG. 7 is used, in extremely cold regions, the snowmelt water from the roof surface freezes at the coldest cover plate 103 and eaves 102 part, and the generation of icicles generated around the eaves 102 is generated. Could not be prevented.
[0004]
In the prior art shown in FIG. 8 as well, under the weather conditions in which wind and snow are intense and the temperature is low, the cover plate 103 is cooled, so that snow is accumulated on the cover plate 103. The melted snow water impregnates and freezes, so that the snowmelt water cannot be dripped into the eaves bowl 102 and circulates around the eaves bowl 102 to generate icicles and damage the eaves bowl 102.
[0005]
In this way, snow that has accumulated on the roof due to snowfall usually melts from the lower layer, and the melted water flows or drops from the edge of the eaves to the ground. Depending on climatic conditions such as cold weather, the snowmelt water falling from the edge of the eaves freezes again here, and ice pillars grow on the eaves. This icicle not only interferes with snow removal, but may cause danger in some cases, so a roof that can prevent its growth is desired.
[0006]
Furthermore, in cold regions, a large amount of snow is generated on the roof, so it is indispensable to remove the accumulated snow, but it is dangerous to perform snow removal work by climbing the roof during snowfall. A configuration that can be easily removed is desired.
[0007]
The present invention has been made paying attention to the above-mentioned problems, and its purpose is to stably collect water without dripping rainwater or snowmelt water on a roof in a building in a cold district, It is to provide a roof that prevents the occurrence of icicles.
[0008]
Another object of the present invention is to provide a roof that can easily remove snow from the roof.
[0009]
Still another object of the present invention is to provide a roof structure that prevents sudden sliding down of the eaves of snow that has fallen on the roof.
[0010]
[Means for Solving the Problems]
The roof according to claim 1 of the present invention has a ridge line between adjacent inclined surfaces, and the roof plate includes a plurality of roof plates connected to each other, and the roof plate includes an end portion on the upper side of the inclined surface. An engaging portion that winds an end portion on the lower side of the inclined surface to the opposite side of the engaging portion on the upper side of the inclined surface, and the engaging portion on the upper side of the inclined surface and the lower side of the inclined surface The roof plates adjacent to each other in the vertical direction of the inclined surface are connected to each other by hooking the engaging portions to each other, and the roof plate is erected on the inclined surface from the roof ridge to the eaves The rising portions are formed at predetermined intervals in the inclination direction, and the end portions of the rising portions are disposed at a certain distance from the ridge line, and a water discharge device is provided in the roof ridge. It is characterized by that.
[0011]
Of the engaging portions formed on the roof plate, the engaging portion on the upper side of the inclined surface is formed by folding the end portion of the roof plate outward from the roof side, and the engaging portion on the lower side of the inclined surface. It is preferable that the portion is formed by folding the end portion of the roof plate from the outside to the roof side. The roof plate may be fixed by nailing at least one of the engaging portions formed on the roof plate. Furthermore, it is preferable that a roof plate not formed with the rising portion is connected to at least one side of the roof plate formed with the rising portion.
[0012]
As described above, the roof of the present invention is formed such that the rising portions are formed on the roof plate and arranged at predetermined intervals in the inclination direction, and further, the end portions of the rising portions are located at a certain distance from the ridgeline of the roof. It is configured such that when there is precipitation on the roof or when the snow on the roof melts and becomes melted water, the rainwater or melted water flows along the slope of the roof and hits the rising portion. And rain water and snowmelt water flow along the rising part, and when rain water accumulates on this rising part, it hits the rising part located below. Or it flows down between the rising part and the ridgeline of the roof. In this way, finally rainwater and snow melting water is configured to be water collector Te ridge lower portion smell.
[0013]
According to the roof of the present invention as described above, rainwater and snow melting water ya Negami can be collecting in ridge lower portion of the roof. Moreover, since rain water or snowmelt water does not drip from the eaves, it is possible to prevent the generation of icicles that are generated by re-freezing of the snowmelt water at the eaves.
[0014]
And in the roof of the present invention, a water discharge device is arranged in the ridge, and by letting ground water and tap water flow down from the water discharge device to the roof surface, it is possible to melt snow by heat energy possessed by the ground water and tap water. It becomes possible. At this time, the water flowing down from the nozzle gradually flows down while hitting a plurality of rising portions, like rainwater and snowmelt water, so that it is possible to spread the water over the entire roof surface. Furthermore, in summer, the roof surface can be cooled by the water flowing down from the water discharge device, and the comfort of the living space can be improved.
[0015]
Further, since the rising portion formed on the roof can be used as a snow stopper to hold the snow accumulated on the roof, it is possible to prevent sudden snow falling from the eaves.
[0016]
DETAILED DESCRIPTION OF THE INVENTION
The present invention relates to a roof 10 having a ridge line 12 between adjacent inclined surfaces 11 and a plurality of roof plates 13 connected to each other. The roof plate 13 includes an engaging portion 13a that winds an end portion on the upper side of the inclined surface 11 and an engaging portion that winds an end portion on the lower side of the inclined surface 11 to the opposite side of the engaging portion 13a on the upper side of the inclined surface 11. The roof board 13 adjacent to the up-down direction of the inclined surface 11 is connected by hooking the engaging part 13a of the inclined surface 11 upper side, and the engaging part 13a of the inclined surface 11 lower side. Further, the roof plate 13 is formed with a rising portion 14 erected on the inclined surface 11 of the roof 10 from the ridge 2 to the eaves 3. The rising portions 14 are formed at predetermined intervals in the tilt direction, and the end portions 14 a of the rising portions 14 are disposed so as to be positioned at a certain distance from the ridge line 12. A water discharge device 19 is provided in the ridge of the roof 10.
[0017]
Of the engaging portions 13 a formed on the roof plate 13, the engaging portion 13 a on the upper side of the inclined surface 11 is formed by folding the end of the roof plate 13 outward from the roof side, and below the inclined surface 11. The side engaging portion 13a is formed by folding the end portion of the roof plate 13 from the outside to the roof side. The roof plate 13 is fixed by nailing at least one of the engaging portions 13a formed on the roof plate 13 to the roof. Furthermore, the roof board 13 in which the rising part 14 is not formed is connected to at least one side of the roof board 13 in which the rising part 14 is formed.
[0018]
Since it is configured as described above, when there is precipitation on the roof or when the snow on the roof melts to form snow melting water, rain water or snow melting water flows along the slope of the roof and forms on the roof 10. It strikes against the raised portion 14 that has been made. After rainwater and snowmelt water once accumulates on the rising portion 14, it flows out from the end portion 14 a and the long side portion 14 b of the rising portion 14 and further flows out to the rising portion 14 below. Further, a flow passage 15 is defined between the end portion 14a of the rising portion 14 and the ridgeline 12 of the roof, and the flow passage 15 is lowered.
[0019]
Note that the end portion 14 a of the rising portion 14 is disposed with a certain distance from the ridgeline 12 of the roof 10. The roof 10 has a trapezoidal or triangular roof surface. Therefore, the length of the rising portion 14 provided on the eaves 3 side is longer than that on the ridge 2 side on the roof surface.
[0020]
Therefore, rainwater and snowmelt water on the roof 10 first strikes the rising portion 14 located on the ridge 2 side, and when water accumulates on the rising portion 14, the end portion 14 a and the long side portion 14 b of the rising portion 14. And flow out to the rising portion 14 or the flow passage 15 below. As the length of the rising portion 14 increases as it flows downward, the amount of water on the rising portion 14 gradually decreases. In this way, rainwater and snowmelt water are collected at the lower end of the ridgeline 12 of the roof 10 without dripping from the eaves 3 via the plurality of rising portions 14 and the flow passages 15.
[0021]
As described above, according to the roof 10 of the present invention, water can be collected at the lower end of the ridgeline of the roof 10, so that water is collected without using eaves that are easily damaged by snow or the like particularly in cold regions. It becomes possible. Moreover, it is possible to prevent the generation of icicles generated by re-freezing of the snowmelt water at the eaves without the rainwater dripping from the eaves. Furthermore, the rising part 14 can prevent snow from suddenly falling on the roof 10 as a snow stopper.
[0022]
Further, a water discharge device 19 is disposed in the ridge of the roof 10 of the present invention. The water discharge device 19 is a device for causing groundwater or tap water to flow down on the roof 10. By using this water discharging device 19 to flow groundwater or tap water from the nozzle 19b of the water discharging device 19 to the roof surface during snowfall, it is possible to melt snow by heat energy possessed by the groundwater or tap water.
[0023]
At this time, the water flowing down from the nozzle 19b gradually flows down while hitting a plurality of rising portions 14 arranged on the roof 10, like rain water and snowmelt water, so that the water is spread over the entire roof. Is possible. Further, in summer, the roof surface can be cooled by the water flowing down from the water discharge device, and the comfort of the living space can be improved.
[0024]
【Example】
Hereinafter, an embodiment of the present invention will be described with reference to the drawings. The members, arrangements, and the like described below are not intended to limit the present invention and can be variously modified within the scope of the gist of the present invention.
[0025]
1 to 4 show an embodiment according to the present invention. FIG. 1 is a plan view of the roof of the present invention, FIG. 2 is a sectional view of the roof of the present invention, and FIG. FIG. 4 is an explanatory view of the water discharge device.
[0026]
The roof 10 of the present invention is a roof having a ridge line between adjacent inclined surfaces and a plurality of roof plates 13 connected to each other. In FIG. 1, a roof 10 in a building with a dormitory structure is shown. As shown in FIG. 1, the inclined surface 11 of the roof 10 includes a pair of roof surfaces 11 a on the long side of the building and a roof surface 11 b on the short side of the building. A ridgeline 12, so-called corner ridge, is located between the roof surface 11a and the roof surface 11b. In addition, in the roof 10 of a present Example, the roof surface 11a is formed in trapezoid, and the roof surface 11b is formed in the triangle.
[0027]
As shown in FIG. 2, the roof 10 has a windproof and moistureproof sheet 5 disposed on a roof base 4 to perform roofing and is covered with a roof plate 13. The roof plate 13 is made of, for example, a roof color iron plate, and has an engaging portion 13a wound around an end portion. Adjacent roof plates 13 are connected by the engaging portion 13a. The roof plate 13 is fixed to the roof 10 by nailing with a nail 6 as shown in FIG.
[0028]
And on the roof 10 roof surface 11a and the roof surface 11b, the rising part 14 is formed so that it may orthogonally cross with the inclination direction of a roof, ie, the direction through which rainwater flows. As shown in FIG. 2, the rising portion 14 is formed on the roof plate 13, and is formed by providing the roof plate 13 with a bend that rises from the roof 10. Bending is formed so that there is no gap between them.
[0029]
As shown in FIG. 1, the rising portion 14 is disposed in a long shape on the roof 10. For this reason, the roof board 13 in which the rising part 14 is formed is connected to the left and right, and is arranged on the roof so that the rising part 14 is connected. Or the standing part 14 is formed in this roof board 13 using the panel-shaped roof board 13 previously formed in elongate.
[0030]
Further, as shown in FIG. 2, the rising portions 14 are formed on the roof plate 13 every other one in the inclination direction of the roof. Thus, the rising portions 14 are formed at appropriate intervals according to the size of the roof 10. Further, the end portion 14 a of the rising portion 14 is disposed with a certain distance from the ridge line 12.
[0031]
A plurality of rising portions 14 are formed at a predetermined interval, and the end portion 14a of the rising portion 14 is disposed at a certain distance from the ridge line 12, so that the gap between the end portion 14a of the rising portion 14 and the ridge line 12 is as shown in FIG. As shown in FIG. Rainwater or snowmelt water on the roof 10 passes through this flow passage and flows down to the lower end of the ridgeline 12.
[0032]
Further, as shown in FIG. 1, the rising portion 14 is configured such that the rising portion 14 disposed on the eaves 3 side is longer than the building 2 side on the roof surface 11a and the roof surface 11b. .
[0033]
Further, a water discharge device 19 is provided in the ridge of the roof 10 of the present invention. As shown in FIG. 4, the water outlet 19 includes a water distribution pipe 19a disposed on the ridge, a plurality of nozzles 19b provided on the water distribution pipe 19a, and a water pump (not shown). ) To the main pipe 19c.
[0034]
The water distribution pipe 19a is disposed along the ridge, and a plurality of nozzles 19b are formed in the water distribution pipe 19a so that water can flow out to all the roof surfaces 11a and 11b. The water distribution pipe 19a is connected to the main pipe 19c, and the main pipe 19c is connected to a well pump or a water pipe (not shown).
[0035]
Then, water is fed from the well pump or the water pipe to the water distribution pipe 19a via the trunk pipe 19c, and the water is allowed to flow down on the roof surfaces 11a and 11b from the nozzles 19b arranged at various places of the water distribution pipe 19a. It is configured.
[ 0036 ]
The roof plate 13 of the present embodiment will be described in more detail. As shown in FIG. 3, the roof plate 13 includes an engaging portion 13 a that includes an end portion on the upper side of the inclined surface 11, and a lower side of the inclined surface 11. An engaging portion 13a is formed in which the end portion of this is wound on the opposite side to the engaging portion 13a above the inclined surface 11. And the roof board 13 adjacent to the up-down direction of the inclined surface 11 is connected by hooking the engaging part 13a above the inclined surface 11 and the engaging part 13a below the inclined surface 11.
[ 0037 ]
In this example, as shown in FIG. 3, among the engaging portions 13 a formed on the roof plate 13, the engaging portion 13 a on the upper side of the inclined surface 11 has an end portion of the roof plate 13 on the outer side from the roof side. The engaging portion 13a on the lower side of the inclined surface 11 is formed by folding the end portion of the roof plate 13 from the outside to the roof side.
[ 0038 ]
Furthermore, in this example, as shown in FIG. 2, the roof board 13 in which the rising part 14 is not formed is connected adjacent to the roof board 13 in which the rising part 14 is formed.
[ 0039 ]
The roof board 13 of this example has the above-described configuration, and is fixed to the roof by the nails 6. In this example, as shown in FIG. 3, at least one of the engaging portions 13a formed on the roof plate 13 (the engaging portion 13a positioned on the upper side of the inclined surface 11 in FIG. 3) is nailed to the roof. It is fixed by.
[ 0040 ]
Next, the flow of rainwater and snowmelt water on the roof of the present invention will be described. When there is rainfall or snowfall on the roof, the rainwater or snowmelt water tends to flow along the slope of the roof, and the rainwater or snowmelt water hits the rising portion 14 while flowing on the roof surfaces 11a and 11b. Rainwater and snowmelt gradually accumulate on the rising portion 14, and then flow out from the end portion 14 a of the rising portion 14, get over the rising portion 14, and flow out from the long side portion 14 b of the rising portion 14.
[ 0041 ]
Rain water and snowmelt water flowing out from the rising portion 14 flows onto the lower roof surface, and further flows to the rising portion 14 or the flow passage 15 located below. In this way, the rain water and melting Yukisui is going to flow down over the roof surface.
[ 0042 ]
And the rising part 14 on the roof surfaces 11a and 11b is configured such that the rising part 14 located on the eaves 3 side is longer than the rising part 14 located on the ridge 2 side. Therefore, as rainwater that has fallen on the roof flows downward, the rainwater hits the longer rising portion 14, so that it is difficult for the rainwater to flow out from the long side portion 14 b of the rising portion 14. And while rainwater or snowmelt water flows down to the eaves side, it finally passes through the flow passage 15 and is collected on the lower end side of the ridgeline 12.
[ 0043 ]
As described above, according to the roof of the present invention, water can be collected at the lower end portion of the ridgeline of the roof, so that water can be collected without using eaves that are easily damaged by snow accumulation or the like particularly in cold regions. Is possible. Moreover, since rain water or snowmelt water does not drip from the front of the eaves, it is possible to prevent the generation of icicles generated by re-freezing the snowmelt water at the edge of the eaves. Furthermore, the rising portion can be used as a snow stop to hold the snow on the roof and prevent sudden sliding off from the eaves.
[ 0044 ]
Also, since the roof has a water outlet, the groundwater and tap water flow down from the nozzle of the water outlet to the roof surface during snowfall, so that the snow can be melted by the thermal energy of the groundwater and tap water. Is possible. At this time, the water flowing down from the nozzle gradually flows down while hitting a plurality of rising portions, like rainwater and snowmelt water, so that it is possible to spread the water over the entire roof surface.
[ 0045 ]
As described above, the roof of the present invention is preferably used particularly in cold regions, but even in the summer, water can be collected without dripping rainwater on the roof from the eaves. It is possible to prevent rainwater from splashing on the figurine, and to prevent rainwater on the ground under the eaves. In addition, rainwater is led to the flow passage while gradually flowing down a plurality of rising parts, and is collected so that rainwater does not flow into the reed at a time and can be collected stably. It is possible to prevent the building from decaying and becoming dirty due to rebounding.
[ 0046 ]
Furthermore, the water supply device not only melts snow in the winter, but in the summer it can cool the roof surface with water flowing down from this water supply device, reducing the temperature rise in the room and improving the comfort of the living space It becomes possible to make it.
[ 0047 ]
In addition, in the present Example, although the example which formed each 4 rising parts on the roof surface of the building long side and the roof surface of the building short side was shown, it is not restricted to this, The size of a building or a roof According to the above, the number of rising parts shall be adjusted.
[ 0048 ]
In the above embodiment, an example of a building with a dormitory structure is shown. However, the present invention is not limited thereto, and any building having a roof having a ridgeline between adjacent inclined surfaces may be used. Of course, the roof of the invention can be used.
[ 0049 ]
5 and 6 are explanatory views showing a reference example of the present invention. In this example, the same members as those in the above embodiment are denoted by the same reference numerals, and the description thereof is omitted.
[ 0050 ]
FIG. 5 is an explanatory view showing a ridge portion. In the present embodiment, a plurality of ridge portions 16 are disposed on the roof 10. As shown in the figure, the ridge 16 is formed of a rectangular column-shaped long member having a rectangular cross section, and is orthogonal to the roof inclination direction, that is, the direction in which rainwater flows, on the roof surface 11a and the roof surface 11b. It is arranged as follows. The ridges 16 are arranged at predetermined intervals, and the ends of the ridges 16 are arranged at a certain distance from the ridgeline 12. Further, the ridge portion 16 is configured such that the ridge portion 16 disposed on the eaves 3 side is longer than the ridge 2 side on the roof surface 11a and the roof surface 11b.
[ 0051 ]
Then, when there is precipitation on the roof 10 or when the snow on the roof melts to become snowmelt water, rainwater or snowmelt water flows along the slope of the roof and strikes the ridges 16. And rainwater and snowmelt water flow along the ridges 16, and when rainwater accumulates on the ridges 16, it strikes the ridges 16 located below. Or it flows down the flow path 15 formed between the protruding line part 16 and the ridgeline 12 of the roof. In this way, finally, rainwater and snowmelt water are collected at the lower end of the ridgeline 12.
[ 0052 ]
In addition, the protrusion 16 is not limited to the prismatic long member, but is formed from a long member having an L-shaped cross section as shown in FIG. 6, for example, and one side of this member is fixed on the roof surface. It is good also as composition to do.
[ 0053 ]
By using the ridges 16 as described above, even when the roof plate 13 is formed of a member that cannot be bent, the rainwater on the roof can be obtained simply by arranging the ridges 16 on the roof. Etc. can be collected at the lower end of the ridgeline to prevent dripping of water from the eaves and to prevent snow from falling.
[ 0054 ]
【The invention's effect】
As described above, the roof of the present invention is configured to collect water without dripping snow melting water on the eaves, so that it is possible to eliminate eaves at the eaves and prevent the occurrence of icicles at the eaves. be able to. Further, since the water discharge device is disposed in the roof ridge, the snow on the roof can be melted by the water flowing down from the water discharge device, and snow removal is possible. Furthermore, since the rising portion serves as a snow stop to prevent snow falling on the roof, it can be suitably used particularly in cold regions.
[ 0055 ]
In addition to the above-described effects in winter, rainwater can be collected stably and reliably in summer, and a comfortable living space can be obtained by cooling the roof with a water discharge device.
[Brief description of the drawings]
FIG. 1 is a plan view of a roof according to the present invention.
FIG. 2 is a cross-sectional view of the roof of the present invention.
FIG. 3 is an enlarged view of a main part of FIG. 3;
FIG. 4 is an explanatory view showing a water discharge apparatus of the present invention.
FIG. 5 is an explanatory view showing a ridge portion.
FIG. 6 is an explanatory view showing another example of a protruding portion.
FIG. 7 is an explanatory diagram showing a conventional example.
FIG. 8 is an explanatory diagram showing a conventional example.
[Explanation of symbols]
2 buildings 3 eaves 10 roof 11 inclined surface 11a roof surface 11b roof surface 12 ridge line 13 roof plate 14 rising portion 15 flow passage 16 ridge portion 19 water discharge device

Claims (4)

In a roof having a ridgeline between adjacent inclined surfaces and connecting and arranging a plurality of roof plates,
The roof plate includes an engaging portion that winds an end portion on the upper side of the inclined surface, and an engaging portion that winds an end portion on the lower side of the inclined surface on the opposite side of the engaging portion on the upper side of the inclined surface. ,
By hooking the engaging portion on the upper side of the inclined surface and the engaging portion on the lower side of the inclined surface, the roof plates adjacent in the vertical direction of the inclined surface are connected,
The roof plate has a rising portion erected on an inclined surface extending from the roof ridge to the eaves, the rising portion is formed at a predetermined interval in the inclination direction, and an end portion of the rising portion is connected to the ridgeline. Arranged to be located at a certain distance,
The roof ridge is provided with a water discharge device. Of the engaging portions formed on the roof plate, the engaging portion on the upper side of the inclined surface is formed by folding the end portion of the roof plate outward from the roof side, and the engaging portion on the lower side of the inclined surface. 2. The roof according to claim 1, wherein the portion is formed by folding an end portion of the roof plate from the outside to the roof side. The roof according to claim 1 or 2, wherein the roof plate is fixed by nailing at least one of engaging portions formed on the roof plate. The roof according to any one of claims 1 to 3, wherein a roof plate not formed with the rising portion is connected to at least one side of the roof plate formed with the rising portion.

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