JP5551293B1 - Ventilation structure - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a ventilation structure having a high waterproof function, such as a ventilation building installed on a single-flow roof of a metal roof material having a low gradient.
SOLUTION: A ventilation wing 5 is configured around a first member 10, a ventilation member 30 installed on the first member 10, and a second member 20 installed so as to cover the ventilation member 30. Yes. A first corner part 78, a second corner part 79, and a third corner part 80, which change the ventilation direction at right angles, are formed in the ventilation path of the ventilation building 5. Further, in the third corner portion 80 serving as the specific corner portion, the protruding piece 41 extends from the inner corner 81 toward the outer corner 82 so as to block a part of the third corner portion 80. . As a result, rainwater that has entered through the vent 47 is inverted outward by the protruding piece 41, so that the waterproof effect is improved.
[Selection] Figure 6

Description

  The present invention relates to a ventilation structure and, for example, relates to a ventilation structure such as a ventilation building attached to a roof in order to achieve natural ventilation in a shed space in a house.

  Various ventilation structures such as a ventilation building mounted on a roof have been proposed. By the way, in the case of a metal roof using metal as a roofing material, the roof slope is often set to be lower than usual, so rainwater may enter the ventilation building along the roof surface. In order to solve such a problem, the ventilation building disclosed in Patent Document 1 will be described below.

  FIG. 8 is a schematic perspective view showing the state of attachment of the ventilation building disclosed in Patent Document 1 to the metal roof, and FIG. 9 is a schematic perspective view showing the external shape of the ventilation building shown in FIG. FIG. 10 is an enlarged cross-sectional view taken along line XX shown in FIG.

  Referring to these drawings, the single-flow roof 61 has a base plate 65 that is inclined only on one side. An opening 66 is formed in the base plate 65 near the top of the single-flow roof 61. A mounting base 93 is fixed to the upper surface of the base plate 65 across the opening 66 at a position below the opening 66 on the flow side, and a top support base 94 is fixed to the end surface of the top portion of the base plate 65. Has been. The ventilation ridge 96 is covered so as to cover the opening 66 from above in accordance with the center of the opening 66.

  The ventilation building 96 has a lower plate 100 that is placed and fixed on the mounting base 93, an upper plate 108 that can substantially cover the upper portion of the lower plate 100, and a fixed interval between the lower plate 100 and the upper plate 108. And the baffle plate 121 held in the center.

  The lower plate 100 includes a main body 101 mounted on the mounting base 93, a guide plate 102 extending obliquely upward from the main body 101 toward the upper direction of the single-flow roof 61, and a lower portion of the single-flow roof 61 following the guide plate 102. And a guide plate 103 extending to the right. Therefore, when the ventilation building 96 is fixed to the mounting base 93, air from the opening 66 is guided to the path between the lower plate 100 and the upper plate 108.

  Further, a storm plate 116 rising upward is formed at the lower edge of the main body 101 in the flow direction of the single-flow roof 61.

  The upper plate 108 includes a main body 109 that widely covers the upper portion of the opening 66 of the base plate 65, a ridge covering plate 110 that extends downward from the upper edge in the flow direction of the single-flow roof 61 of the main body 109, and the single-flow roof 61 of the main body 109. And a shielding plate 111 bent into a side L shape from the lower edge in the flow direction. A large number of exhaust ports 112 are formed in the shielding plate 111 at regular intervals in the width direction.

  On the other hand, the baffle plate 121 is positioned between the three contact plates 122a, 122b, and 122c that alternately contact the back surface (lower surface) of the upper plate 108 and the upper surface of the lower plate 100, and the contact plates 122a, 122b, and 122c. Two partition plates 124a and 124b, and a shielding plate 126 extending downward from the lower edge of the one-flow roof 61 in the flow direction of the contact plate 122c are provided. The adjacent two partition plates 124a and 124b are formed with a large number of vent holes 128a and 128b at predetermined intervals in the width direction at positions that alternate in the height direction.

A roofing material 115 is attached to the lower surface of the mounting base 93 on the flow side and the upper surface of the base plate 65. Further, from the top of the roofing material 68, the metal roofing material 62 is rolled up until it hits the lower surface of the mounting base 93 on the flow side, and a draining plate 114 bent in an inverted L shape is attached between them. Thus, rainwater from the eaves direction is prevented from entering from the abutting portion between the mounting base 93 and the metal roof material 62.
In addition, by providing a storm plate 116 that rises above the lower plate 97 outside the exhaust port 112, rainwater is prevented from flowing into the discharge port 112 from the eaves direction of the single-flow roof 61.

JP 2010-248819 A

  In the conventional ventilation building as described above, inflow of rainwater that has traveled through the metal roofing material 62 by the drainage board 114 and storm panel 116 can be prevented, but direct intrusion of rainwater from the discharge port 112 can be sufficiently prevented. It is not possible and the waterproof performance is insufficient.

  The present invention has been made to solve the above-described problems, and provides a ventilation structure having excellent waterproof performance, such as a ventilation building that can exhibit high waterproof performance even when installed on a low-gradient roof. The purpose is to do.

In order to achieve the above object, the invention according to claim 1 is a ventilation structure having a corner portion that is formed in the middle of the ventilation path and changes in a ventilation direction at a right angle. The ventilation structure is made of a metal roof. A projecting piece that extends from the inner corner to the outer corner is formed so as to block a part of the specific corner portion in the specific corner portion of the corner portion including the ventilation ridge attached on the top. The protruding length of the protruding piece is set to a distance from 1/4 to 1/3 of the distance from the inner corner to the outer corner, and the corner portion is from the outer opening position. At least three or more locations are formed continuously, and the specific corner portion corresponds to the third corner portion from the outside, and the first corner portion of the corner portion is a flange portion and a flange disposed along the metal roof Stand upward from the outer edge of the Is constituted by a raised vertical portion, further, the upper end of the vertical portion, in which the inclined plate which is inclined toward the metal roof is connected.

If comprised in this way, while a protrusion piece will expand the resistance at the time of rain water penetration | invasion, it will not become excessive ventilation resistance. Moreover, the rainwater which invaded reverses outward by the protruding piece. Furthermore, the rainwater that is about to enter along the metal roof jumps upward by the inclined plate.

According to a second aspect of the invention, in the structure of the invention of claim 1 Symbol placement, the passing air path has a bar shape extending in the longitudinal direction so as to cross the vent path, from one side in the lateral direction A ventilation member provided with a plurality of ventilation holes penetrating to the other side surface is installed.

  If comprised in this way, the rainwater which penetrate | invades easily will be excluded by the protrusion piece and the ventilation member.

As described above, according to the first aspect of the present invention, since the protruding piece increases the resistance when the rainwater enters, the waterproof effect is improved. Further, since the protruding piece does not have excessive ventilation resistance, an efficient ventilation effect and a waterproof effect are exhibited. Furthermore, since the rainwater that has entered is reversed outward by the protruding piece, the waterproof effect is further improved. Furthermore, since rainwater trying to invade along the metal roof jumps upward by the inclined plate, direct intrusion of rainwater along the metal roof is reduced.

The invention of claim 2, wherein, in addition to the effect of the invention of claim 1 Symbol placement, the protruding piece and ventilation member, since intrusion easily rainwater is eliminated, the reliability by improving the waterproof effect of the ventilation building Will improve.

1 is a schematic exploded perspective view of a ventilation building according to a first embodiment of the present invention. It is an expanded sectional view of the II-II line shown in FIG. It is the schematic perspective view which showed the external appearance shape of the ventilation member shown in FIG. It is a general | schematic exploded end view which showed the attachment process to the metal roof material of the ventilation building shown in FIG. It is the schematic end elevation which showed the attachment state to the metal roof material of the ventilation building shown in FIG. FIG. 6 is an enlarged view of a portion “X” shown in FIG. 5. It is a schematic diagram which shows roughly the waterproofing effect of the ventilation building shown in FIG. 1 compared with the conventional structure. It is the schematic perspective view which showed the attachment state to the metal roof material of the ventilation building disclosed by patent document 1. FIG. It is the schematic perspective view which showed the external appearance shape of the ventilation building shown in FIG. It is an expanded sectional view of the XX line shown in FIG.

  FIG. 1 is a schematic exploded perspective view of a ventilation building according to the first embodiment of the present invention, and FIG. 2 is an enlarged sectional view taken along line II-II shown in FIG.

  With reference to these drawings, the ventilation building 5 includes a first member 10 formed by pressing a steel plate, a ventilation member 30 installed on the first member 10, and a ventilation member as indicated by arrows in the figure. It is mainly comprised from the 2nd member 20 formed by the press work of the steel plate installed so that 30 may be covered.

  The first member 10 has an opening portion 17a to 17d formed in a substantially central portion thereof, a flat surface 11 extending obliquely downward in the width direction in a parallel state to a metal roof material (not shown), and an outer wall (not shown). A hanging surface 12 installed on the outer side and extending vertically downward from the apex of the flat surface 11, and a first vertical portion 13 connected to an outer end facing the hanging surface 12 of the flat surface 11 and extending vertically downward , Connected to the lower end of the first vertical portion 13 and extending outwardly in parallel with the flat surface 11, and connected to the outer end of the flange portion 14 and vertically upward in parallel with the first vertical portion 13 The second vertical portion 15 extends in the direction from the top and the inclined plate 16 extends obliquely downward outward from the apex of the second vertical portion 15. A plurality of mounting holes (not shown) for inserting a fixing nail or the like to be described later are formed in the end of the flat surface 11 on the first vertical portion 13 side in the longitudinal direction.

  The ventilation member 30 is installed on the upper surface of the flat surface 11 closer to the first vertical portion 13 than the opening portions 17a to 17d, has a rectangular cross section in the width direction, and extends in the longitudinal direction along the opening portions 17a to 17d. It is formed in a bar shape. The detailed structure of the ventilation member 30 will be described later.

  A draining member 38 extending in the longitudinal direction along the opening portions 17a to 17d is disposed on the opening portions 17a to 17d side of the ventilation member 30. Here, the draining member 38 is connected to the installation plate 39 installed on the upper surface of the flat surface 11, the end of the installation plate 39 on the opening portions 17 a to 17 d side, and extends vertically upward, and the vertical piece 40. And a projecting piece 41 extending obliquely outward from the end portion of the installation plate 39 facing the. Further, the partition plate 25 is fixed to the flat surface 11 with a rivet (not shown) at a position facing the draining member 38 through the opening portions 17a to 17d. Here, the partition plate 25 is connected to the end of the first plate portion 26 installed on the upper surface of the flat surface 11 and the first plate portion 26 on the opening portions 17a to 17d side, and extends vertically upward. 27, connected to the upper end portion of the second plate portion 27, connected to the third plate portion 28 extending parallel to the flat surface 11 in the direction of the suspended surface 12, and connected to the end of the third plate portion 28 on the suspended surface 12 side, The fourth plate portion 29 extends vertically downward. Furthermore, partition plates 31 a and 31 b formed so as to cover from the vicinity of the end in the longitudinal direction of the ventilation member 30 to the partition plate 25 are fixed to the flat surface 11 with rivets or the like. The effects of the partition plates 25, 31a, 31b will be described later.

  The ventilation member 30 is provided with a plurality of Ω-shaped metal bands 35 at predetermined intervals in the longitudinal direction so as to cover a part of the ventilation member 30. And the part which touches each flat surface 11 of the metal band 35 is being fixed to the flat surface 11 by the rivets 36a and 36b. Further, attachment holes 56 and 57 are formed on the upper surface of the metal band 35. The effect of the metal band 35 will be described later.

  The second member 20 has a flat plate portion 21 extending obliquely downward in the width direction in a parallel state with respect to the flat surface 11 of the first member 10 and an outer side of the hanging surface 12 of the first member 10 in the installed state. The flat surface 11 is connected to a first hanging portion 22 that extends vertically downward from the apex of the flat plate portion 21 and an outer end that faces the first drooping portion 22 of the flat plate portion 21, and is in an abutted state. And a second hanging portion 23 extending vertically downward toward the outer side position. In the flat plate portion 21, mounting holes 58 are formed at positions corresponding to the mounting holes 57 on the upper surface of the metal band 35 in the installed state.

  Next, the detailed structure of the ventilation member 30 will be described.

  FIG. 3 is a schematic perspective view showing the external shape of the ventilation member shown in FIG.

  Referring to the drawing, ventilation member 30 has a rectangular cross section in the width direction, and from the outer end of opening portion 17a shown in FIG. 1 to the outer end of opening portion 17d in the longitudinal direction. It has a rod shape having a length substantially the same as the distance. Specifically, the ventilation member 30 is connected and integrated with each other by thermal fusion in a state where a plurality of synthetic resin sheets each having an uneven cross-sectional shape are stacked. A plurality of vent holes 46 penetrating from one side surface to the other side surface in the short direction are formed.

  In the ventilation member 30 in this embodiment, the length A in the width direction of the rectangular cross-sectional shape is 18 mm, and the length B corresponding to the height is 10 mm. The vent hole 46 is set to have a rectangular opening size of approximately 1 mm × 4 mm. Such a ventilation member 30 has basically the same structure as the ridge cover material disclosed in Japanese Patent No. 2610342. Thus, under certain conditions, the ventilation member 30 can ventilate through the vent hole 46, and exhibits ventilation performance and waterproof performance to prevent rainwater from entering through the vent hole 46. .

  Next, attachment to the metal roof material of the ventilation building shown in FIG. 1 will be described.

  4 is a schematic exploded end view showing a process of attaching the ventilation building shown in FIG. 1 to a metal roof material.

  Referring to the figure, a single-flow roof 61 includes an outer wall 51 that extends vertically downward, a roof base 65 that is connected to the outer wall 51 and that has an opening 66 formed on the apex side thereof, and extends downward. And a metal roofing material 62 laid on the upper surface. Note that the metal roof material 62 has an overlap portion 63, a bent portion 72 having a L-shaped cross section in the flow direction of the single-flow roof 61, and a cross-section in the flow direction of the single-flow roof 61 by the Yachiyo folding process. A triangle-shaped rising portion 73 is formed.

  Specifically, the metal roof material 62 is installed on a roof base 65 installed on a rafter (not shown) via a roofing 67. The roofing 67 further covers the end side surface of the upper roof base 65 and a part of the lower surface of the roof base 65 and passes downwardly between the outer wall 51 and a fixing member 53 fixed by a fixing nail described later. It extends.

  A tree base 69 is installed on the roofing 67 above the opening 66, and the lower side of the opening 66 is in contact with the end of the rising portion 73 on the opening 66 side. A wood substrate 70 is installed. Further, a chemical face door 71 is installed so as to contact the inner surface of the bending portion 72. Further, a wood substrate 75 is installed from the upper surface of the tree substrate 70 to the upper surface of the chemical door 71, and the upper surface of the tree substrate 75 and the side surface of the tree substrate 75 opposite to the opening 66 are respectively provided by roofing 76. Covered. Further, on the lower side of the opening 66, a draining drain 68 having a L-shaped cross section in the flow direction of the one-sided roof 61 is provided so as to face the wood substrate 69 through the opening 66. Further, an apron face door 74 is installed on the upper surface of the metal roof material 62 below the chemical face door 71.

  At the time of attachment, first, the partition plate 25 is installed on the flat surface 11 of the first member 10 on the drooping surface 12 side from the opening portion 17. On the other hand, on the flat surface 11 of the first member 10 on the first vertical portion 13 side from the opening portion 17, the draining member 38 and the ventilation member 30 are installed in this order, and the metal band 35 is covered from above to cover the metal band 35. Both ends of the band 35 are fixed to the flat surface 11 with rivets 36 a and 36 b together with the draining member 38. Then, the draining member 38 and the ventilation member 30 are fixed on the flat surface 11.

  Next, the first member 10 to which the ventilation member 30 is attached is lowered from above so that the opening portion 17 faces the opening 66 above the metal roof material 62. Then, the upper lower surface of the flat surface 11 is installed on the upper surface of the tree base 69, and the lower lower surface of the flat surface 11 is installed on the upper surface of the tree base 75 via the roofing 76. Further, the drooping surface 12 is located on the outer side of the outer wall 51. In such a state, the first member 10 is fixed to the wood substrate 75 with the fixing nail 60 through the attachment hole 56 (see FIG. 1) formed on the upper surface of the metal band 35.

  Then, the second member 20 (see FIG. 2) is lowered from above the first member 10 and the ventilation member 30 so as to cover the ventilation member 30. Then, the flat plate portion 21 (see FIG. 2) is installed with the lower surface in contact with the upper surface of the partition plate 25 and the upper surface of the metal band 35. Then, the second member 20 is fixed to the metal band 35 with screws, which will be described later, through the attachment holes 58 (see FIG. 1) and the attachment holes 57 (see FIG. 1) formed in the metal band 35. Furthermore, the first hanging portion 22 (see FIG. 2) installed in contact with the lower side of the hanging surface 12 is fixed to the hanging surface 12 by screws to be described later, and the first hanging portion 22 and the hanging surface 12 are also fixed. Is fixed to each of the outer wall 51 and the fixing member 53 by fixing nails described later.

  Thus, when the ventilation building 5 is attached on the single-flow roof 61, it will be in the state shown in FIG.

  FIG. 5 is a schematic end view showing a state in which the ventilation building shown in FIG. 1 is attached to the metal roof material.

  Referring to the drawing, the second member 20 installed so as to cover the ventilation member 30 is fixed to the metal band 35 by a screw 59a through an attachment hole 58 (see FIG. 1). That is, the second member 20 is attached in a state where the ventilation member 30 is protected by the metal band 35 having high rigidity. Therefore, the second member is stably attached without damaging the ventilation member 30 due to an impact from the outside. Further, the first hanging portion 22 installed in contact with the outer side of the hanging surface 12 is fixed to the hanging surface 12 by a screw 59b. Further, the first hanging portion 22 and the hanging surface 12 are fixed to the outer wall 51 and the fixing member 53 by fixing nails 54, respectively.

  And by installing the ventilation building 5 in this way, the opening part 66 of the metal roof material 62 and the opening part 17 of the 2nd member 20 will be in a communication state, and a ventilation path is formed. In the ventilation state, the air rising from the opening 66 of the metal roofing material 62 passes through the opening 17 of the first member 10 and then passes through the ventilation hole of the ventilation member 30 (see FIG. 3). Pass to the side. And the air which passed the ventilation member 30 is discharged | emitted outside through the vent 47 which consists of the space between the lower end of the 2nd drooping part 23, and the upper end of the 2nd perpendicular | vertical part 15. FIG.

  Thus, since the ventilation building 5 has a shape corresponding to the single-flow roof 61 having the outer wall 51 and the metal roof material 62, the ventilation building 5 can be attached to the single-flow roof 61 as described above.

  FIG. 6 is an enlarged view of a portion “X” shown in FIG.

  Referring to the drawing, in the installed state, ventilation member 30 extends in the longitudinal direction so as to cross the ventilation path as described above. The second drooping portion 23 extends vertically downward toward the flange portion 14 of the first member 10. As a result, a first corner portion 78, a second corner portion 79, and a third corner portion 80, which change the ventilation direction at right angles, are formed in the middle of the ventilation path. Further, in the third corner portion 80 serving as the specific corner portion, the protruding piece 41 extends from the inner corner 81 toward the outer corner 82 so as to block a part of the third corner portion 80. . Here, when the distance from the inner corner 81 to the outer corner 82 in the third corner portion 80 is L, and the protruding length of the protruding piece 41 is T, the distance is set to T = 1 / 4L. . In this way, the distance W from the protruding portion of the protruding piece 41 to the outer corner 82 is substantially equal to the distance B from the first vertical portion 13 of the first member 10 to the second hanging portion 23 of the second member 20. Since they are equal (W≈B), the gas flowing through the ventilation path during ventilation is not compressed by the protruding piece 41 and the ventilation resistance does not increase. According to this, a waterproof effect is exhibited without disturbing the ventilation performance of the ventilation building 5.

  Here, the advantages of the provision of the protruding piece 41 as in the present embodiment will be described in an easy-to-understand manner.

  FIG. 7 is a schematic view schematically showing the waterproof effect of the ventilation building shown in FIG. 1 in comparison with the conventional structure.

  First, referring to FIG. 7 (1), a ventilation path including a first corner portion 85, a second corner portion 86, and a third corner portion 87 whose ventilation direction changes at right angles to three consecutive locations in the middle of the ventilation path. Then, let us consider a ventilation path in which no protruding piece according to the present embodiment exists. In this case, rainwater flowing in the direction of the arrow from the vent 84 passes through the ventilation path in the order of the first corner portion 85, the second corner portion 86, and the third corner portion 87. Here, a part of kinetic energy is released from the rainwater every time it bends each corner. Therefore, the momentum of the flow of rain after passing through the third corner portion 87 is lower than the momentum of the flow before passing through the third corner portion 87. The momentum further decreases as it passes through the fourth corner portion 88 and the fifth corner portion 89, but a part thereof may enter the inside depending on the momentum of inflow.

  On the other hand, as shown in FIG. 7 (2), in the ventilation path of FIG. In the ventilation path provided with the protruding piece 41 extending toward 82, the rainwater flowing in the direction of the arrow from the ventilation port 47 is caused to flow in the protruding direction of the protruding piece 41, that is, outward by the third corner portion 80. Invert toward. At this time, the kinetic energy release is greater due to the presence of the protruding piece 41 as compared to FIG. Therefore, compared with the case of (1), since the momentum of the flow of rainwater after passing through the third corner portion 80 is further reduced, the possibility of entering inward is reduced, and the waterproof effect is further improved.

  Furthermore, returning to FIG. 6, in the installed state, since the inclined plate 16 is provided on the outer side of the first member 10, the ventilation building 5 passes along the overlapping portion 63 of the metal roof material 62 with a gentle inclination. Even if rainwater tries to enter the rainwater, the inclined plate 16 causes the rainwater to jump upward. For this reason, direct rainwater intrusion through the metal roof material 62 is also reduced.

  Furthermore, in the installed state, the ventilation member 30 side in the space formed by the first member 10 and the second member 20 by the partition plate 25 (see FIG. 5) and the partition plates 31a and 31b (see FIG. 1). The surrounding area except for is sealed. Therefore, the reliability of the ventilation building 5 is improved by improving the sealing performance of the opening portion 17.

  In the above embodiment, the ventilation structure is applied to a ventilation building as a ventilation structure. However, the ventilation structure according to the present invention can be similarly applied to a ventilation structure under an eaves or under a headboard.

  Further, in the above embodiment, the ventilation building is installed on a single-flow roof having a roof material as a metal roof, but the same can be applied to a double-flow roof. Further, the present invention can be similarly applied to a roof material other than a metal roof such as a tile roof or a roof having a steep slope.

  Furthermore, in the above-described embodiment, the ventilation structure expressed as a ventilation building is formed in a specific shape, but the ventilation structure is provided with a corner portion that is formed in the middle of the ventilation path and in which the ventilation direction changes at a right angle. Any other shape may be used.

  Furthermore, in the above-described embodiment, a part of the draining member is a protruding piece, but a part of another member constituting the ventilation structure may be a protruding piece.

  Furthermore, in the above embodiment, the protruding length T of the protruding piece is set to a distance of T = 1 / 4L, but may be another distance. Preferably, the same effect can be expected if the distance is set to T = 1 / 4L to 1 / 3L.

  Furthermore, in the above-described embodiment, the third corner portion from the outer opening position is the specific corner portion, but the specific corner portion can be similarly applied to other corner portions.

  Furthermore, in the above embodiment, the protruding piece is provided at one place, but the protruding piece may be provided at two or more places.

  Furthermore, in the above-described embodiment, the ventilation member having a specific shape is installed in the ventilation path, but the ventilation member may have another shape. Or it can apply similarly even if it installs the ventilation member from which a ventilation means differs. Or there may be no ventilation member.

DESCRIPTION OF SYMBOLS 5 ... Ventilation ridge 10 ... 1st member 11 ... Flat surface 12 ... Drooping surface 13 ... 1st drooping lower part 14 ... Flange part 15 ... 2nd perpendicular part 17 ... Opening part 20 ... 2nd member 21 ... Flat plate part 22 ... 1st Hanging part 23 ... Second hanging part 38 ... Draining member 39 ... Installation plate 40 ... Vertical piece 41 ... Projection piece 47 ... Venting hole 61 ... Single-flow roof 66 ... Opening part 78 ... First corner part 79 ... Second corner part 80 ... 3rd corner part 81, 82 ... angle In addition, the same code | symbol in each figure shows the same or equivalent part.

Claims (2)

In the ventilation structure having a corner portion that is formed in the middle of the ventilation path and whose ventilation direction changes at right angles, the ventilation structure includes a ventilation ridge attached on a metal roof,
In the specific corner portion among the corner portions, a protruding piece extending from the inner corner toward the outer corner is formed so as to block a part of the specific corner portion,
The protruding length of the protruding piece is set to a distance from 1/4 to 1/3 of the distance from the inner corner to the outer corner ,
The corner portion is continuously formed at least three locations from the outer opening position,
The specific corner portion corresponds to the third corner portion from the outer side,
The first corner portion of the corner portion is composed of a flange portion arranged along the metal roof and a vertical portion rising upward from an outer side end portion of the flange portion,
The ventilation structure further comprising an inclined plate that is inclined toward the metal roof at an upper end portion of the vertical portion . The ventilation path is provided with a ventilation member having a rod shape extending in the longitudinal direction so as to cross the ventilation path and having a plurality of ventilation holes penetrating from one side surface to the other side surface in the short direction. that, according to claim 1 Symbol placement of the ventilation structure.

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