JP2012233340A - Outer wall structure - Google Patents

Abstract

To provide an outer wall structure that is highly waterproof and can be easily constructed in a building such as a house.
An outer wall structure according to the present invention includes a wall base 2, a first outer wall portion 101 and a second outer wall portion 102 that are installed at positions on the outdoor side with respect to the wall base 2, and ventilation separation. Part 6. The outer wall portions 101 and 102 are abutted in a direction crossing each other in plan view. A ventilation space 3 communicating with the outside is formed between the wall base 2 and the outer wall portions 101 and 102. The ventilation dividing portion 6 divides the ventilation space 6 at a position where the outer wall portions 101 and 102 are abutted with each other or in the vicinity thereof.
[Selection] Figure 1

Description

  The present invention relates to an outer wall structure of a building.

  Conventionally, in an outer wall structure of a building such as a residential house, when an outer wall is formed by attaching a plurality of outer wall materials, a sealing material is provided between adjacent outer wall materials to ensure waterproofness.

  FIG. 16 shows a conventional building outer wall structure. In the illustrated outer wall structure, a sealing material 40 is provided and sealed between the adjacent left and right outer wall materials 10 to ensure waterproofness. Also in the opening 30 such as a window, a sealing material 40 is provided between the cut out outer wall material 10 and the opening 30. Note that the outer wall materials 10 and 10 adjacent to each other in the vertical direction are secured by being overlapped and attached.

  In the outer wall structure of the building as described above, the portion of the sealing material 40 or the boundary portion between the sealing material 40 and the outer wall material 10 is more likely to deteriorate than the outer wall material 10 over time, and rainwater starts from the deteriorated portion. In some cases, the water resistance of the outer wall deteriorates due to water immersion. Moreover, it is necessary to seal between the adjacent outer wall materials 10 with the sealing material 40, and it may take time for construction. Further, if cracks or cracks occur in the sealing material 40, the appearance of the outer wall may be impaired, and the design may be deteriorated.

  Accordingly, it is conceivable to construct the outer wall material 10 without using the sealing material 40 to form the outer wall. The intrusion of water from the gap in the outer wall greatly depends on the intensity of wind and rain, in other words, the wind speed (external wind pressure) and the amount of rainfall. Therefore, in the non-sealing method, as shown in FIG. 15, a ventilation space 3 is provided between the wall base 2 constituting the wall surface and the outer wall portion 1 formed by the outer wall material 10. An external wall structure that prevents the entry of wind and rain by reducing the pressure difference with the external space of the building can be considered. Such a ventilation space 3 is designed by a so-called isobaric theory.

  As a wall design using the isobaric theory, a building wall structure has been proposed. For example, Patent Document 1 discloses a building wall structure in which a space is provided between an outer panel and an inner panel, the space is sealed, and the pressure of the space is substantially equal to the outside. Has been. However, in this wall structure, it is necessary to provide a sealing means for closing the space between the panels called flushing between two adjacent outer panels, and this sealing means is provided on the panel connecting portion over the entire outer wall. Since it had to be provided, it took time for construction. Further, the flushing as the sealing means is attached to the outside of the panel arranged on the lower side, so that it appears on the outside of the building, which may deteriorate the design.

Special table 2007-521427 gazette

  The present invention has been made in view of the above problems, and an object of the present invention is to provide an outer wall structure that is highly waterproof and can be easily constructed in a building such as a house.

The outer wall structure according to the present invention includes a wall base, a first outer wall part and a second outer wall part that are installed at positions on the outdoor side with respect to the wall base, and a ventilation dividing part,
The outer wall portions are butted against each other in a direction crossing each other in plan view;
A ventilation space communicating with the outdoors is formed between the wall base and the outer wall portion,
The ventilation dividing portion divides the ventilation space at a position where the outer wall portions are in contact with each other or in the vicinity thereof.

In the present invention, the ventilation dividing portion includes a first member and two second members having elasticity,
The first member includes a first piece interposed between the wall base and the first outer wall, and a second piece interposed between the wall base and the second outer wall. The first piece and the second piece are each formed with a protrusion that protrudes toward the first outer wall and a protrusion that protrudes toward the second outer wall,
One of the two second members is the first piece and the first outer wall portion at a position opposite to the position where the outer wall portions are abutted with each other with respect to the ridge in the first piece. Between the second piece and the second outer wall portion at a position opposite to the position where the outer wall portions face each other with respect to the ridge in the second piece. It is preferable to interpose between them.

In the present invention, includes a communication port for connecting the ventilation space and outdoor, it to the area of the wall surface of wall base of said vent space, the ratio of the opening area of the communication port is 65cm 2 ^/ m ² or more Is preferred.

  ADVANTAGE OF THE INVENTION According to this invention, in buildings, such as a house, the outer wall structure which is highly waterproof and can be constructed easily is implement | achieved.

(A) And (b) is a planar view sectional drawing which shows the one aspect | mode of the corner part of the outer wall structure in one Embodiment of this invention. (A) And (b) is a planar view sectional drawing which shows another aspect of the corner part of the outer wall structure in one Embodiment of this invention. It is a plane view sectional view showing the outer wall structure in one embodiment of the present invention. It is a partial side view sectional view showing the outer wall structure in one embodiment of the present invention. It is a front view which shows the outer wall structure in one Embodiment of this invention. It is side surface sectional drawing which shows the outer wall structure in one Embodiment of this invention. It is a sectional view in plan view showing another form of the outer wall structure in one embodiment of the present invention. (A) And (b) is a planar view sectional drawing which shows another aspect of the corner part of the outer wall structure in one Embodiment of this invention. (A), (b) and (c) is a front view which shows the other form of the outer wall structure in one Embodiment of this invention. (A), (b) and (c) are side view sectional drawings which show the further another form of the outer wall structure in one Embodiment of this invention. (A) And (b) is side surface sectional drawing which shows an example of the form of the outer wall part in one Embodiment of this invention. (A)-(e) is a planar view sectional drawing which shows an example of the form of the outer wall part in one Embodiment of this invention. (A) And (b) is a front view which shows an example of the trunk edge in one Embodiment of this invention. It is a front view which shows the other form of the outer wall structure in one Embodiment of this invention. It is a conceptual diagram of the outer wall structure explaining the present invention. It is a front view which shows an example of the outer wall structure of the conventional building.

  FIGS. 1-6 shows an example of embodiment of the outer wall structure of the building of this invention. In this outer wall structure, a ventilation space 3 is formed as an air layer between the wall base 2 and the outer wall portion 1 formed by the outer wall material 10. The outer wall structure further includes a ventilation dividing portion 6 that divides the ventilation space 3 at a position where the outer wall portions 1 and 1 are abutted in a direction intersecting in plan view or in the vicinity thereof.

  The wall base 2 is a base of the outer wall. In the present embodiment, the wall base 2 is constituted by a plurality of pillars 17 and a face material attached to the pillars 17. The face material is a member that closes a gap between adjacent columns 17. Examples of the face material include a structural face material 20 such as an appropriate plate material, a waterproof sheet 14 (waterproof paper), and the like. In the present embodiment, as the face material, the structural face material 20 and the waterproof sheet 14 are used in combination, the structural face material 20 is installed on the outdoor side of the column 17, and the structural face material such as this plate material. 20 is provided with a waterproof sheet 14 on the outdoor side. Thereby, water, such as rain water, is prevented from entering the indoor side by the waterproof sheet 14. An inner wall portion 19 made of an appropriate inner wall material is installed on the indoor side of the pillar 17. A heat insulating material 18 is disposed in a space sandwiched between the face material and the inner wall portion 19. A moisture-proof sheet 14 a is provided on the outdoor side of the inner wall portion 19. By providing the moisture-proof sheet 14a in this way, the intrusion of moisture into the room is suppressed, and as the pillar 17, a column having a square section and a rectangular section are appropriately used.

  A trunk edge 11 is attached to the wall base 2 so as to overlap the pillar 17. The body edge 11 is attached using a fixing tool 13 such as a nail or a screw. In the illustrated embodiment, a trunk edge 11 (vertical trunk edge) whose longitudinal direction coincides with the longitudinal direction is attached along a pillar 17 extending in the longitudinal direction (vertical direction or vertical direction). An outer wall material mounting bracket 12 for mounting the outer wall material 10 is attached to the trunk edge 11 with a fixture 13 such as a nail at a predetermined location.

  A base part (base) 8 is provided at the lower part of the building. On the upper side of the base portion 8, a long base pillar (joist) 16 serving as a foundation for attaching the pillar 17 and the like is provided in the lateral direction. In the illustrated embodiment, a column 17 is disposed vertically above the base column 16 in a vertical direction perpendicular to the base column 16, and the face material is arranged on these outdoor side surfaces so as to cover the base column 16 and the column 17. It is installed. A foundation drainer 9 is provided in the lateral direction on the outdoor surface of the face material on the upper side of the foundation portion 8. The base drainer 9 includes a fixing piece 9a for fixing the base drainer 9 to the wall base 2, a draining piece 9b protruding toward the outdoor side, and a draining tip piece 9c hanging downward from the tip of the draining piece 9b. It is formed in preparation. The draining piece 9b is formed so as to protrude from the outer wall portion 1 while being slightly inclined downward toward the outdoor side.

  The outer wall material 10 is attached to the wall base 2 over almost the entire wall surface so as to cover the wall base 2. Specifically, the outer wall material 10 is attached to the wall base 2 by being engaged with or placed on an outer wall material mounting bracket 12 attached to the trunk edge 11. The outer wall portion 1 is constituted by the plurality of outer wall materials 10. The outer wall portion 1 constitutes the outermost layer of the outer wall of the building.

  The thickness (indoor-outdoor direction dimension) of the ventilation space 3 between the outer wall portion 1 and the wall base 2 is ensured by the thickness of the trunk edge 11 and the protruding width of the outer wall material mounting bracket 12. That is, the trunk space 11 and the outer wall material mounting bracket 12 serve as spacers to form the ventilation space 3. In the illustrated embodiment, since the outer wall material mounting bracket 12 protrudes from the outer side of the trunk edge 11, the outer wall material mounting bracket 12 is disposed in the ventilation spaces 3 and 3 adjacent to each other across the trunk edge 11. It communicates with the gap formed by protruding. Since the ventilation space 3 communicates in the lateral direction (horizontal direction), it is possible to move the air in the lateral direction, and the pressure difference in the lateral direction in the ventilation space 3 can be reduced. In addition, the outer wall material 10 is attached so as not to protrude from the trunk edge 11 so that the outer wall material 10 is closely attached to the trunk edge 11, and the ventilation space 3 is formed so as to be divided laterally by the trunk edge 11. Also good. When the ventilation space 3 is divided in the horizontal direction, the movement of air in the horizontal direction is suppressed, and the air easily moves in the vertical direction.

  The thickness of the ventilation space 3 is set to 20 to 23 mm, for example. If the thickness of the ventilation space 3 is within this range, the ventilation by the ventilation space 3 is reliably ensured. For example, the thickness (width from the back surface of the outer wall portion 1 to the surface of the wall base 2) is 23 mm by using the body edge 11 having a thickness of 18 mm and the outer wall material mounting bracket 12 having a protruding width (working width) of 5 mm. The ventilation space 3 is formed.

  In the outer wall structure according to the present embodiment, a communication port 4 that communicates the outside of the building and the ventilation space 3 is formed.

  When the communication port 4 that communicates between the outside (outdoor) of the building and the ventilation space 3 is formed in this way, the pressure difference between the ventilation space 3 and the outside becomes small, and therefore a gap such as a joint in the outer wall 1 is formed. Intrusion of wind and rain from the inside is suppressed. Thereby, a highly waterproof outer wall structure is realized. The communication port 4 is formed, for example, at a location where the wall base 2 is not partially covered with the outer wall material 10.

  In the case where the communication port 4 is not formed, for example, when the pressure on the outdoor side of the outer wall portion 1 is increased by blowing air on the outer wall portion 1, the outside air enters the indoor side from the joint between the adjacent outer wall materials 10. Inflow of rainwater and so on becomes easier. However, in the present embodiment, since the communication port 4 is formed, a pressure difference between the ventilation space 3 and the outside becomes small, so that it is difficult for outside air, rainwater, and the like to flow from the outside to the inside. Even if outside air, rainwater, or the like flows from the communication port 4, the amount thereof is small, and in this embodiment, for example, it is quickly discharged to the outside from the first communication port 401. Moreover, if some moisture is attached to the wall base 2, the penetration of moisture into the room is sufficiently suppressed by the waterproof sheet 14.

  In order to sufficiently suppress the inflow of rainwater or the like into the indoor space, the pressure difference between the ventilation space 3 and the outside is 50 Pa or less under the condition that the wind speed blown to the outer wall portion 1 is 20 m / sec or less. It is preferable to become. The wind blown to the outer wall 1 in this case may be at least one of a front wind (wind perpendicular to the wall surface) and a slope wind (wind blowing down from the upper 45 ° toward the wall surface). In both cases, the pressure difference is preferably 50 Pa or less. The water spraying pressure test for the building for performing the performance evaluation of such an outer wall structure can be performed according to JIS A1414 “Performance test of building components (panel) and its structural part, 6.5 watertight test”.

In order to sufficiently suppress the inflow of rainwater or the like indoors, the ratio of the opening area of the communication port 4 to the area of the wall surface of the wall base 2 in the ventilation space 3 is 65 cm ² / m ² or more. Is preferred. That is, it is preferable that the opening area of the communication port 4 per 1 m ^{2 of} the wall surface is 65 cm ² or more. The wall surface here is a surface constituting the wall of the building, and is composed of the surface on the outdoor side of the wall foundation 2. The wall surface is generally above the base portion 8 and more than the eaves portion 7. This is the lower planar part. The wall surface does not include the area of the opening 30 such as a window or a ventilation opening. When there are a plurality of communication ports 4 communicating with the ventilation space 3, the ratio of the total amount of the opening areas of the plurality of communication ports 4 is preferably 65 cm ² / m ² or more. The communication ports 4 may be provided concentrated on a part of the wall surface or distributed on the wall surface. Therefore, when the area of the wall surface is Sm ² , the total area of the communication ports 4 may be 65 × Scm ² or more. If the ratio of the opening area of the communication port 4 is smaller than this, the pressure difference may not be reduced. The upper limit of the ratio of the opening area of the communication port 4 is not particularly limited. If the inflow of rainwater or the like from the communication port 4 is sufficiently suppressed due to sufficient water closing, the ratio of the opening area of the communication port 4 is better. It has been confirmed by experiments that the differential pressure decreases as the ratio of the opening area of the communication port 4 increases in the range of the opening area ratio of the communication port 4 up to 110 cm ² / m ² .

  The communication port 4 is formed on the upper side of the base part 8 at the lower end of the outer wall part 1 and on the lower side of the eaves part 7 at the upper end of the outer wall part. That is, the lower end portion of the outer wall member 10 arranged at the lowermost end of the outer wall portion 1 hangs down the open space without contacting the base portion 8 or the base drainer 9, thereby the outer wall portion. 1 opening is formed. By this opening, a linear communication port 4 is formed at the lower end portion of the wall surface over the lower end of the outer wall portion 1. Moreover, the outer wall material 10 arrange | positioned at the upper end of the outer wall part 1 protrudes, without the upper end part contacting the eaves top part 7, and, thereby, the opening of the outer wall part 1 is formed. By this opening, a linear communication port 4 is formed at the upper end portion of the wall surface over the upper end of the outer wall portion 1. That is, a long opening in the horizontal direction along the outer wall is formed between the lower end of the outer wall portion 1 and the outdoor side end portion of the draining piece 9b, and this opening communicates with the ventilation space 3 and the outdoors. It becomes the port 4 (first communication port 401).

Then, the total opening area of the communicating port formed in the upper wall 4 (the second communicating port 402) and formed on the lower side a communicating port 4 (the first communication port 401) of 65cm 2 ^/ m ² That's it. As illustrated, in this embodiment, the first communication port 401 is formed to have a larger opening area than the second communication port 402. Thus, it is preferable that the communication port 4 is provided at least above the base portion 8. When the communication port 4 is provided on the upper side of the base portion 8, rainwater can be discharged from the communication port 4. In addition, by forming the communication port 4 on the upper side of the base portion 8, it is possible to reduce the rate at which wind and rain directly hit the wall base 2. Therefore, when a plurality of communication ports 4 are provided, it is preferable that the opening area of the communication ports 4 formed on the upper side of the base portion 8 is larger than the other communication ports 4.

  In this embodiment, since the communication port 4 is formed in a straight line that is long in the horizontal direction along the outer wall, the opening area is the width of the straight line (gap width) and the length of the straight line (distance in the lateral direction of the wall surface). Is calculated by multiplying

The opening amount of the first communication port 401 is preferably 150 cm ² or more per 1 m of the frontage (the length in the lateral direction of the wall surface). When the opening amount is within this range, air communication between the outside and the ventilation space 3 can be reliably performed. In order to satisfy this value, for example, in the case of the communication port 4 that extends linearly in the lateral direction and opens, the vertical length (gap width) of the communication port 4 is about 10 to 30 mm, for example, 18 mm. It is preferable to do. It is also preferable to make the length of the communication port 4 in the vertical direction larger than the thickness of the trunk edge 11. By setting the length in the vertical direction of the communication port 4 in this manner, a sufficient opening for forming the ventilation space 3 with a small differential pressure can be provided in the outer wall portion 1.

  In addition, the opening area of the communication port 4 formed on the upper side of the base portion 8 is preferably larger than half of the minimum cross-sectional area in the horizontal direction of the ventilation space 3. The minimum cross-sectional area portion of the ventilation space 3 in the horizontal direction is a rate-determining portion when air flows in the ventilation space 3, and the opening area of the communication port 4 is smaller than half of the minimum cross-sectional area portion that becomes the rate-determining portion. By increasing the size, the pressure difference can be reduced by preventing the air flow from being hindered. The minimum cross-sectional area in the horizontal direction of the ventilation space 3 is the area of the region between the outer wall material 10 and the wall base 2 excluding the body edge 11 and the outer wall material mounting bracket 12. However, since the outer wall material mounting bracket 12 has a sufficiently small cross-sectional area compared to the other, it may be ignored in calculation. Therefore, the area of this region is obtained by multiplying the width of the ventilation space 3 (the distance between the outer wall material 10 and the wall base 2) by the lateral length of the wall surface, and cutting off the trunk edge 11 disposed on the wall surface. It is almost equal to the area reduced.

  The communication port 4 formed on the upper side of the base portion 8 is provided between the base drainer 9 and the outer wall material 10 in the illustrated form. That is, the draining piece 9b of the base draining 9 protrudes to the outdoor side from the outer wall portion 1, and the draining piece 9b is arranged below the outer wall material 10 arranged at the lower end portion of the wall surface with a space. Yes. By installing the foundation drainer 9 with such a structure, rainwater flowing down the ventilation space 3 through the back surface of the outer wall material 10 falls onto the drainer piece 9b of the foundation drainer 9, and the surface of the foundation drainer 9 is connected. Therefore, it is discharged to the outside, and the discharged water can flow to a predetermined position. In addition, since the lower part of the ventilation space 3 is closed by the base drainer 9, it is possible to reduce the wind and rain that winds from below from being blown into the ventilation space 3, and to prevent the wind from entering the ventilation space 3. It is.

  As shown in FIG. 6, the communication port 4 (second communication port 402) provided on the lower side of the eaves portion 7 has a communication port at a predetermined distance from the outer wall 1 to the outdoor side. It is preferable that a ventilation parting edge 15 that closes the front surface of the opening 4 and communicates the ventilation space 3 with the outside through the communication port 4 is provided in the lateral direction. By providing the ventilation cut-off edge 15, the lower opening of the eaves part 7 can be made inconspicuous, and by closing the front of the opening of the communication port 4, it is possible that wind and rain directly hit the wall substrate 2. Can be reduced.

  Since the ventilation space 3 communicates with the outside through the communication port 4, it becomes a space through which outside air enters and passes. In this embodiment, as shown by the arrows in FIG. 6, the outside air flows in the direction from (i) to (ii). That is, outside air enters the ventilation space 3 from the communication port 4 on the base portion 8 side, and the invaded outside air rises in the ventilation space 3 and is again discharged to the outside through the communication port 4 on the eave ceiling portion 7 side. The At this time, if the ventilation parting edge 15 is provided on the lower side of the eaves ceiling part 7, the flow direction of the outside air can be moved away from the eaves ceiling part 7, and the outside air can flow smoothly. In addition, even when the outside air contains moisture, it is possible to reduce the outside air from directly hitting the eaves ceiling 7.

The total opening area of the communication ports 4 formed below the eaves ceiling 7 is preferably 6.0 cm ² or less with respect to the wall surface 1 m ² . If the opening area of the communication port 4 at this position is larger than this, the ventilation parting edge 15 for closing the opening may be too large.

  As shown in FIG. 3, on the outer wall of the building, one wall surface (for example, the lower wall surface in the drawing) and the other wall surface (for example, the right or left wall surface in the drawing) are projected so as to intersect in plan view. Together, the corner portion 5 is formed. The corner portions 5 are formed at the exit corner and the entrance corner of the building. In the periphery of the corner portion 5, two outer wall portions 1 (referred to as a first outer wall portion 101 and a second outer wall portion 102 for convenience) face each other in a direction intersecting with each other in plan view. In this outer wall structure, a ventilation dividing portion 6 that divides the ventilation space 3 provided on one wall surface and the ventilation space 3 provided on the other wall surface at the corner portion 5 is provided. The ventilation dividing portion 6 divides the ventilation space 3 at a position where the first outer wall portion 101 and the second outer wall portion 102 are abutted or in the vicinity thereof.

  In one aspect of the present embodiment, the ventilation division 6 at the corner of the building is shown in FIG. 1A, and the ventilation division 6 at the corner of the building is shown in FIG. 1B. In any case, the ventilation dividing part 6 includes a first member 61 and two second members 62 having elasticity.

  The first member 61 includes two pieces 63 and 63 combined in an L shape in plan view. That is, the first member 61 is interposed between the piece base 63 (first piece 631) interposed between the wall base 2 and the first outer wall portion 101, and between the wall base 2 and the second outer wall portion 102. One piece 63 (second piece 632) is provided. On the first piece 631 and the second piece 632, a vertically long ridge 64 protruding toward the first outer wall portion 101 and a vertically long ridge 64 protruding toward the second outer wall portion 102, respectively. Is formed. These ridges 64 are preferably in contact with or close to the first outer wall portion 101 or the second outer wall portion 102. In particular, the distance between the ridge 64 and the first outer wall 101 or the second outer wall 102 is preferably in the range of 0 to 1.5 mm, and more preferably in the range of 0 to 1.0 mm.

  One second member 62 of the two second members 62, 62 is on the outer side of the ridge 64 in the first piece 631 (on the side opposite to the butting position between the outer wall portions 101, 102) and the first piece 631. It is interposed between the one outer wall portion 101. The second member 62 elastically contacts the first piece 631 and the first outer wall material. Of the two second members 62, 62, the other second member 62 is interposed between the second piece 632 and the second outer wall 102 on the outer side of the ridge 64 in the second piece 632. The second member 62 elastically contacts the second piece 632 and the second outer wall material. Therefore, in a state where the second member 62 is not compressed by an external force, the thickness (indoor-outdoor direction dimension) of the second member 62 is larger than the protruding dimension (indoor-outdoor direction dimension) of the ridge 64. Is preferred.

  The first member 61 is formed of an appropriate material, and is formed of, for example, a metal plate material. The second member 62 is formed of a material having appropriate elasticity, and is formed of, for example, EPDM (ethylene-propylene-diene rubber).

  According to this aspect, the ventilation space 3 is divided by the two second members 62 in the vicinity of the position where the first outer wall portion 101 and the second outer wall portion 102 are abutted. Further, a ridge 64 is disposed on the side of the second member 62 where the first outer wall 101 and the second outer wall 102 are abutted. For this reason, the ridge 64 shields the ultraviolet rays inserted from the gap between the first outer wall portion 101 and the second outer wall portion 102, rainwater entering from the gap from the second member 62, thereby ultraviolet rays, Deterioration of the second member 62 due to water or the like is suppressed. Furthermore, since the interval between the wall base and the outer wall portion is regulated by the ridges 64 in the vicinity of the second member 62, the second member 62 is crushed and damaged due to the narrow interval between the wall base and the outer wall portion. Such a thing is suppressed.

  It is also preferable that each of the first piece 631 and the second piece 632 is formed with two or more ridges 64 as shown in FIG. The plurality of ridges 64 are formed in parallel in parallel at an interval in each of the first piece 631 and the second piece 632. In this case, the 2nd member 62 is arrange | positioned on the opposite side to the butting position of outer wall parts with respect to the protruding line 64 in the position farthest from the butting position of outer wall parts among several convex ribs 64. FIG. It is preferable. In such an aspect, since the second member 62 is shielded by the plurality of ridges 64, the deterioration of the second member 62 is further suppressed. Further, in the vicinity of the second member 62, the interval between the wall base and the outer wall is restricted by the plurality of ridges 64, so that the second member 62 is crushed due to a narrow interval between the wall base and the outer wall. Damage is further suppressed.

  Each said aspect WHEREIN: It is preferable that the space | interval between the butt | matching position of the 1st piece 631 and the 2nd piece 632 and each of the some protruding item | line 64 is the range of 5-20 mm. Moreover, the space | interval between the protruding item | line 64 and each of the two 2nd members 62 is 4 mm or more when the drainage property at the time of water permeating between the protruding item | line 64 and the 2nd member 62 should be considered. It is preferable that it is 20 mm or less from a viewpoint of suppression of the enlargement of a member.

  Thus, by dividing the ventilation space 3 for each wall surface by the ventilation dividing portion 6, it is possible to prevent air from flowing from the ventilation space 3 on one wall surface to the ventilation space 3 on the other wall surface. And the pressure difference between the outside and the outside can be reduced.

  For example, when wind is blown toward the first outer wall portion 101, the external air pressure around the first outer wall portion 101 becomes higher than the external air pressure around the second outer wall portion 102. Accordingly, the outside air flows into the ventilation space 3 between the first outer wall portion 101 and the wall base, so that the pressure of the ventilation space 3 is changed between the first outer wall portion 101 and the wall base to the second outer wall. It becomes higher than the pressure of the ventilation space 3 between the part 102 and the wall base. However, even if such a pressure difference occurs between the ventilation spaces 3 and 3, in the present embodiment, the ventilation spaces 3 and 3 are divided by the ventilation dividing portion 6. The pressure in the ventilation space 3 is unlikely to decrease between the first outer wall portion 101 and the wall base due to the movement. For this reason, the difference between the external air pressure around the first outer wall portion 101 and the pressure of the ventilation space 3 between the first outer wall portion 101 and the wall base is less likely to occur. This realizes an outer wall structure that is extremely waterproof when exposed to wind and rain.

  In addition, since a high waterproof property is realized by suppressing the pressure difference between the external air pressure and the ventilation space 3 in this way, when the outer wall portion 1 is configured by installing a plurality of outer wall materials 1, Even in the non-sealing method in which the sealing material is not filled between the matching outer wall materials 1 and 1, intrusion of rainwater or the like from the gap between the outer wall materials 1 and 1 is suppressed. For this reason, in the non-sealing method, the outer wall structure exhibits high waterproofness with a simple structure. In the present embodiment, a sealing material may be filled between the outer wall materials 1 and 1.

  FIG. 7 shows another form of the air dividing part 6. In this embodiment, the ventilating part 6 is formed by arranging an airtight packing 6a formed in a long shape in the vertical direction over the vertical direction. As shown in FIG. 7, such a ventilation dividing part 6 can also be used for the corner part 5 forming the protruding corner part 5a and the corner part 5 forming the entering corner part 5b.

  The structure of the air dividing part 6 is not limited to these. For example, as shown in FIGS. 8A and 8B, the body edge 11 is provided on the wall base 2 constituting each wall surface in the corner part 5. Alternatively, a joiner member 6b such as a hat-type joiner may function as the ventilation dividing portion 6 to fill the gap between the trunk edge 11 and the outer wall portion 1 to divide the ventilation space 3. In addition, in the form of FIG. 8, the sealing material 40 is provided in the outdoor side of the joiner member 6b. Moreover, in the form of Fig.8 (a), the outer wall material 10a for corners of the L-shaped cross section is arrange | positioned in the protruding corner part 5a.

  In each of the above embodiments, the wall base 2 is configured by laying a plurality of face materials. As the face material, a structural face material 20 such as a plywood can be used. Thus, airtightness can be ensured by forming the wall base 2 with the face material.

In order to reduce the pressure difference between the ventilation space 3 and the outside, it is ideal that no gap is formed in the wall base 2. However, in actual construction of the outer wall, a slight gap may be formed in the joint between the face material and the opening 30, such as a mounting portion of a facility such as a sash (window frame) or a ventilation fan. There is. Therefore, in order to reduce the pressure difference between the ventilation space 3 and the outside, it is preferable to reduce the gap between the wall base 2 as much as possible so that the total area with respect to the wall surface is 9 cm ² / m ² or less. If the total area of the gap with respect to the wall surface is larger than 9 cm ² / m ² , the air may move from the ventilation space 3 to the indoor side and the pressure difference between the ventilation space 3 and the outside may not be reduced. The total area of the gap is theoretically 0 cm ² / m ² if the entire surface of the wall can be covered with a face material such as plywood without providing the opening 30 or the like, but 3 cm ² in the field construction. It is realistic to be / m ² or less.

  When an opening that penetrates indoors and outdoors, such as the opening 30, is provided, it is preferable to attach an airtight tape around the opening 30 in the wall base 2. Thereby, it becomes possible to ensure airtightness. There may be a gap at the abutting portion between the face material 20 and the face material 20, but if the waterproof sheet 14 is adhered to the abutting portion across the face material 20, the airtightness is improved. be able to.

The wall base 2 may be provided with an opening after the construction of the outer wall by an air conditioner or the like. Therefore, the total opening area of the gaps during construction of the outer wall is preferably 5 cm ² / m ² or less. By making the opening area of the gap within this range, it becomes possible to ensure airtightness.

  In FIG. 9, the form of the outer wall structure with a high wall surface is shown. Such a form is used for a two-story or three-story or higher building. When the height of the wall surface increases, the area of the wall surface inevitably increases, and accordingly the opening area of the communication port 4 needs to be increased accordingly.

  In FIG. 9A, the communication port 4 having a large area is formed above the base portion 8, and the communication port 4 having a small area is formed below the eaves ceiling portion 7. In such a design, when the opening area is set to the range shown above, the opening by the communication port 4 in the base portion 8 may be too large. For example, in the case of a one-story building, the opening width is 18 mm. If the communication port 4 to be designed is a two-story building, the opening width is 36 mm, and wind and rain may enter or the appearance may deteriorate.

  Therefore, in FIG. 9B, a communication port 4 having a large area is formed on the upper side of the base portion 8 and in the middle of the floor height (such as the boundary between the upper floor portion and the lower floor portion). A communication port 4 having a small area is formed on the lower side. At this time, the distance between the communication ports 4 and 4 is preferably within 3 m. In this form, since the opening by the communicating port 4 is disperse | distributed to a predetermined location, each opening area can be made small.

  Further, in FIG. 9C, the communication port 4 having a large area is formed on the upper side of the base portion 8, the communication port 4 having a small area is formed on the lower side of the eaves ceiling portion 7, and the outer walls adjacent to each other in the vertical direction. The communication port 4 is formed as a gap extending in the lateral direction between the materials 10 and 10 (so-called horizontal joint portion). In this case, the openings of the communication ports 4 are further dispersed, and the openings can be made less noticeable. In addition, you may make it provide the communicating port 4 by forming a clearance gap between the outer wall materials 10 and 10 adjacent to right and left (what is called a vertical joint part).

  FIG. 10 shows an example of a structure in which the communication port 4 is formed in the middle of the floor. 10 (a) and 10 (b) correspond to the form of FIG. 9 (b), and the outer wall 1 is divided by the floor high drainer 22, and communication openings are provided on both upper and lower sides of the floor high drainer 22. 4 is provided. By using the floor drainer 22, draining can be performed in the middle of the floor, and the opening can be made inconspicuous. In the illustrated floor high drainer 22, the floor high drainer tip piece 22 a that hangs down covers the front surface of the communication port 4 provided below the floor high drainer 22. It is possible to prevent wind and rain from blowing directly into the communication port 4 on the side.

  In FIG. 10A, the floor drainer 22 is attached to the surface of the trunk edge 11 on the outdoor side. In this embodiment, the trunk edge 11 is not divided, and the trunk edge 11 attached in the longitudinal direction can reinforce the strength of the building. Moreover, in FIG.10 (b), the floor high drainer 22 is attached to the surface of the wall base 2, and the outer wall part 1 and the trunk edge 11 are divided | segmented by the up-down direction. In this form, it is possible to form the trunk edge 11 and the outer wall portion 1 for each floor. 10 (a) and 10 (b), when the roof portion 21 is formed at the boundary between the lower floor portion and the upper floor portion, if the communication port 4 is formed adjacent to the roof, the opening becomes less conspicuous. preferable.

  FIG. 10C corresponds to the form of FIG. 9C, and the communication port 4 is formed by the gap between the outer wall materials 10 and 10. In the case where the gap between the outer wall materials 10 and 10 is the communication port 4, the openings can be dispersed and become less conspicuous. The width L of the gap between the outer wall materials 10 and 10 can be designed as appropriate, and can be set to, for example, about 1 to 5 mm, specifically 3 mm. In order for the total amount of the opening area of the communication port 4 to satisfy the above range, the width L of the gap between the outer wall materials 10 and 10 is preferably 1.5 mm or more.

  In FIG. 11, an example of the junction part of the outer wall materials 10 and 10 adjacent up and down is shown. In the form of FIG. 11, the outer wall portion 1 is formed by arranging the overlapping portion 32 of the outer wall material 10 disposed on the upper side on the outdoor side of the receiving portion 31 of the outer wall material 10 disposed on the lower side. Yes. In such a joining structure, the outer wall member mounting bracket 12 having an engaging portion protruding upward is disposed between the upper and lower outer wall members 10, and the lower end portion of the upper outer wall member 10 is engaged with the outer wall member mounting bracket 12. It can be formed by engaging the joint.

  In FIG. 11A, the lower end portion of the upper outer wall member 10 and the upper end portion of the lower outer wall member 10 are in contact with each other, and no gap is formed. An outer wall material packing 33 may be provided between the receiving portion 31 of the lower outer wall material 10 and the overlapping portion 32 of the upper outer wall material 10.

  FIG.11 (b) shows the specific example of the form of FIG.10 (c). In this embodiment, the lower end portion of the upper outer wall member 10 and the upper end portion of the lower outer wall member 10 are not in contact with each other, and a gap is formed between the outer wall members 10 and 10. The gap formed between the outer wall materials 10 and 10 is bent along the overlapping shape of the outer wall material 10 to communicate the outside with the ventilation space 3, and this gap becomes the communication port 4. In this embodiment, the front of the opening portion of the ventilation space 3 is covered with the overlapping portion 32 of the outer wall material 10. In this way, when the opening is covered by overlapping the outer wall material 10, the wall base 2 can be made invisible from the outside, the opening can be made less noticeable, and direct rain can be prevented from hitting the opening. In addition, the waterproof property can be further enhanced. In addition, when the clearance gap formed between the outer wall materials 10 and 10 is bent and the communication port 4 is formed, the opening area of the communication port 4 is defined as a width L where the width of the gap is the smallest in the vertical direction, It is calculated based on this width L. This is because the portion where the width of the gap is the minimum is the rate of the air flow.

  In FIG. 12, an example of the junction part (vertical joint part) of the outer wall materials 10 and 10 adjacent on the right and left is shown. When the outer wall material 10 is attached in a superposed manner, a gap is generally generated between the left and right outer wall materials 10 and 10. The gap can be closed by a closing member such as a sealer or packing. However, in the non-sealing method, the gap can be closed so that the closing member is not exposed to the outer surface. Alternatively, this gap can be used for the communication port 4. 12A, 12B, and 12C are examples in which the gap between the outer wall materials 10 and 10 is closed. 12D and 12E, the gap between the outer wall materials 10 and 10 is not closed, and the gap between the outer wall materials 10 and 10 is made to function as the communication port 4 so that the outside and the ventilation space 3 communicate with each other. It is an example.

  12A and 12B, by providing a sealer material 25 such as an ept sealer between the steel plate material 26 provided on the surface of the steel plate base material 27 and the outer wall material 10, a gap between the outer wall materials 10 is provided. It is closed and the outside and the ventilation space 3 are separated. FIG. 12A shows an example in which the outer wall member 10 is formed by using the outer wall member 10 having a flat end surface at the side end portion and abutting the outer wall member 10 in the lateral direction. In FIG. 12B, the outer wall material 10 in which the lateral support portion 28 is formed on one side end portion and the lateral overlap portion 29 is formed on the other side end portion is used. An example in which the outer wall portion 1 is formed by overlapping the overlapping portions 29 is shown. In the case of FIG.12 (b), the wall base 2 can be hidden and a clearance gap can be made not conspicuous. In addition, in the form of Fig.12 (a) and (b), the ventilation space 3 is divided | segmented by the horizontal direction.

  In FIG. 12C, a vertical joint covering material 24 having a vertical joint covering portion 23 that covers the front surface of the gap between the outer wall members 10 and 10 is disposed between the outer wall members 10 and 10. A sealer member 25 is provided between the back surface and the surface of the outer wall member 10 to close the gap between the outer wall members 10 and 10. In this embodiment, the gap between the outer wall materials 10 can be hidden to make it less noticeable. Moreover, if the hole opened to a horizontal direction is formed in the part adjacent to the ventilation space 3 of the vertical joint coating | covering material 24, the ventilation space 3 can be formed so that it may communicate over a horizontal direction.

  In FIG. 12D, the steel plate material 26 is attached to the wall base 2 at the position of the gap of the outer wall material 10, and the sealer material 25 is provided on the back surface of the side end portion of the outer wall material 10. And the sealer material 25 are not in contact with each other. Therefore, the outside and the ventilation space 3 communicate with each other through the gap between the outer wall materials 10 and 10. The width L of the gap between the outer wall materials 10 and 10 can be set to, for example, about 5 to 20 mm, specifically 12 mm.

  12 (e), in addition to the configuration of FIG. 12 (d), the vertical joint covering material 24 including the vertical joint covering portion 23 covering the front surface of the gap between the outer wall members 10 and 10 is provided between the outer wall members 10 and 10. Is arranged. In this embodiment, the gap between the outer wall materials 10 can be hidden to make it less noticeable. The width L of the gap between the outer wall materials 10 and 10 can be set to, for example, about 5 to 20 mm, specifically 12 mm.

  In addition, although the sealer material 25 is used in said vertical joint structure, since this sealer material 25 is not exposed to the outer surface of an outer wall, it can make it hard to deteriorate.

  In the above embodiment, the example of the outer wall structure using the vertical trunk edge whose longitudinal direction is arranged along the vertical direction (vertical direction) is shown as the trunk edge 11, but the present invention is limited to this. Instead, it may be an outer wall structure using a horizontal trunk edge whose longitudinal direction is arranged along the horizontal direction (horizontal direction).

  In FIG. 13, an example of the attachment structure of the trunk edge 11 is shown. FIG. 13A shows an example of a vertical trunk edge, and FIG. 13B shows an example of a horizontal trunk edge. In these examples, a state in which the outer wall material 10 is attached to the lower left end of the wall surface is shown. In the example of FIG. 13A, the rectangular outer wall material 10 is disposed with the longitudinal direction set in the horizontal direction, and is attached with a so-called horizontal stretch. In the example of FIG. 13B, the rectangular outer wall material 10 is disposed with the longitudinal direction set to the vertical direction, and is attached by so-called vertical tension.

  Since the trunk edge 11 is disposed in the ventilation space 3, there is a possibility that the movement of air may be hindered. Therefore, in order to make the air flow smooth, the communication port 4 is formed in a direction perpendicular to the longitudinal direction of the trunk edge 11, that is, the trunk edge 11 and the communication port 4 are formed substantially orthogonally. Is preferred.

  In the case of FIG. 13A, as described above, the communication port 4 can be provided at the lower end portion of the wall surface (upper side of the base portion 8) and the upper end portion of the wall surface (below the eaves ceiling portion 7). The communication port 4 can also be provided in the gap between the outer wall materials 10. Thereby, the linear communication port 4 can be formed in the horizontal direction which is a direction perpendicular | vertical to a vertical trunk edge.

  In the case of FIG. 13 (b), the communication wall 4 can be formed by providing a portion where the outer wall material 10 does not cover the wall base 2 at the side edge of the wall surface, and the communication port is formed in the gap between the left and right outer wall materials 10. 4 can be provided. Thereby, the linear communication port 4 can be formed in the vertical direction which is a direction perpendicular | vertical to a horizontal trunk edge. In the case of FIG. 13B as well, the communication port 4 may be provided on the upper side of the base part 8 or on the lower side of the eaves part 7. Although the differential pressure can be reduced also in the configuration of FIG. 13B, in order to reduce the differential pressure with the external space, the configuration using the horizontal trunk edge as shown in FIG. The form using the vertical trunk edge as shown in FIG.

  In the above embodiment, the communication port 4 is mainly formed on both the upper side of the base part 8 and the lower side of the eaves part 7, but the present invention is not limited to this. Instead, the communication port 4 may be provided on either the upper side of the base part 8 or the lower side of the eaves part 7. Alternatively, the communication port 4 is not provided on either the upper side of the base portion 8 or the lower side of the eaves top portion 7, and the opening area necessary for the communication port 4 is secured by the gap between the outer wall materials 10. Also good.

  FIG. 14 shows an example of an outer wall structure in which the communication port 4 is formed by a gap between the outer wall materials 10. In this embodiment, the communication port 4 is formed between the outer wall materials 10 and 10 adjacent to each other in the vertical and horizontal directions. That is, the communication port 4 is formed around each outer wall material 10, and the communication port 4 has a lattice shape as a whole wall surface. In this case as well, the total opening area of the communication port 4 is within the above-described range.

  In the above embodiment, the outer wall portion 10 and the ventilation space 3 are formed by attaching the outer wall material 10 to the wall base 2 via the trunk edge 11, but the present invention is limited to this. It is not a thing. For example, without using the trunk edge 11, the outer wall material mounting bracket 12 having the width of the ventilation space 3 as a working width is made to function as a spacer, and the outer wall material mounting bracket 12 is attached to the wall base 2 and the outer wall material mounting bracket 12 A ventilation space 3 may be formed between the outer wall portion 1 and the wall base 2 by attaching the outer wall material 10. Alternatively, a spacer member for securing the thickness of the ventilation space 3 may be used instead of the trunk edge 11.

  The invention is explained in more detail by means of examples.

[Test Example 1]
In Example 1, a test body (house) having an outer wall structure as shown in FIG. 1 was used, and the differential pressure (pressure difference with the external space) generated in the ventilation space 3 was measured. For the test body, a body edge 11 with a thickness of 18 mm and an outer wall material mounting bracket 12 with a protruding width of 5 mm were used, and the thickness of the ventilation space 3 was 23 mm. The trunk edge 11 was a vertical trunk edge, and the outer wall portion 1 was formed by horizontally stretching a rectangular outer wall material 10. Moreover, the wall surface was divided for every surface by the ventilation | gas_flowing part 6 of the structure shown in FIG. Regarding the dimension of the first member 61 of the air dividing portion 6, the first piece is in the range of 25 to 80 mm, the second piece is in the range of 25 to 80 mm, the protruding dimension of the ridge is 5 mm, and the material of the second member 62 is EPDM, and the cross-sectional dimensions thereof were 10 mm × 10 mm. Further, a structural face material 20 made of plywood is used for the wall base 2, and a ventilation parting edge 15 is disposed below the eaves ceiling part 7. The dimension of the wall surface was 2.4 m long × 5.4 m wide (area: 13.0 m ² ). The opening 30 was not provided. The position of the communication port 4 is the upper side of the base portion 8 and the lower side (parting portion) of the eaves ceiling portion 7, and the shape of the communication port 4 is a straight line extending in the lateral direction.

  In Comparative Example 1, the air dividing part 6 was not provided in Example 1.

  Other specifications are as shown in Table 1.

Front surface of the test specimen at a wind speed of 5 m / sec (evaluation of an assumed wind speed of 20 m / sec is measured at a wind speed of 5 m / sec due to equipment constraints and converted by the following conversion formula). Applying wind (wind perpendicular to the wall surface, angle 0 ° to the horizontal direction) or slope wind (wind blowing obliquely to the wall surface, angle 45 ° to the horizontal direction), the ventilation space 3 and the outside The pressure difference was measured at many points on the wall surface, and the maximum value was noted. In order to evaluate the pressure difference at an assumed wind speed of 20 m / sec, the pressure difference is obtained using the conversion formula P = V ² × 1/2 × ρ (P: wind pressure, V: wind speed, ρ: air density). It was. The pressure was measured by averaging 300 points for 30 seconds per measurement point using a Baratron (Nihon KS Corp., 220DD-00001A2B). In addition, the average value of the differential pressure | voltage in Table 1 was calculated | required by the average of 48 measurement locations per surface. The results are shown in Table 1.

  As shown in Table 1, it was confirmed that the differential pressure was smaller in Example 1 provided with the air dividing part 6 than in Comparative Example 1.

[Test Example 2]
Using a test body (house) having an outer wall structure as shown in FIG. 7, the differential pressure (pressure difference with the external space) generated in the ventilation space 3 was measured. For the test body, a body edge 11 with a thickness of 18 mm and an outer wall material mounting bracket 12 with a protruding width of 5 mm were used, and the thickness of the ventilation space 3 was 23 mm. Moreover, the wall surface was divided for every surface by the ventilation | gas_flow part 6 (airtight packing 6a). Further, a structural face material made of plywood was used for the wall base 2, and a ventilation parting edge 15 was disposed on the lower side of the eaves ceiling part 7. The dimension of the wall surface was 2.4 m long × 5.4 m wide (area: 13.0 m ² ). The opening 30 was not provided. The position of the communication port 4 is the upper side of the base portion 8 and the lower side (parting portion) of the eaves ceiling portion 7, and the shape of the communication port 4 is a straight line extending in the lateral direction. Other specifications are as shown in Table 2.

Front surface of the test specimen at a wind speed of 5 m / sec (evaluation of an assumed wind speed of 20 m / sec is measured at a wind speed of 5 m / sec due to equipment constraints and converted by the following conversion formula). Applying wind (wind perpendicular to the wall surface, angle 0 ° to the horizontal direction) or slope wind (wind blowing obliquely to the wall surface, angle 45 ° to the horizontal direction), the ventilation space 3 and the outside The pressure difference was measured at many points on the wall surface, and the maximum value was noted. In order to evaluate the pressure difference at an assumed wind speed of 20 m / sec, the pressure difference is obtained using the conversion formula P = V ² × 1/2 × ρ (P: wind pressure, V: wind speed, ρ: air density). It was. The pressure was measured by averaging 300 points for 30 seconds per measurement point using a Baratron (Nihon KS Corp., 220DD-00001A2B). In addition, the average value of the differential pressure | voltage in Table 2 was calculated | required by the average of 48 measurement locations per surface. The results are shown in Table 2.

  As shown in Table 2, it was confirmed that the differential pressure decreases when the opening area of the communication port 4 is large.

[Test Example 3]
Using a test body (house) having an outer wall structure as shown in FIG. 7, the differential pressure (pressure difference with the external space) generated in the ventilation space 3 was measured. For the test body, a body edge 11 with a thickness of 18 mm and an outer wall material mounting bracket 12 with a protruding width of 5 mm were used, and the thickness of the ventilation space 3 was 23 mm. The trunk edge 11 was a vertical trunk edge, and the outer wall portion 1 was formed by horizontally stretching a rectangular outer wall material 10. Moreover, the wall surface was divided for every surface by the ventilation | gas_flow part 6 (airtight packing 6a). There was no division within the wall. Further, a structural face material made of plywood was used for the wall base 2, and a ventilation parting edge 15 was disposed on the lower side of the eaves ceiling part 7. As for the opening area of the wall base 2, the actual gap was 9 cm ² / m ² , and the effective opening area where the resistance was calculated was 5 cm ² / m ² . The dimension of the wall surface was 2.4 m long × 5.4 m wide (area: 13.0 m ² ). The opening 30 was not provided. The position of the communication port 4 is the upper side of the base portion 8, the lower side of the eaves ceiling portion 7 (parting portion), and the gap (base material portion) between the outer wall materials 10, 10. The shape of the communication port 4 is horizontal A straight line extending in the direction was used. Other specifications are as shown in Table 3.

Front surface of the test specimen at a wind speed of 5 m / sec (evaluation of an assumed wind speed of 20 m / sec is measured at a wind speed of 5 m / sec due to equipment constraints and converted by the following conversion formula). Applying wind (wind perpendicular to the wall surface, angle 0 ° to the horizontal direction) or slope wind (wind blowing obliquely to the wall surface, angle 45 ° to the horizontal direction), the ventilation space 3 and the outside The pressure difference was measured at many points on the wall surface, and the maximum value was noted. In order to evaluate the pressure difference at an assumed wind speed of 20 m / sec, the pressure difference is obtained using the conversion formula P = V ² × 1/2 × ρ (P: wind pressure, V: wind speed, ρ: air density). It was. The pressure was measured by averaging 300 points for 30 seconds per measurement point using a Baratron (Nihon KS Corp., 220DD-00001A2B). The results are shown in Table 3.

  As shown in Table 3, it was confirmed that the differential pressure ΔP decreases as the opening area of the communication port 4 increases. Furthermore, it was confirmed that there was no significant difference in the results regardless of whether the openings were locally or evenly provided on the wall substrate. Furthermore, it was confirmed that the pressure difference tends to be smaller when the communication port is formed on the base side.

DESCRIPTION OF SYMBOLS 101 1st outer wall part 102 2nd outer wall part 2 Wall base 3 Ventilation space 6 Ventilation part 61 First member 62 Second member 631 First piece 632 Second piece 64 Projection

Claims (3)

A wall base, a first outer wall part and a second outer wall part installed at a position on the outdoor side with respect to the wall base, and a ventilation dividing part,
The outer wall portions are butted against each other in a direction crossing each other in plan view;
A ventilation space communicating with the outdoors is formed between the wall base and the outer wall portion,
An outer wall structure in which the ventilation dividing portion divides the ventilation space at a position where the outer wall portions are in contact with each other or in the vicinity thereof. The ventilation dividing part includes a first member and two second members having elasticity,
The first member includes a first piece interposed between the wall base and the first outer wall, and a second piece interposed between the wall base and the second outer wall. The first piece and the second piece are each formed with a protrusion that protrudes toward the first outer wall and a protrusion that protrudes toward the second outer wall,
One of the two second members is the first piece and the first outer wall portion at a position opposite to the position where the outer wall portions are abutted with each other with respect to the ridge in the first piece. Between the second piece and the second outer wall portion at a position opposite to the position where the outer wall portions face each other with respect to the ridge in the second piece. The outer wall structure interposed between the two. A communication port that connects the ventilation space and the outdoors is provided, and the ratio of the opening area of the communication port to the area of the wall surface of the wall base in the ventilation space is 65 cm ² / m ² or more. The outer wall structure as described in.

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