JP5643054B2 - Roof structure - Google Patents

Description

  The present invention relates to a roof structure in which a solar cell panel that receives sunlight is installed on an upper surface.

2. Description of the Related Art Conventionally, a technique for installing a solar cell panel that receives sunlight on an upper surface of a sloped roof of a building is known. As a solar cell panel used in such a technique, for example, there is one obtained by bonding a plurality of photovoltaic cell substrates called solar cells to a white plate tempered glass or a transparent resin plate having a thickness of about 4 to 5 mm. . In addition, there are elements mainly composed of monocrystalline or polycrystalline silicon and elements mainly composed of amorphous silicon as a device for generating photovoltaic power.
By the way, although such a solar cell has a difference by the base material of an element, generally, when element temperature becomes high, it has the characteristic that electric power generation efficiency falls.
Therefore, the gap between the roof and the solar cell panel is used as a ventilation layer communicating with the outside, and the solar cell is caused by flowing outside air into the ventilation layer through an eaves vent opening provided on the eaves side of the ventilation layer. A technique for removing heat from the panel is known (see, for example, Patent Document 1).

Japanese Patent Laid-Open No. 11-044035

By the way, a ventilation louver is attached to the above-mentioned eaves vent, so that rain water, dust and the like can be prevented from entering the ventilation layer while flowing outside air into the ventilation layer.
However, since this ventilation gallery opens to the outside, rainwater enters the ventilation layer together with the wind blown toward the ventilation gallery in the case of strong wind and rain such as a typhoon. As a result, sufficient waterproofness may not be exhibited.

  An object of the present invention is to provide a roof structure capable of reliably flowing outside air into the ventilation layer while reliably preventing rainwater from entering the ventilation layer and capable of exhibiting sufficient waterproofness. Objective.

The invention according to claim 1 is a roof structure, for example, as shown in FIGS. 1 to 6, a solar cell panel 20 that receives sunlight is installed on the upper surface of a gable-shaped roof 10, A ventilation layer 30 is formed between the roof 10 and the solar cell panel 20,
An eaves bowl 11 is attached to the end of the roof 10 on the eaves side.
An eaves vent 31 is provided at the eaves end of the vent layer 30.
Between the eaves side end of the solar cell panel 20 and the outer edge of the eaves ridge 11, a portion between the eaves side end of the solar cell panel 20 and the outer edge of the eaves 11 is shielded. An eaves cover material 1 is provided so as to cover the eaves vent 31 .
It said being spaced from the eaves side end of the eaves gutter 11 of the solar cell panel 20,
Between the eaves side end portions of the solar cell panels 20 and the eaves eaves 11, an air passage 32 is formed which is located below the eaves cover member 1 and communicates with the eaves vent 31 of the vent layer 30. ,
The eaves edge cover material 1 includes a drainage portion 1a formed above the eaves ridge 11 and having a plurality of drainage holes 2 penetrating through the eaves edge cover material 1 in the thickness direction, and the ventilation path 32. A water supply portion 1b that is located above and not formed with a plurality of drain holes 2 ...
The drainage portion 1a has a drainage groove 1c formed along the outer edge of the drainage portion 1a and deeper than the upper surface of the drainage portion 1a. It has holes 4 ...
And the wife side end 14 which the lower end part is connected to the eaves end 11 is attached to the end side of the end of the roof 10,
Between the end portion of the solar cell panel 20 and the outer edge portion of the end surface 14, a portion between the end portion of the solar panel 20 and the outer end portion of the end surface 14 is shielded. Wife side cover material 3 to be provided,
In the wife side cover material 3, a plurality of drain holes 4... Passing through the wife side cover material 3 in the thickness direction and drain grooves 3 a along the outer edge are located above the wife side ridge 14. Formed,
Further, the lower end of the wife side collar 14 is communicated with the eaves anchor 11, and the eaves edge cover material 1 and the wife side cover material 3 are inclined between the end of the eaves edge cover material 1 and the wife side cover material 3. The outer bent cover material 5 is connected to the lower end portion by a substantially L-shaped outer bent cover member 5 connected to the lower end portion. The outer bent cover member 5 includes a plurality of penetrating through the outer bent cover member 5 in the thickness direction. A drainage hole 6 ... and a drainage groove 5c are formed, and the drainage groove 1c of the eaves edge cover material and the drainage groove 3a of the wife side cover material 3 are communicated with each other through the drainage groove 5c of the outer bent cover material 5. It is characterized by.

According to the invention described in claim 1, the eaves edge cover material 1 is applied to the eaves edge cover material 1 that shields a portion between the eave edge side end portion of the solar cell panel 20 and the outer edge portion of the eaves wall 11. Since a plurality of drain holes 2 penetrating in the thickness direction are formed, rainwater flowing from the upper surface of the solar cell panel 20 toward the eaves is passed through the plurality of drain holes 2 of the eaves cover material 1. It can be poured into the tub 11.
Also, outside air that enters the back side of the eaves cover material 1 through the plurality of drain holes 2... Enters the back side of the eaves cover material 1, changes the angle toward the eaves ventilation port 31, and then opens the eaves ventilation port 31. Therefore, the outside air can surely flow into the ventilation layer 30.
In order for rainwater to enter the ventilation layer 30, it enters the back side of the eaves cover material 1 together with outside air, changes the angle toward the eaves ventilation port 31, and then enters the ventilation layer 30 through the eaves ventilation port 31. Since it is extremely difficult, it is possible to reliably prevent rainwater from entering the ventilation layer 30 together with the outside air even during a strong wind and rain. That is, it is possible to surely allow outside air to flow into the ventilation layer 30 while reliably preventing rainwater from entering the ventilation layer 30, and to exhibit sufficient waterproofness.
Further, dust or the like that enters the back side of the eaves cover material 1 through the plurality of drain holes 2... Changes the angle toward the eaves vent 31 like the rainwater and then vents through the eaves vent 31. Since it must penetrate into the layer 30, it is possible to reliably prevent dust and the like from entering the ventilation layer 30.

Moreover , since the ventilation path 32 is formed between the eaves side edge part of the solar cell panel 20 arrange | positioned at intervals, and the eaves cage | basket 11, the eaves edge cover material 1 via the said several drain hole 2 ... The outside air that enters the back side of the air can flow into the ventilation layer 30 after passing through the ventilation path 32.
Therefore, in order for rainwater to enter the ventilation layer 30, it enters the back side of the eaves cover material 1 together with outside air, changes the angle toward the eaves vent 31, passes through the ventilation path 32, and then eaves vent 31. It is extremely difficult to enter the ventilation layer 30 via For this reason, it is possible to more reliably prevent rainwater from entering the ventilation layer 30 together with the outside air even during a strong wind and rain.

In addition, since the eaves edge cover member 1 includes the water supply portion 1b that is located above the air passage 32 and is not formed with a plurality of drain holes 2, the air passage 32 is reliably shielded by the water supply portion 1b. be able to.
As a result, the rainwater flowing from the upper surface of the solar cell panel 20 toward the eaves flows through the upper surface of the water supply portion 1b, so that the rainwater can be guided to the drainage portion 1a by the water supply portion 1b. Rainwater can be more reliably flowed to the eaves 11 through the plurality of drain holes 2 formed in the drainage section 1a.

Further, the rainwater flowing from the upper surface of the solar cell panel 20 to the upper surface of the eaves cover member 1 is reliably caught by the drainage groove 1c, and the caught rainwater is passed to the eaves bowl 11 through the plurality of drainage holes 2 ... Since it can flow, it can prevent reliably that rainwater flows down from the outer edge part of the eaves cover material 1 downward.

In addition, rainwater flowing from the upper surface of the solar cell panel 20 to the end of the wife 10 on the roof 10 is allowed to flow to the wife side ridge 14 through the plurality of drain holes 4 of the wife side cover member 3. In addition, since rainwater can flow to the eaves wall 11 through the wife side fence 14, rainwater can be reliably prevented from flowing down from the end of the roof 10 on the wife side.

According to the present invention, the eaves cover material that shields the portion between the eaves end of the solar cell panel and the outer edge of the eaves has a plurality of drain holes that penetrate the eaves cover material in the thickness direction. Therefore, rainwater flowing from the upper surface of the solar cell panel toward the eaves can be flowed to the eaves through the plurality of drain holes of the eaves cover material.
In addition, outside air that enters the back side of the eaves cover material through a plurality of drain holes enters the back side of the eaves cover material, changes the angle toward the eaves ventilation port, and then flows into the ventilation layer through the eaves ventilation port Therefore, the outside air can surely flow into the ventilation layer.
In order for rainwater to enter the ventilation layer, it must enter the back side of the eaves cover with outside air, change the angle toward the eaves vent, and then enter the vent layer via the eaves vent. Since it is extremely difficult, it is possible to reliably prevent rainwater from entering the ventilation layer together with the outside air even during strong wind and rain. That is, it is possible to reliably allow the outside air to flow into the ventilation layer while reliably preventing rainwater from entering the ventilation layer, and to exhibit sufficient waterproofness.
In addition, the rainwater, which has a large amount of rain and could not flow from the plurality of drain holes of the eaves cover material, flows from the eaves side drainage groove to the eaves, and further from the upper surface of the solar cell panel toward the end of the wife side. The flowing rainwater can be flowed from the wife side wall to the eaves wall by the wife side cover material.

It is sectional drawing which shows an example of the roof structure which concerns on this invention. It is a perspective view of the roof structure shown in FIG. It is a perspective view which shows an eaves edge cover material, a wife side cover material, and an outward bending cover material. It is a perspective view which shows a bend outside curve. It is a disassembled perspective view which shows an eaves cup. It is a perspective view which shows an eaves cup. It is sectional drawing which shows the wife side edge part of a roof. It is sectional drawing which shows the ridge part of a roof.

Embodiments of the present invention will be described below with reference to the drawings.
In this embodiment, a panel method is used in which components such as walls, floors, and roofs are pre-panelized at the factory, and these panels are assembled at the construction site to construct a building. This can also be applied to buildings such as wooden structures, steel structures, and reinforced concrete structures.
In addition, the panel is composed of vertical and horizontal saddles assembled in a rectangular shape, and auxiliary bars are assembled vertically and horizontally inside a rectangular frame to form a frame, and face materials are formed on both sides or one side of the frame. It is affixed and has an internal hollow structure. Furthermore, a heat insulating material such as glass wool or rock wool is usually loaded into the hollow interior portion.

FIG. 1 is a sectional view showing an example of a roof structure according to the present invention.
In FIG. 1, the code | symbol 10 shows a roof. The roof 10 is configured as a gable roof having a ridge 10A and two roof surfaces 10B and 10B that are arranged on both sides of the ridge 10A and are inclined from the ridge 10A toward the eaves. .
On the roof surface 10B on one side of the roof surfaces 10B, 10B on both sides of the ridge 10A, the solar cell panel 20 is installed in a state in which the ventilation layer 30 is interposed between the roof surface 10B. That is, the ventilation layer 30 is formed between the roof 10 and the solar cell panel 20. In addition, an eaves vent hole 31 is provided at the eaves side end of the ventilation layer 30.
Further, as shown in FIG. 8, a plurality of roofing materials 18 such as slate are provided on the other roof surface 10B from the ridge 10A of the roof 10 to the eaves side.
And between the eaves side edge part of the said solar cell panel 20 and the outer side edge part of the eaves rod 11, the part between these eaves side edge parts of the solar cell panel 20 and the outer edge part of the eaves wall 11 is provided. The eaves edge cover material 1 to be shielded is provided, and the eaves edge cover material 1 is formed with a plurality of drain holes 2 penetrating the eaves edge cover material 1 in the thickness direction.

Here, as shown in FIGS. 1 and 7, the roof 10 has an eaves-end side end and a building-side end separated from the outer wall W of the building, and there is an eaves-out (keraba out). It is in a state.
The roof 10 is provided with an adjusting material 10a for forming a vertical surface at the eaves side end at the eaves side end, and an adjustment material for adjusting the protrusion of the keraba at the end of the wife. 10c and 10c are attached.
Further, a moisture permeable waterproof sheet 10b is attached to the upper surface of the roof 10 so as to cover the upper surface of the roof 10 and the adjusting materials 10a, 10c, 10c.
Furthermore, on the upper surface of the eave end side end portion of the roof 10 (the eave end side end portion of the roof surface 10B), the front end protrudes toward the eave end side from the adjustment material 10a, and the front end is formed in a hook shape. A drainer 10d is attached.

And the eaves hook 11 is attached to the vertical surface of the adjustment material 10a attached to the eaves edge part, as shown in FIG.1, FIG5 and FIG.6.
The eaves bowl 11 is formed by bending a metal plate so as to have a substantially inverted trapezoidal shape in a side view, and the building side edge and the outer edge are bent so as to be wound inside. ing.
The eaves rod 11 is attached to the adjusting material 10a via a bracket 11b fixed to the adjusting material 10a. The bracket 11b is formed in accordance with the shape of the eaves rod 11, and a pair of members are overlapped to constitute one bracket 11b.

In addition, the eaves rods 11 adjacent to each other in the length direction are joined together by an inner joint 11c attached to the inner peripheral surface of the connecting portion of the adjacent eaves rods 11 and an outer joint 11d attached to the outer peripheral surface. Further, an eaves anchor stop 11e having a bottom wall having an upward slope is connected to the end of the eaves anchor 11.
Also, the eaves rod 11, the bracket 11b, the outer joint 11d, and the eaves rod stop 11e are covered with the eaves cover 11a so that the eaves rod 11 and the like are not visible when viewed from below. It has become.

Further, as shown in FIG. 1, a ventilation member 12 is attached to the vertical surface of the adjusting member 10 a so as to be connected to the eaves cover 11 a and perform ventilation on the back of the eaves.
The ventilation member 12 includes a ventilation portion 12a that is positioned below the adjustment material 10a and that is disposed with a gap 12b between the side wall of the roof cover 11a and the building.
In addition, a plurality of ventilation holes 12c opened in the gap 12b are arranged on the side surface of the eaves cover 11a of the ventilation portion 12a along the length direction of the eaves end side end of the roof 10, that is, along the length direction of the eaves enclosure 11. It is installed.

A cutout portion 10 e is formed at the eaves-end side end portion of the roof 10 by cutting out a lower portion of the eaves constituting the roof 10. The notch 10e is used as a vent for communicating the ventilation member 12 and the back of the eaves.
In addition, the inside of the ventilation portion 12a is a gap, and the gap portion of the ventilation portion 12a is located between the plurality of ventilation holes 12c and the notch portion 10e.

In addition, an eaves ceiling 13 is provided on the lower surface of a portion protruding from the outer wall W on the eaves side of the roof 10.
The eaves ceiling 13 is provided on a lower surface of a portion protruding from the outer wall W via a field edge 13 a fixed to the lower surface of the roof material of the roof 10.
Further, the upper end of the eaves ceiling 13 in the inclination direction is covered with an eaves ceiling parting member 13b fixed to the field edge 13a. The lower end of the eaves ceiling 13 in the inclination direction can block the line of sight from below by the convex portion 12 d formed on the side surface of the ventilation member 12.

As shown in FIG. 7, a wife side collar 14 is attached to the adjustment member 10 c attached to the end of the roof 10 on the wife side.
The wife side flange 14 is formed by bending a metal plate, and the lower end portion communicates with the eaves flange 11.
Further, the end of the wife 10 on the roof 10, the end of the end 14 and the adjusting members 10c and 10c are covered with the blast 14a. There is no such thing.

Further, a ventilation member 14b is attached to the lower surface of the end portion on the side of the roof 10 that is connected to the wind blast 14a to ventilate the eaves.
The ventilation member 14b is arranged with a gap 14c and a side surface of the building of the gust 14a. A ventilation hole 14d opening in the gap 14c is provided on the side of the gust 14a of the ventilation member 14b. A plurality are arranged along the length direction of the end.

Further, a climbing eave ceiling 16 is provided on the lower surface of the portion protruding from the outer wall W on the wife side of the roof 10.
The climbing eaves ceiling 16 is provided on the lower surface of the portion protruding from the outer wall W via a field edge 16 a fixed to the lower surface of the roof material of the roof 10.
Moreover, the building side edge part of the climbing eave ceiling 16 is covered with the eaves parting material 16b fixed to the field edge 16a. The end of the climbing eaves ceiling 16 on the side of the blast 14a can block the line of sight from below by the convex portion 14e formed on the side surface of the ventilation member 14b.

As shown in FIGS. 2 and 4, the blast wind 14a and the heel cover 11a are connected by a blast wind bend 15 connected to the lower end of the gust 14a in the inclination direction and the end of the heel cover 11a. ing.
Inner joints 15a for connecting the windbreak external bend 15, the windbreak 14a, and the coffin cover 11a are respectively attached to the end portion of the windbreak 11b side and the end portion of the windbreak 14a. .
Further, the portion where the side of the heel cover 11a and the side of the breezes 14a contact each other is formed at an angle of 45 degrees, and when these two members are brought into contact with each other, the angle is 90 degrees. It is set to become. In addition, the angle of this windbreak outer curve 15 can be suitably changed according to the shape of a roof.

  As the solar cell panel 20 installed on the roof surface 10B on the one side, for example, a plurality of photovoltaic cell substrates called solar cells are bonded to white plate tempered glass or transparent resin plate having a thickness of about 4 to 5 mm. Thus, an element mainly composed of single crystal or polycrystalline silicon or an element mainly composed of amorphous silicon is adopted as an element for generating a photovoltaic force.

A rectangular frame-shaped frame 21 surrounding the periphery is provided on the periphery of the solar cell panel 20.
In addition, the solar cell panel 20 is arrange | positioned at intervals with the said eaves 11. In other words, the eaves drainer 10d attached on the roof surface 10B is exposed between the eaves end of the solar cell panel 20 and the eaves 11 without being covered by the solar cell panel 20.

  As shown in FIGS. 1 and 7, the frame 21 includes a pair of vertical frame portions 22, 22 arranged on the left and right along the inclination direction of the roof 10, and upper and lower ends of the vertical frame portions 22, 22. The upper frame part 23 and the lower frame part 24 which are connected and arrange | positioned along the girder direction of the roof 10 are provided. The vertical frame portion 22, the upper frame portion 23, and the lower frame portion 24 waterproof and reinforce the solar cell panel 20.

As shown in FIG. 1, the upper frame portion 23 is a long member integrally formed by aluminum extrusion or the like, and includes a pair of projecting pieces 23 a and 23 a into which the solar cell panel 20 is fitted.
Similarly, the lower frame portion 24 is a long member integrally formed by aluminum extrusion or the like, and includes a pair of projecting pieces 24a and 24a into which the solar cell panel 20 is fitted.

On the other hand, as shown in FIG. 7, the vertical frame portion 22 is a long member having a substantially L-shaped cross section, and a pair of vertical frame portions 22, 22 arranged on the left and right along the inclination direction of the roof 10 The support rails 25 are fixed to the roof surface 10B. Each vertical frame portion 22, 22 includes a pair of protruding pieces 22 a, 22 a into which the solar cell panel 20 is fitted, similar to the above-described upper frame portion 23 and lower frame portion 24. Each of the vertical frame portions 22 and 22 includes fixed pieces 22b and 22b fixed to the support rail 25.
In addition, the pair of vertical frame portions 22 and 22 arranged on the left and right has an opening formed on the upper surface thereof, and a cover member 22c is attached to the opening with a screw.

The solar cell panel 20 provided with the frame 21 as described above at the periphery is supported by a support rail 25 with a ventilation layer 30 interposed between the roof surface 10B.
The support rails 25 are long ones that extend from the eaves of the roof 10 toward the ridge on the roof surface 10B. A plurality of the support rails 25 are provided at predetermined intervals in the ridge direction, and adjacent support rails 25, The solar cell panel 20 is supported by 25.
As shown in FIG. 7, the support rail 25 supports the support rail 25 and is formed on both ends of the support rail 25 along the longitudinal direction of the support portion 26 that is fixed on the roof surface 10 </ b> B with screws. The water stop part 27 which prevents the rain water etc. which should have entered from between the solar cell panel 20 and the cover member 22c falling on the roof surface 10B is provided.

The solar cell panel 20 configured as described above is attached to the roof surface 10B as follows.
That is, the frame 21 is attached to the solar cell panel 20 by fitting the peripheral edge portion thereof into the pair of projecting pieces 22a, 23a, 24a of the vertical frame portions 22, 22, the upper frame portion 23, and the lower frame portion 24. ing. Further, as shown in FIG. 7, a support rail 25 is attached on the roof surface 10 </ b> B by fixing the support portion 26 with screws, and the vertical frame portion 22 is supported by the support rail 25. Thus, the solar cell panel 20 is attached.
Thus, the solar cell panel 20 is provided in a state in which the ventilation layer 30 is interposed between the solar cell panel 20 and the roof surface 10B.

Further, as shown in FIG. 1, the ventilation layer 30 is formed along the longitudinal direction of the support rail 25, and the eaves side of the ventilation layer 30 opens toward the eaves 11. It is a mouth 31.
As shown in FIGS. 1 and 7, the eaves vent hole 31 is surrounded by the roof surface 10 </ b> B, a lower frame portion 24 near the eaves of the frame 21, and support rails 25, 25 adjacent to the left and right. It points to the part. Further, as described above, since the solar cell panel 20 is arranged with a space from the eaves bowl 11, the eaves vent hole 31 is also arranged with a gap from the eaves bowl 11.

The lower space of the eaves cover member 1 that shields the portion between the eaves end of the solar battery panel 20 and the outer edge of the eaves ridge 11 is a ventilation path 32 that communicates with the eaves vent 31. ing. That is, the air passage 32 is formed between the eaves end of the solar cell panel 20 and the eaves 11 so as to be positioned below the eaves cover 1.
The air passage 32 is shielded by a water supply portion 1b in which a plurality of drain holes 2 are not formed. That is, this water supply part 1b becomes the roof of the ventilation path 32, and prevents intrusion of rainwater.

The eaves edge cover material 1 is formed by bending a metal plate, as shown in FIGS. 1 to 3, and is located above the eaves ridge 11 and has a plurality of drain holes 2. The drainage portion 1a, the water supply portion 1b that is located above the ventilation path 32 and is not formed with a plurality of drain holes 2, and is located at the building side edge of the eaves cover 1 and is integrally formed with the water supply portion 1b. And a support portion 1e that supports the eaves edge cover material 1 on the roof surface 10B.
The drainage portion 1a has a drainage groove 1c formed along the outer edge of the drainage portion 1a and deeper than the upper surface of the drainage portion 1a.
The covering portion 1d is fixed to the lower frame portion 24 so as to cover the upper surface of the lower frame portion 24 in the vicinity of the eaves edge of the frame 21, and the outer edge portion of the eaves edge covering material 1 is It is fixed to the outer edge of the cover 11a.

The plurality of drain holes 2 are a plurality of flat drain holes 2a provided in a flat portion of the drain part 1a where the drain groove 1c is not formed, and the drain groove 1c of the drain part 1a. It is assumed that the plurality of groove drain holes 2b...
The plurality of flat drain holes 2a are arranged vertically and horizontally in the flat portion of the drain part 1a, and the plurality of groove drain holes 2b are arranged along the length direction of the drain groove 1c. It is installed side by side.
The groove drain holes 2b are formed by cutting out a metal plate constituting the eaves edge cover material 1 in a substantially L shape from the bottom wall constituting the drain groove 1c to the building side wall similarly constituting the drain groove 1c. It is formed in this way.

  A plurality of the eaves cover materials 1 as described above are arranged in parallel along the length direction of the eaves. Moreover, when providing the eaves edge cover material 1 between the eaves edge part of the said solar cell panel 20, and the outer edge part of the eaves eaves 11, the said support part 1e is installed in the said eaves edge drainer 10d upper surface. . And while fixing an outer edge part to the outer edge part of the said eaves cover 11a, fixing the said coating | coated part 1d to the lower frame part 24 near the said eaves edge | end | tip, the eaves side edge part of the said solar cell panel 20 And the outer edge of the eaves 11.

On the other hand, between the end portion of the solar cell panel 20 and the outer edge portion of the end surface 14, as shown in FIG. 2, FIG. 3 and FIG. A wife side cover material 3 is provided to shield a portion between the outer edge of the wife side collar 14 and the outer side edge part.
Further, a plurality of drain holes 4 are formed in the wife side cover member 3 so as to penetrate the wife side cover member 3 in the thickness direction. The rainwater flowing from the upper surface of the solar cell panel 20 to the upper surface of the wife side cover member 3 flows down from the plurality of drain holes 4 to the wife side rod 14, and the rainwater flowing down to the wife side rod 14 is It flows to the eaves bowl 11.

The wife side cover material 3 is formed by bending a metal plate, is located at the drainage groove 3a formed along the outer edge and the building edge, and is the end of the roof 10 on the wife side. And a covering portion 3b that covers the upper surface of the vertical frame portion 22 in the vicinity of the portion.
Further, the covering portion 3b of the wife side cover member 3 is fixed to the vertical frame portion 22, and the outer edge portion of the wife side cover member 3 is fixed to the outer edge portion of the windbreak 14a.
It is assumed that the drainage groove 3a communicates with a drainage groove 5c formed in the outer curved cover material 5 described later. Moreover, according to this drainage groove 3a, the rain water which flows from the solar cell panel 20 side of the wife side cover material 3 to the outer edge part of the wife side cover material 3 can be reliably caught.

Moreover, the said eaves edge cover material 1 and the wife side cover material 3 are each connected to the edge part of the eaves edge cover material 1, and the inclination direction lower end part of the wife side cover material 3, as shown in FIG.2 and FIG.3. They are connected by an outer bend cover material 5. Further, the outer bent cover member 5 is formed with a plurality of drainage holes 6 penetrating the outer bent cover member 5 in the thickness direction.
In addition, as shown in FIG. 3, the outer bent cover member 5 and the end portion of the end cover member 3 are connected by a joint 7. Further, the outer bent cover material 5 and the eaves cover material 1 are connected by a connection tool (not shown).

  Further, the outer bent cover material 5 is formed by bending a metal plate and is formed in a substantially L shape in plan view. And the drainage part 5a in which the some drainage hole 6 ... was formed while being located above the said eaves rod 11 and the wife side collar 14, and the some drainage hole 6 ... was formed in the upper direction of the said ventilation path 32. The water supply part 5b which is not performed is provided. The drainage portion 5a has a drainage groove 5c formed along the outer edge of the drainage portion 5a and deeper than the upper surface of the drainage portion 1a. The drainage groove 1c of the eaves edge cover material 1 and the drainage groove 3a of the wife side cover material 3 communicate with each other.

  In addition, the outer bent cover material 5 includes an eaves side covering portion 5d that covers the upper surface of the lower frame portion 24 in the vicinity of the eaves edge of the frame 21 together with the covering portion 1d of the eaves edge cover material 1, and the wife side cover material 3 A cover side 3e that covers the upper surface of the vertical frame portion 22 near the end of the end of the roof 10 together with the cover 3b, and a support 5f that supports the outer curved cover material 5 on the roof surface 10B are provided. Yes.

  The outer bent cover material 5 as described above fixes the outer edge portions to the outer edge portions of the eaves cover 11a and the breezes 14a, and the eaves side covering portion 5d is fixed to the lower frame portion 24 in the vicinity of the eaves edge. And fixing the wife side covering portion 5e to the vertical frame portion 22 in the vicinity of the wife side end portion of the roof 10, whereby the end portion of the eaves edge cover material 1 and the inclination direction of the wife side cover material 3 are fixed. It is provided between the lower end portions.

The plurality of drain holes 6... Are a plurality of flat drain holes 6 a provided in a flat part of the drain part 5 a where the drain grooves 5 c are not formed, and the drain groove 5 c of the drain part 5 a. The plurality of drainage holes 6b for grooves provided in the portion are indicated.
The plurality of flat drain holes 6a are juxtaposed vertically and horizontally in the flat portion of the drain part 5a, and the plurality of groove drain holes 6b are arranged along the length direction of the drain groove 5c. It is installed side by side.
The groove drain holes 6b are also formed in a substantially L-shape, similar to the groove drain holes 2b.

Note that the ridge 10 </ b> A of the roof 10 is covered with a ridge wrap 17.
The ridge wrap 17 is fixed on the roof surfaces 10B and 10B, and is fixed to a plurality of base materials 17a that are long along the ridge direction.
On the roof surface 10B side on which the roof material 18 is installed, one base material 17a is provided on the upper surface of the roof material 18 disposed in the vicinity of the ridge 10A. A drainer 17d is attached to the base material 17a to cover the upper surface and the eaves side of the base material 17a. Furthermore, another base material 17a is provided on the base material 17a to which the drainer 17d is attached so as to correspond to the shape of the ridge wrap 17.

On the other hand, on the side of the roof surface 10B where the solar cell panel 20 is installed, two heights are provided so as to correspond to the base material 17a provided on the roof surface 10B on the roof material 18 side and attached with a drainer 17d. The base materials 17a and 17a are provided so as to overlap each other.
A drainer 17b connected to the upper frame portion 23 of the frame 21 provided around the solar cell panel 20 is attached to the base materials 17a and 17a. The drainage 17b can cover the gap formed between the ridge wrap 17 and the solar cell panel 20.
The upper frame portion 23 in the vicinity of the ridge portion 10A is joined to a frame fixture 28 which is formed in a substantially L shape in cross section and is fixed to the roof surface 10B. Further, the ridge 10A side opening of the ventilation layer 30 is closed by the frame fixture 28.

Furthermore, another base material 17 a is provided on the base materials 17 a and 17 a so as to correspond to the shape of the ridge wrap 17.
The ridge wrap 17 is fixed to the plurality of base materials 17a so as to wrap the plurality of base materials 17a provided in the ridge portion 10A as described above.

Next, the flow of rainwater and the flow of air when raining on the roof 10 will be described.
First, rainwater that has poured onto the roof surface 10B on which the roofing material 18 is installed flows on the surface of the roofing material 18 toward the eaves side and the wife side. Note that a wind break (not shown) is attached to the end of the roof 10 on the roof surface 10B side where the roofing material 18 is installed so that rainwater does not flow downward from the end of the end of the roof 10. It has become.

Subsequently, rainwater that has poured onto the roof surface 10B on which the solar cell panel 20 is installed flows on the surface of the solar cell panel 20 toward the eaves side and the wife side.
Rainwater that has flowed to the wife side flows down from the plurality of drain holes 4 of the wife side cover material 3 to the wife side rod 14, and the rainwater that has flowed down to the wife side rod 14 flows to the eaves wall 11.
Further, the drainage groove formed in the outer bent cover material 5 by catching rainwater flowing from the solar cell panel 20 side of the wife side cover material 3 to the outer edge of the wife side cover material 3 by the drainage groove 3a. It is also possible to flow to 5c.

Further, the rainwater that has flowed to the eaves side flows over the water supply part 1 b of the eaves edge cover material 1 and the upper surface of the water supply part 5 b of the outer curve cover material 5, while The plurality of flat drain holes 2a ..., 6a ... formed in the drain 5a flow down to the eaves bowl 11.
Further, the rainwater flowing on the upper surfaces of the drainage portions 1a and 5a is caught by the drainage grooves 1c and 5c, and from the drainage holes 2b, 6b, formed in the drainage grooves 1c, 5c to the eaves 11 respectively. Can be flowed.
The rainwater that has flowed down to the eaves wall 11 flows to the ground or a drainage channel through a wall (not shown) connected to the eaves wall 11.

On the other hand, air flows from the plurality of drain holes 2 of the eaves edge cover material 1 and the plurality of drain holes 6 of the outer curve cover material 5 to the back side of the eaves edge cover material 1 and the outer curve cover material 5. After entering and changing the angle toward the eaves vent hole 31, the air flows into the vent layer 30 through the eaves vent hole 31.
The fallen leaves falling on the roof 10 are difficult to pass through the plurality of drain holes 2, 4, 6, and so on, and even if they enter the back side of the eaves cover material 1 etc., they are angled toward the eaves vent 31 Since it is necessary to enter the ventilation layer 30 through the eaves vent hole 31 after changing the air flow, it is extremely difficult to enter the ventilation layer 30 together with air.
Moreover, even if relatively small dust or rainwater that is not as large as the fallen leaves enters the back side of the eaves cover material 1 or the like, the air-permeable layer is changed through the eaves vent 31 after changing the angle to the eaves vent 31. It is extremely difficult to enter the ventilation layer 30 together with the air because it has to enter the inside 30.
Furthermore, since an air passage 32 is formed between the eaves end of the solar cell panel 20 and the eaves 11, in order for rainwater, dust, etc. to enter the air layer 30, this air passage is used. 32 must rise with the outside air, and it becomes even more difficult to enter the ventilation layer 30.
As described above, it is possible to allow outside air to flow into the ventilation layer 30 while preventing rainwater from entering the ventilation layer 30.

According to the present embodiment, rainwater flowing from the upper surface of the solar cell panel 20 toward the eaves can be caused to flow to the eaves 11 through the plurality of drain holes 2 of the eaves cover 1.
Also, outside air that enters the back side of the eaves cover material 1 through the plurality of drain holes 2... Enters the back side of the eaves cover material 1, changes the angle toward the eaves ventilation port 31, and then opens the eaves ventilation port 31. Therefore, the outside air can surely flow into the ventilation layer 30.
In order for rainwater to enter the ventilation layer 30, it enters the back side of the eaves cover material 1 together with outside air, changes the angle toward the eaves ventilation port 31, and then enters the ventilation layer 30 through the eaves ventilation port 31. Since it is extremely difficult, it is possible to reliably prevent rainwater from entering the ventilation layer 30 together with the outside air even during a strong wind and rain. That is, it is possible to surely allow outside air to flow into the ventilation layer 30 while reliably preventing rainwater from entering the ventilation layer 30, and to exhibit sufficient waterproofness.

Moreover, since the ventilation path 32 is formed between the eaves side edge part of the solar cell panel 20 arrange | positioned at intervals, and the eaves cage | basket 11, the eaves edge cover material 1 via the said several drain hole 2 ... The outside air that enters the back side of the air can flow into the ventilation layer 30 after passing through the ventilation path 32.
Therefore, in order for rainwater to enter the ventilation layer 30, it enters the back side of the eaves cover material 1 together with outside air, changes the angle toward the eaves vent 31, passes through the ventilation path 32, and then eaves vent 31. It is extremely difficult to enter the ventilation layer 30 via For this reason, it is possible to more reliably prevent rainwater from entering the ventilation layer 30 together with the outside air even during a strong wind and rain.

Moreover, since the eaves edge cover material 1 is provided with the water supply part 1b which is located above the said air flow path 32 and is not formed with the some drainage hole 2 ..., the air flow path 32 is reliably shielded by this water supply part 1b. be able to.
As a result, the rainwater flowing from the upper surface of the solar cell panel 20 toward the eaves flows through the upper surface of the water supply portion 1b, so that the rainwater can be guided to the drainage portion 1a by the water supply portion 1b. Rainwater can be more reliably flowed to the eaves 11 through the plurality of drain holes 2 formed in the drainage section 1a.

  Further, rainwater flowing from the upper surface of the solar cell panel 20 to the upper surface of the eaves cover member 1 is reliably caught by the drainage groove 1c, and the caught rainwater is passed to the eaves bowl 11 through the plurality of drainage holes 2 ... Since it can flow, it can prevent reliably that rainwater flows down from the outer edge part of the eaves cover material 1 downward.

  In addition, rainwater flowing from the upper surface of the solar cell panel 20 to the end of the end of the roof 10 can flow to the end of the end 14 through the plurality of drain holes 4 of the end cover 3. Furthermore, since rainwater can be flowed to the eaves wall 11 through the wife side fence 14, rainwater can be reliably prevented from flowing down from the end of the roof 10 on the wife side.

1 eaves cover 2 drainage hole 10 roof 11 eaves 20 solar panel 30 vent layer 31 eaves vent 32 vent

Claims (1)

A solar cell panel that receives sunlight is installed on the upper surface of the gable roof, and a ventilation layer is formed between the roof and the solar cell panel,
The eaves side is attached to the eaves side end of the roof,
An eaves vent is provided at the eaves end of the ventilation layer,
Between the eaves side end of the solar cell panel and the outer edge of the eaves eaves, an eaves cover material that shields a portion between the eaves side end of the solar panel and the outer edge of the eaves is provided. It is provided so as to cover the eaves vent ,
Wherein the eaves side end of the eaves gutter of the solar cell panel are spaced apart,
Between the eaves side end portion of the solar cell panel and the eaves eaves, an air passage that is located below the eaves cover material and communicates with the eaves vent of the vent layer is formed ,
The eaves edge cover material is located above the eaves eaves and has a drainage portion formed with a plurality of drainage holes penetrating the eaves edge cover material in the thickness direction, and located above the air passage and a plurality of drainage holes. And a water supply section where a drain hole is not formed,
The drainage section has a drainage groove formed deeper than the upper surface of the drainage section along the outer edge of the drainage section, and the drainage groove has a plurality of drainage holes for allowing rainwater to flow into the eaves. ,
And the lower end is attached to the end side of the wife side of the roof, and the end of the end of the roof is attached to the end of the eaves.
A wife side cover that shields a portion between the wife side end of the solar cell panel and the outer edge of the wife side collar between the wife side end of the solar cell panel and the outer edge of the wife side collar. Materials are provided,
In the wife side cover material, a plurality of drain holes penetrating the wife side cover material in the thickness direction and drain grooves along the outer edge are formed above the wife side collar,
Furthermore, the lower end of the wife side collar is communicated with the eaves eaves, and the eaves edge cover material and the wife side cover material are respectively connected to an end portion of the eaves edge cover material and a lower end portion in the inclination direction of the wife side cover material. Are connected by an outer bent cover material having a substantially L shape in plan view, and the outer bent cover material is formed with a plurality of drain holes and drain grooves that penetrate the outer bent cover material in the thickness direction, A roof structure characterized in that the drainage groove of the eaves edge cover material and the drainage groove of the wife side cover material communicate with each other through the drainage groove of the outer curved cover material .

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