JP5700387B2 - ALC panel mounting structure - Google Patents

Description

  The present invention relates to a mounting structure for attaching an upper end of an ALC panel suitably used as a wall of a building such as an outer wall, a partition wall, a partition wall, and a sleeve wall to a building frame, and more specifically, a veranda in a high-rise building such as an apartment house. It is related with the attachment structure which attaches the upper end of the ALC panel used suitably as walls used outdoors, such as a wall separated from the next door in the doorway, and a sleeve wall in the passage around the entrance.

  Conventionally, lightweight cellular concrete panels (ALC panels) have been widely used as building materials such as building roofing materials, flooring materials, and wall materials because of their excellent properties such as lightness, heat resistance, and fire resistance. ing.

  When the ALC panel is used as a wall material, the upper end and the lower end of the ALC panel are fixed to the building frame. Conventionally, the following example is disclosed as an attachment structure which fixes the upper end of an ALC panel to a building frame.

  That is, for example, Patent Document 1 uses a mounting bracket in which a fixing piece fixed to a housing and an attachment piece for attaching a wall panel are connected in an angle shape to fix the fixing piece to the housing and stand upright from the fixing piece. An attachment structure for attaching the upper end of the wall panel to the housing by fixing the wall surface on the upper end side of the wall panel to the attached attachment piece is disclosed.

  Further, in Patent Documents 2 to 5, a runner having a top plate and a pair of side plates hanging from the top plate is used, the top plate of the runner is fixed to the housing, and the upper end of the wall panel with the pair of side plates. The attachment structure which attaches the wall panel upper end to a housing by pinching | interposing from the outside is disclosed.

Japanese Patent Laid-Open No. 11-10091 Japanese Patent Laid-Open No. 05-9993 Japanese Patent Laid-Open No. 04-153438 JP 2002-129664 A JP 2001-27001 A

  However, if the metal fittings are exposed outside the wall surface of the ALC panel as in the conventional mounting structure for fixing the upper end of the ALC panel to the building frame, the aesthetics are impaired and the ALC panel is mounted outdoors. The exposed metal fittings may rust due to the influence of wind and rain, and the appearance quality may be impaired.

  The problem to be solved by the present invention is that the metal fitting used to attach the upper end of the ALC panel to the building frame is not exposed to the outside of the wall surface of the ALC panel, so that the appearance is excellent even when used outdoors. An object of the present invention is to provide an ALC panel mounting structure capable of maintaining good quality.

  In order to solve the above problems, an ALC panel mounting structure according to the present invention is an ALC panel mounting structure in which an ALC panel is mounted on a building housing, and a plurality of rod-shaped bodies are attached to one end of the building housing. It is fixed directly or indirectly, and the fixed plurality of rod-shaped bodies are loosely inserted into a plurality of insertion holes drilled from the top edge surface of the ALC panel toward the ALC panel. It is a summary.

  In this case, the building housing includes an engaging surface portion to which one end side of the rod-shaped body is engaged, and a leg portion that extends to the engaging surface portion and is directly fixed to the building housing, and an upper end of the ALC panel. A plurality of mounting brackets having a size that fits within the area of the facet surface may be fixed, and the plurality of rod-shaped bodies may be indirectly fixed to the building frame via the plurality of mounting brackets.

  The ALC panel includes an anchor fitting having a tubular body and a cylindrical body disposed in the inner space of the tubular body and having both ends supported by the peripheral surface of the tubular body. The tubular body may be embedded in a position where the tubular body is embedded in the main reinforcement embedded in the rod, and the rod-shaped body may be further loosely inserted into the hole of the tubular body of the anchor metal fitting.

  In the ALC panel mounting structure according to the present invention, the plurality of insertion holes may be provided inside the bar arrangement embedded in the ALC panel in the width direction of the ALC panel. preferable. Moreover, it is preferable that the insertion length of the rod-like body into the ALC panel is longer than the distance from the upper end edge surface of the ALC panel to the bar arrangement embedded in the ALC panel. Moreover, it is preferable that the said rod-shaped body is provided with the base part directly or indirectly fixed to the said building frame, and the rod-shaped part standingly arranged from this base part, and loosely inserted in the said insertion hole. Moreover, it is preferable that the said insertion hole is arrange | positioned 1 each on both sides which pinched | interposed the center position in the width direction of the said ALC panel. The plurality of insertion holes are preferably arranged at equal positions on both sides of the center position in the width direction of the ALC panel.

  Furthermore, in the mounting structure of the ALC panel according to the present invention, the lower end of the ALC panel is sized to fit within the region of the lower end edge surface of the ALC panel, and the width direction and the thickness direction center on the lower end edge surface. It may be fixed to the floor slab via a lower end mounting bracket attached to the part.

  In the mounting structure of the ALC panel according to the present invention, the rod-like body is fixed to the building frame and is loosely inserted into the insertion hole formed in the upper edge of the ALC panel. It is arranged in the area. Thus, the rod-shaped body for attaching the upper end of the ALC panel to the building frame is not exposed outside the wall surface of the ALC panel. Therefore, there is no possibility that the aesthetics of the ALC panel attached by the metal fitting for attaching the upper end of the ALC panel to the building frame will be impaired. In addition, since the metal fitting for attaching the upper end of the ALC panel to the building frame is not exposed to the outside of the wall surface of the ALC panel, even when the ALC panel is installed outdoors, the metal fitting is not easily affected by wind and rain. Therefore, rust is unlikely to occur in this metal fitting. Thereby, even when used outdoors, the appearance quality of the attached ALC panel can be favorably maintained.

  Further, since the rod-like body is loosely inserted into a plurality of insertion holes drilled from the upper end small edge surface of the ALC panel into the ALC panel, the rod-like body is Slide up and down in the insertion hole. Thereby, the ALC panel can be smoothly locked. Therefore, according to the mounting structure of the ALC panel according to the present invention, the tracking performance with respect to interlayer deformation of the ALC panel is also excellent.

  At this time, if the rod-shaped body and the mounting bracket are engaged and the rod-shaped body is indirectly fixed to the building frame via the mounting bracket, the rod-shaped body is inserted when the building frame is deformed between layers. Even if it slides up and down in the hole and swings in the horizontal direction, it can slide smoothly between the rod-shaped body and the mounting bracket. Thereby, the followability with respect to the interlayer deformation of the ALC panel is improved. Moreover, if the followability to the interlayer deformation of the ALC panel is improved in this way, the possibility that the rod-like body may lose the wall surface in the insertion hole is also reduced.

  And if the said anchor metal fitting is used and the said rod-shaped body is the structure inserted loosely in the hole of the cylindrical body of the said anchor metal fitting, the attachment strength of the ALC panel upper end will also improve. Thereby, it is applicable also to the ALC panel of the outdoor use for which the attachment intensity | strength which can endure rain and wind is requested | required.

  In the mounting structure of the ALC panel according to the present invention, if the plurality of insertion holes are provided on the inner side of the reinforcing bar embedded in the ALC panel in the width direction of the ALC panel, the ALC panel has a high strength. Since the rod-shaped body is loosely inserted, the shear pull-out load of the rod-shaped body can be increased. Thereby, the attachment strength of the upper end of the ALC panel is improved. In addition, since the position where the rod-shaped body is loosely inserted into the insertion hole is closer to the inside from the end in the width direction of the ALC panel, the rod-shaped body is locked when the ALC panel is locked than in the case where these are near the end in the width direction. The distance that the slides up and down can be shortened. Thereby, it can suppress that a rod-shaped body twists the inner wall surface of an insertion hole, and a rod-shaped body can slide smoothly with respect to an insertion hole.

  Further, if the insertion length of the rod-like body into the ALC panel is longer than the distance from the upper end edge surface of the ALC panel to the bar arrangement embedded in the ALC panel, the attachment strength at the upper end of the ALC panel is improved.

  In addition, if the rod-shaped body is configured to include a pedestal portion that is directly or indirectly fixed to the building housing and a rod-shaped portion that is erected from the pedestal portion and loosely inserted into the insertion hole, Welding work becomes easy. Further, the engagement with the mounting bracket can be facilitated.

  And if the said insertion hole is arrange | positioned 1 each on both sides which pinched | interposed the center position in the width direction of an ALC panel, a rod-shaped body will slide easily at the time of locking of an ALC panel.

  Further, if the plurality of insertion holes are arranged at equal positions on both sides of the center position in the width direction of the ALC panel, the balance is improved when the ALC panel is locked.

  In the ALC panel mounting structure according to the present invention, the lower end of the ALC panel is sized to fit within the area of the lower end facet of the ALC panel, and is attached to the center in the width direction and the thickness direction of the lower end facet. If it is fixed to the building frame via the lower end mounting bracket, the mounting bracket is not exposed to the outside even at the lower end of the ALC panel. Thereby, the attachment structure of the lower end of an ALC panel is also excellent in aesthetics. Moreover, the appearance quality of the attached ALC panel can be maintained well even when used outdoors. Furthermore, when the building frame undergoes interlayer deformation due to an earthquake, the ALC panel can be rocked smoothly.

  At this time, the lower end of the ALC panel is fixed to the building frame in one place via a lower end mounting bracket attached to the center portion in the width direction and thickness direction on the lower end facet, but the upper end of the ALC panel is Since a plurality of rod-shaped bodies are attached to the building frame by loosely inserting into a plurality of insertion holes, the horizontal direction (outside of the wall surface) of the ALC panel is rotated (returned) after being attached. There is no risk of it occurring.

It is the front view (a) and side view (b) showing the attachment structure of the ALC panel which concerns on 1st embodiment of this invention. It is the front view (a) and top view (b) showing the rod-shaped body which concern on 1st embodiment. It is a perspective view showing an example of the structure of an ALC panel. It is a figure explaining the loose insertion position of the rod-shaped body in the width direction of an ALC panel. It is the front view (a) and side view (b) showing the attachment structure of the ALC panel which concerns on 2nd embodiment of this invention. It is the front view (a) and top view (b) showing the rod-shaped body which concern on 2nd embodiment. It is the front view (a) and top view (b) showing an example of the attachment metal fitting used for attachment of an ALC panel. It is the front view (a) and side view (b) showing the attachment structure of the ALC panel which concerns on 3rd embodiment of this invention. It is the front view (a) and side view (b) showing an example of the anchor metal fitting used for attachment of an ALC panel. It is the front view (a) and side view (b) showing an example of the embedment position of an anchor metal fitting. It is the front view (a) and side view (b) showing the attachment structure of the ALC panel which concerns on 4th embodiment of this invention. It is the front view (a) and side view (b) showing the attachment structure of the lower end of an ALC panel. It is a figure showing the other form of the attachment metal fitting used for attachment of an ALC panel. It is a front view showing the other example of the embedding position of an anchor metal fitting. It is a figure showing the combination of the other form of the rod-shaped body used for attachment of an ALC panel, and the other form of the cylindrical body of an anchor metal fitting. It is a figure showing the combination of the other form of the rod-shaped body used for attachment of an ALC panel, and the other form of the cylindrical body of an anchor metal fitting.

  Next, an embodiment of the present invention will be described in detail.

  As shown in FIG. 1, the ALC panel (lightweight cellular concrete panel) mounting structure 10 according to the first embodiment of the present invention uses two rod-shaped bodies 16 to attach the upper end of the ALC panel 12 to a building housing 14. It consists of things.

  As shown in FIG. 2, the rod-like body 16 includes a pedestal portion 18 having a square disk shape and a rod-like portion 20 erected from the center of the pedestal portion 18. A metal flat bar 22 is fixed to the building housing 14, and a pedestal 18 of the rod-shaped body 16 is fixed to the flat bar 22. The fixing method is not particularly limited, and examples thereof include welding and bolting.

  As shown in FIG. 3, the ALC panel 12 includes a lightweight cellular concrete 24 formed into a plate wall shape, and a reinforcing reinforcing bar 26 embedded in the lightweight cellular concrete 24 to reinforce the concrete. The length direction of the ALC panel 12 is the X direction, the width direction is the Y direction, and the thickness direction is the Z direction.

  The reinforcing reinforcing bars 26 are composed of main bars 26 a arranged along the length direction of the ALC panel 12 and auxiliary bars 26 b arranged along the width direction of the ALC panel 12. Reinforcement mats 28a and 28b are formed by combining a plurality of main reinforcing bars 26a and a plurality of auxiliary reinforcing bars 26b in a lattice pattern. Two reinforcing bar mats 28a and 28b are embedded in the ALC panel 12 along the wall surface 12c of the ALC panel 12, and the pair of reinforcing bar mats 28a and 28b are arranged in parallel in the ALC panel 12 at a predetermined distance. Has been. Reinforcing bar spacers 30 spanning the reinforcing bar mats 28a, 28b are welded to the main reinforcing bars 26a on the side edges of the reinforcing bar mats 28a, 28b, and the reinforcing reinforcing bars 26 are formed in a cage shape. In the reinforcing bar mats 28a and 28b, the auxiliary reinforcing bars 26b of the reinforcing reinforcing bars 26 are arranged inside the ALC panel 12 with respect to the main reinforcing bars 26a.

  The length of the ALC panel 12 is preferably in the range of 1500 to 3500 mm. The width of the ALC panel 12 is preferably in the range of 300 to 610 mm. The thickness of the ALC panel 12 is preferably in the range of 75 to 150 mm.

  An insertion hole 32 having an inner diameter larger than the outer diameter of the rod-shaped portion 20 of the rod-shaped body 16 and a depth exceeding the length of the rod-shaped portion 20 of the rod-shaped body 16 is provided in the upper end facet 12a of the ALC panel 12. The rod-shaped portion 20 is loosely inserted into the insertion hole 32. Thereby, the rod-shaped part 20 can slide in the insertion hole 32 in the vertical direction.

  Here, if the difference between the inner diameter of the insertion hole 32 and the outer diameter of the rod-shaped portion 20 is too large, rattling is likely to occur between the insertion hole 32 and the rod-shaped portion 20 when the ALC panel is installed. Therefore, from the viewpoint of suppressing rattling between the insertion hole 32 and the rod-shaped portion 20 when the ALC panel is installed, and the rod-shaped portion 20 can smoothly slide in the insertion hole 32 when an earthquake occurs, the insertion hole The difference between the inner diameter of 32 and the outer diameter of the rod-shaped portion 20 is preferably in the range of 0.1 to 1.0 mm. More preferably, it exists in the range of 0.1-0.7 mm. In addition, it is preferable that the magnitude | size of the outer diameter of the rod-shaped part 20 of the rod-shaped body 16 exists in the range of 8-16 mm from the relationship with the magnitude | size of the ALC panel 12. FIG.

  It is preferable that the pedestal 18 of the rod-like body 16 has a size that does not protrude outside the region of the upper end facet 12a of the ALC panel 12 (contains within the region). Therefore, it is preferable that the length of one side of the square plate-like pedestal 18 is a length that does not exceed the thickness of the ALC panel 12. Specifically, since the width of the flat bar fixed to the building frame is usually about 65 to 75 mm, the length of one side of the square plate-like pedestal portion 18 is preferably 30 to 60 mm.

  The insertion hole 32 of the ALC panel 12 is preferably provided on the inner side of the reinforcing bar 26 embedded in the ALC panel 12 in the width direction of the ALC panel 12. More specifically, as shown in FIG. 4, the position A of the insertion hole 32 of the ALC panel 12 is more inward in the width direction than the position B of the main bar 26 a disposed at the extreme end in the width direction of the ALC panel 12. Preferably there is. Since the portion inside the reinforcing reinforcing bars 26 in the width direction is reinforced by the reinforcing reinforcing bars 26, the panel strength is higher than the portion outside the reinforcing reinforcing bars 26. That is, since the rod-like body 16 is loosely inserted into the portion where the strength of the ALC panel 12 is high, the shear pulling load of the rod-like body 16 can be increased. Thereby, the attachment strength of the upper end of the ALC panel 12 can be improved.

  Further, the position of the insertion hole 32 of the ALC panel 12 is set to the inside of the reinforcing reinforcing bar 26, so that the position where the rod-like body 16 is loosely inserted into the insertion hole 32 is inevitably inside the end of the ALC panel 12 in the width direction. I will stop by. As a result, the distance that the rod-like body 16 slides in the insertion hole 32 in the vertical direction when the ALC panel 12 is locked can be shortened as compared with the case where these are near the ends in the width direction. The shorter the sliding distance of the rod-shaped body 16 in the insertion hole 32, the less the rod-shaped body 16 is brought into frictional contact with the inner wall surface of the insertion hole 32. Therefore, it is possible to prevent the rod-shaped body 16 from squeezing the inner wall surface of the insertion hole 32, and the rod-shaped body 16 can slide smoothly with respect to the insertion hole 32.

  The reinforcing reinforcing bars 26 are normally embedded up to a position of 50 mm from the end in the width direction of the ALC panel 12. Therefore, specifically, the insertion hole 32 of the ALC panel 12 is preferably located at a position 75 mm or more away from the end in the width direction of the ALC panel 12 inward.

  On the other hand, as the position of the insertion hole 32 of the ALC panel 12 approaches the center in the width direction of the ALC panel 12, the ALC panel 12 is easily rotated in the horizontal direction (outward direction of the wall surface). Further, since the pedestal portion 18 of the rod-shaped body 16 has a predetermined size, there is a limit in arranging a plurality of rod-shaped bodies 16 near the center in the width direction of the ALC panel 12. From this viewpoint, it is preferable that the insertion hole 32 of the ALC panel 12 is located at a position away from the center in the width direction of the ALC panel 12 by 50 mm or more.

  Moreover, it is preferable that the rod-shaped body 16 is inserted to a position where it is reinforced by the reinforcing reinforcing bars 26 in the ALC panel 12. More specifically, as shown in FIG. 4, the tip position C of the rod-shaped portion 20 of the rod-shaped body 16 is larger than the position D of the accessory muscle 26 b arranged at the extreme end in the length direction of the ALC panel. It is preferable that it exists in the inside of a length direction. Thereby, the attachment strength of the upper end of the ALC panel 12 can be improved. In other words, the length of insertion of the rod-like body 16 into the ALC panel 12 is preferably longer than the distance from the upper end facet 12a of the ALC panel 12 to the reinforcing reinforcing bars 26 embedded in the ALC panel 12. . The length (covering dimension) from the reinforcing reinforcing bar 26 embedded in the ALC panel 12 to the panel upper end facet 12a is about 8 to 28 mm.

  When the ALC panel 12 is attached to the building housing 14, the gap between the building housing 14 and the upper edge surface 12a of the ALC panel 12 is normally set to about 20 mm. Then, if the rod-like body 16 is inserted into the ALC panel 12 by 40 mm or more, even if the rod-like body 16 slides up and down when the ALC panel 12 is locked, the rod-like body 16 is not likely to come out of the insertion hole 32. . Further, since the cover size is about 8 to 28 mm, if the rod-like body 16 is inserted into the ALC panel 12 by 40 mm or more, the mounting strength of the upper end of the ALC panel 12 can be improved reliably.

  Therefore, the insertion length of the rod-like body 16 into the ALC panel 12 is preferably 40 mm or more. More preferably, it is 50 mm or more. Further, the length of the rod-shaped portion 20 of the rod-shaped body 16 is preferably 60 mm or more. More preferably, it is 70 mm or more. On the other hand, the upper limit of the length of the rod-shaped portion 20 is preferably 150 mm or less. This is because the longer the rod-shaped portion 20 is, the easier it is to bend the inner wall surface of the insertion hole 32 when the ALC panel 12 is locked.

  In the ALC panel mounting structure 10, it is preferable that one insertion hole 32 is disposed on each side of the ALC panel 12 across the center position in the width direction. Thereby, the rod-shaped body 16 is easily slid smoothly when the ALC panel 12 is locked. Further, the insertion holes 32 are preferably arranged at equal positions on both sides of the center position in the width direction of the ALC panel 12. This improves the balance when the ALC panel 12 is locked.

  For example, the ALC panel 12 can be attached to the building housing 14 as follows. First, the insertion hole 32 is formed at a predetermined position and a predetermined depth at a predetermined position of the upper end facet 12 a of the ALC panel 12. Next, the rod-shaped portion 20 of the rod-shaped body 16 is inserted into the insertion hole 32. Next, the upper end edge surface 12a of the ALC panel 12 is opposed to the flat bar 22 fixed to the building housing 14 with a predetermined interval. Next, the rod-shaped portion 20 of the rod-shaped body 16 is slid upward to bring the pedestal portion 18 of the rod-shaped body 16 into contact with the flat bar 22. Next, the edge of the pedestal 18 is welded to the flat bar 22.

  At this time, since welding is performed in the gap between the upper end small edge surface 12a of the ALC panel 12 and the building housing 14, the rod-like body 16 has the pedestal portion 18, so that the base portion of the rod-like portion 20 is in a deep position. Since welding can be performed at the position of the edge of the pedestal 18 disposed on the front side, the welding work of the rod-shaped body 16 to the building housing 14 is facilitated. Furthermore, since the shape of the pedestal portion 18 is a square disk shape, if one side to be welded is aligned in parallel to the width direction of the upper end facet 12a of the ALC panel 12, the welding operation is further facilitated.

  After welding the pedestal portion 18 of the rod-shaped body 16 to the flat bar 22, a sealing material may be filled in the gap between the upper end of the ALC panel 12 and the building housing 14 for the purpose of waterproofing or the like, if necessary. it can. Examples of the material for the sealing material include polyurethane materials and modified silicone materials.

  According to the ALC panel mounting structure 10 having the above-described configuration, the rod-like body 16 is loosely inserted into the insertion hole 32 that is fixed to the building housing 14 and drilled in the top edge surface 12a of the ALC panel 12. Therefore, the ALC panel 12 is disposed in the region of the upper edge edge surface 12a. Thus, the rod-like body 16 for attaching the upper end of the ALC panel 12 to the building housing 14 is not exposed to the outside of the wall surface 12c of the ALC panel 12. Therefore, there is no possibility that the aesthetic appearance of the attached ALC panel 12 is impaired by the metal fitting for attaching the upper end of the ALC panel 12 to the building housing 14. In addition, since the metal fitting for attaching the upper end of the ALC panel 12 to the building housing 14 is not exposed to the outside of the wall surface 12c of the ALC panel 12, this metal fitting is affected by wind and rain even when the ALC panel 12 is installed outdoors. It is hard to receive. Therefore, rust is unlikely to occur in this metal fitting. Thereby, even when used outdoors, the appearance quality of the attached ALC panel 12 can be maintained well.

  Further, since the rod-like body 16 is loosely inserted into the plurality of insertion holes 32 drilled from the upper end small facet 12a of the ALC panel 12 into the ALC panel, when the building housing 14 undergoes interlayer deformation due to an earthquake, The rod-like body 16 slides up and down in the insertion hole 32. Thereby, since the ALC panel 12 can be locked smoothly, it is excellent also in the follow-up performance with respect to the interlayer deformation of the ALC panel 12.

  Next, an ALC panel mounting structure according to the second embodiment of the present invention will be described.

  As shown in FIG. 5, the ALC panel mounting structure 110 according to the second embodiment is obtained by mounting the upper end of the ALC panel 12 to the building housing 14 using two rod-shaped bodies 116 and two mounting brackets 134. Consists of. Since the configuration of the ALC panel 12 is the same as that of the first embodiment, description thereof is omitted.

  As shown in FIG. 6, the rod-shaped body 116 includes a disk-shaped pedestal portion 118 and a rod-shaped portion 120 erected from the center of the pedestal portion 118.

  As shown in FIG. 7, the mounting bracket 134 has a plate-like engagement surface portion 136 with which the pedestal portion 118 of the rod-like body 116 is engaged, and extends at both ends of the engagement surface portion 136 and is folded from both ends. And a pair of leg portions 138 formed with a bend. A through hole 140 having an inner diameter large enough to allow insertion of the rod-shaped portion 120 of the rod-shaped body 116 is formed at the center of the engaging surface portion 136. Further, the tip 138 a of the leg 138 is bent so as to open outward in a direction parallel to the engagement surface 136. A recess 142 is formed by the engagement surface 136 and the pair of legs 138. Thus, the attachment fitting 134 is configured in a hat shape as a whole.

  The mounting bracket 134 is configured to have a size that does not protrude from the region of the upper edge surface 12a of the ALC panel 12 (contains within the region). For example, as shown in FIG. 5, when the mounting bracket 134 is disposed along the width direction of the ALC panel 12, the width of the mounting bracket 134 is a size that does not exceed the thickness of the ALC panel 12. Further, when the mounting bracket 134 is disposed along the thickness direction of the ALC panel 12, the length of the mounting bracket 134 does not exceed the thickness of the ALC panel 12.

  As shown in FIG. 5, the rod-shaped portion 120 of the rod-shaped body 116 is inserted through the through hole 140 from the inside of the engagement surface portion 136 to the base end, and the pedestal portion 118 of the rod-shaped body 116 is accommodated in the recess 142. And is engaged with the engaging surface portion 136. And the front-end | tip 138a of the leg part 138 parallel to the engaging surface part 136 is being fixed to the metal flat bar 22 fixed to the building housing 14 by welding etc. As shown in FIG. Therefore, the rod-like body 116 is fixed to the flat bar 22 via the mounting bracket 134.

  An insertion hole 32 having an inner diameter larger than the outer diameter of the rod-shaped portion 120 of the rod-shaped body 116 and having a depth exceeding the length of the rod-shaped portion 120 of the rod-shaped body 116 is provided in the upper end facet 12a of the ALC panel 12. The rod-shaped portion 120 of the rod-shaped body 116 is loosely inserted into the insertion hole 32. The difference between the inner diameter of the insertion hole 32 and the outer diameter of the rod-shaped portion 120 is preferably in the range of 0.1 to 1.0 mm, as in the ALC panel mounting structure 110 of the first embodiment. More preferably, it exists in the range of 0.1-0.7 mm.

  It is preferable that the pedestal portion 118 of the rod-like body 116 has a size that does not protrude outside from the region of the upper end edge surface 12 a of the ALC panel 12. Therefore, the diameter of the disk-shaped pedestal portion 118 is preferably a size that does not exceed the thickness of the ALC panel 12. Specifically, the diameter of the disk-shaped pedestal portion 118 is preferably 30 to 60 mm.

  The diameter of the rod-shaped portion 120 of the rod-shaped body 116, the length of the rod-shaped portion 120 of the rod-shaped body 116, the insertion length of the rod-shaped body 116 into the ALC panel 12, the size of the inner diameter of the insertion hole 32, the insertion What is necessary is just to set the depth of the hole 32, the position of the insertion hole 32 in the width direction of the ALC panel 12, etc. similarly to the attachment structure 110 of the ALC panel of 1st embodiment.

  For example, the ALC panel 12 can be attached to the building housing 14 as follows. First, the insertion hole 32 is formed at a predetermined position and a predetermined depth at a predetermined position of the upper end facet 12 a of the ALC panel 12. Next, the rod-shaped portion 120 of the rod-shaped body 116 is inserted into the through hole 140 of the engagement surface portion 136 from the inside of the engagement surface portion 136 of the mounting bracket 134. Next, the rod-shaped portion 120 of the rod-shaped body 116 is inserted into the insertion hole 32 of the ALC panel 12. Next, the upper end edge surface 12a of the ALC panel 12 is opposed to the flat bar 22 fixed to the building housing 14 with a predetermined interval. Next, the tip 138 a of the leg portion 138 of the mounting bracket 134 is brought into contact with the flat bar 22. Next, the tip 138 a of the leg portion 138 of the mounting bracket 134 is welded to the flat bar 22. Thereafter, if necessary, a sealing material may be filled in a gap generated between the upper end of the ALC panel 12 and the building housing 14 for the purpose of waterproofing or the like.

  In the ALC panel mounting structure 110 having the above-described configuration, the rod-shaped body 116 is fixed to the building housing 14 via the mounting bracket 134 and is inserted into the insertion hole 32 formed in the upper end facet 12a of the ALC panel 12. Since it is loosely inserted into the ALC panel 12, the ALC panel 12 is disposed in the region of the top edge surface 12 a. Thus, the rod-like body 116 for attaching the upper end of the ALC panel 12 to the building housing 14 is not exposed to the outside of the wall surface 12c of the ALC panel 12. Further, the mounting bracket 134 used together with the rod-shaped body 116 is configured to have a size that does not protrude outside (contains within the region) from the region of the upper end facet 12 a of the ALC panel 12. Therefore, there is no possibility that the aesthetic appearance of the attached ALC panel 12 is impaired by the metal fitting for attaching the upper end of the ALC panel 12 to the building housing 14. In addition, since the metal fitting for attaching the upper end of the ALC panel 12 to the building housing 14 is not exposed to the outside of the wall surface 12c of the ALC panel 12, this metal fitting is affected by wind and rain even when the ALC panel 12 is installed outdoors. It is hard to receive. Therefore, rust is unlikely to occur in this metal fitting. Thereby, even when used outdoors, the appearance quality of the attached ALC panel 12 can be maintained well.

  Moreover, since the rod-shaped body 116 is loosely inserted into the insertion hole 32 drilled from the upper end small edge surface 12a of the ALC panel 12 into the ALC panel 12, when the building housing 14 is deformed between layers by an earthquake, The rod-like body 116 slides up and down in the insertion hole 32. Thereby, since the ALC panel 12 can be locked smoothly, it is excellent also in the follow-up performance with respect to the interlayer deformation of the ALC panel 12.

  In the ALC panel mounting structure 110 of the second embodiment, unlike the ALC panel mounting structure 110 of the first embodiment, the pedestal 118 of the rod-shaped body 116 is made of a metal fixed to the building housing 14. It is not fixed directly to the flat bar 22 but is fixed to the building frame 14 via a mounting bracket 134. Since the pedestal portion 118 of the rod-shaped body 116 and the mounting bracket 134 are merely engaged with each other and are not integrated by welding or the like, the pedestal portion 118 of the rod-shaped body 116 is attached to the mounting bracket 134 within the recess 142. It is possible to move freely without being constrained by the engagement surface portion 136.

  Therefore, when the building housing 14 undergoes interlayer deformation, even if the rod-like body 116 slides in the vertical direction within the insertion hole 32 and swings in the horizontal direction, the base 118 and the mounting bracket 134 of the rod-like body 116 are engaged. It can slide smoothly in the horizontal direction between the surface portion 136. Thereby, the followability with respect to the interlayer deformation of the ALC panel 12 is further improved. In addition, if the followability to the interlayer deformation of the ALC panel 12 is improved as described above, the possibility that the rod-like body 116 may lose the inner wall surface of the insertion hole 32 is also reduced.

  Further, since the pedestal portion 118 of the rod-shaped body 116 can move freely without being constrained by the engagement surface portion 136 of the mounting bracket 134, the pedestal portion 118 is rotated in a horizontal plane with the ALC panel 12 attached. There is. Here, since the pedestal portion 118 is disk-shaped, if the diameter does not exceed the thickness of the ALC panel 12, even if the pedestal portion 118 of the rod-shaped body 116 is rotated in the horizontal plane, the pedestal portion There is no possibility that 118 is exposed outside the region of the upper edge edge surface 12a of the ALC panel 12.

  Next, an ALC panel mounting structure according to the third embodiment will be described.

  As shown in FIG. 8, the ALC panel mounting structure 210 according to the third embodiment is obtained by mounting the upper end of the ALC panel 212 to the building frame 14 using two rod-shaped bodies 16 and two anchor fittings 244. Consists of. Since the rod-like body 16 has the same configuration as that of the first embodiment, description thereof is omitted.

  The ALC panel 212 includes a lightweight cellular concrete 24 formed into a plate wall shape, a reinforcing reinforcing bar 26 embedded in the lightweight cellular concrete 24 to reinforce the concrete, and an anchor metal fitting 244 embedded in the lightweight cellular concrete 24. I have. Since the lightweight cellular concrete 24 and the reinforcing reinforcing bars 26 in the ALC panel 212 have the same configuration as that of the first embodiment, description thereof is omitted.

  As shown in FIG. 9, the anchor fitting 244 includes a tubular body 246 formed in a square tubular shape and a cylindrical body 248 formed in a cylindrical shape.

  The tubular body 246 has a pair of welded surface portions 250a and 250b welded to the reinforcing reinforcing bars 26 embedded in the ALC panel 212, and a pair of connection surface portions 252a and 252b connecting the pair of welded surface portions 250a and 250b. And. The peripheral surface of the tubular body 246 is formed by the pair of welding surface portions 250a and 250b and the pair of connection surface portions 252a and 252b, and the tubular body 246 is hollow. The welding surface portions 250a and 250b and the connection surface portions 252a and 252b are formed in a flat shape, the pair of welding surface portions 250a and 250b are arranged in parallel to each other, and the pair of connection surface portions 252a and 252b are parallel to each other. Is arranged. Circular through holes 254a and 254b are formed at the center positions of the connecting surface portions 252a and 252b of the tubular body 246, respectively.

  A cylindrical body 248 is disposed in the internal space of the hollow tubular body 246. One end portion 248a of the cylindrical body 248 is inserted through the through hole 254a of the one connection surface portion 252a, and the peripheral edge of the one end portion 248a is welded to the one connection surface portion 252a. The other end 248b of the cylindrical body 248 is inserted into the through hole 254b of the other connecting surface 252b, and the periphery of the other end 248b is welded to the other connecting surface 252b. Thereby, both ends of the cylindrical body 248 are supported by the connecting surface portions 252a and 252b of the tubular body 246.

  As shown in FIG. 10A, two anchor fittings 244 having such a configuration are arranged along the width direction of the ALC panel 212. Further, as shown in FIG. 10B, the anchor metal fitting 244 is disposed between a pair of reinforcing bar mats 28a and 28b embedded in the ALC panel 212. And the welding surface parts 250a and 250b of the tubular body 246 of the anchor metal fitting 244 are arranged in parallel to the wall surface 212c of the ALC panel 212. Further, the connecting surface portions 252 a and 252 b of the tubular body 246 are arranged in parallel to the upper end edge surface 212 a of the ALC panel 212. Both open ends of the tubular body 246 are opened in the width direction of the ALC panel 212.

  The thickness of the anchor fitting 244 is the length in the thickness direction of the ALC panel 212 and corresponds to the distance between the welded surface portions 250a and 250b of the tubular body 246. The welded surface portions 250a and 250b The length is adjusted according to the distance between the reinforcing bar mats 28a and 28b so as to be in contact with 26b or to be close to the auxiliary reinforcing bar 26b so as to be weldable.

  As shown in FIG. 10 (a), one main bar 26a is applied to the welded surface portions 250a and 250b of the tubular body 246, respectively. That is, one main reinforcing bar 26a is arranged on the outer side in the thickness direction of the welded surface portions 250a and 250b. In the ALC panel 212, the tubular body 246 is disposed at a position in the width direction where one main reinforcing bar 26a is applied to each of the welding surface portions 250a and 250b, and is restrained from both sides by a total of two main reinforcing bars 26a in the thickness direction. . As a result, the mounting strength at the upper end of the ALC panel 212 is improved, so that it can also be applied to an ALC panel for outdoor use that requires mounting strength that can withstand rain and wind. Here, the main reinforcement 26a being applied to the welded surface portions 250a and 250b means that the main reinforcement 26a is in the region in the width direction of the surfaces of the welded surface portions 250a and 250b.

  Further, the welding surface portions 250a and 250b of the tubular body 246 have a length equal to or longer than the distance between the secondary reinforcing bars 26b of the reinforcing bar mats 28a and 28b, and the welding surface portions 250a and 250b each include two auxiliary reinforcing bars 26b. Is on. That is, the two auxiliary reinforcing bars 26b are arranged on the outer sides in the thickness direction of the welded surface portions 250a and 250b. In the ALC panel 212, the tubular body 246 is arranged at the position in the length direction where the two auxiliary bars 26b are respectively applied to the welding surface portions 250a and 250b, and is restrained from both sides by a total of four auxiliary bars 26b in the thickness direction. Has been. Here, the fact that the secondary reinforcement 26b is applied to the welded surface portions 250a and 250b means that the secondary reinforcement 26b is present in a region in the length direction of the surfaces of the welded surface portions 250a and 250b.

  One welded surface portion 250a of the tubular body 246 is welded to the two accessory bars 26b of the one reinforcing bar mat 28a, and the other welded surface portion 250b of the tubular body 246 is welded to the two accessory bars 26b of the other reinforcing bar mat 28b. It is welded to. Therefore, the tubular body 246 is welded to the accessory bar 26b of the reinforcing bar mat 28a and is also welded to the accessory bar 26b of the reinforcing bar mat 28b.

  Both ends of the cylindrical body 248 of the anchor metal fitting 244 are welded to the coupling surface portions 252a and 252b so as to bridge between the coupling surface portions 252a and 252b of the tubular body 246, and the axial direction of the cylindrical body 248 is an ALC panel. It arrange | positions so that it may become parallel to the length direction of 212. As shown in FIG. 8, the cylindrical body 248 communicates with an insertion hole 232 provided from the upper end facet 212 a of the ALC panel 212 toward the inside of the ALC panel 212, and the rod-shaped portion 20 of the rod-shaped body 16 is Further, it is loosely inserted into the hole 256 of the cylindrical body 248 of the anchor fitting 244 through the insertion hole 232. Thereby, the rod-shaped part 20 can slide up and down in the insertion hole 232 and the hole 256 of the cylindrical body 248.

  Here, the insertion hole 232 and the hole 256 of the cylindrical body 248 allow the rod-shaped portion 20 to slide smoothly and suppress the rattling between the insertion hole 232 and the rod-shaped portion 20. The difference between the inner diameter of 232 and the outer diameter of the rod-shaped portion 20 is preferably within a range of 0.1 to 1.0 mm. More preferably, it exists in the range of 0.1-0.7 mm. The inner diameter of the cylindrical body 248 may be approximately the same as the inner diameter of the insertion hole 232.

  The size of the tubular body 246 of the anchor metal fitting 244 embedded in the ALC panel 212 can be appropriately determined in consideration of the size of the ALC panel 212. The length, width, and thickness of the tubular body 246 are the dimension in the length direction, the dimension in the width direction, and the dimension in the thickness direction of the ALC panel 212, respectively. The length of the tubular body 246 is preferably in the range of 50 to 180 mm. The width of the tubular body 246 is preferably in the range of 80 to 200 mm. The thickness of the tubular body 246 is preferably in the range of 30 to 110 mm. The plate thickness of the tubular body 246 is preferably in the range of 1.5 to 3.5 mm.

  The insertion length of the rod-like body 16 into the ALC panel 212, the size of the inner diameter of the insertion hole 232, the position of the insertion hole 232 in the width direction of the ALC panel 212, etc. are the same as those of the ALC panel mounting structure 10 of the first embodiment. It may be set similarly.

  The ALC panel 212 can be manufactured, for example, as follows. First, the reinforcing bars 26 are assembled in a cage shape, and the anchor fitting 244 is welded to a predetermined position of the reinforcing bars 26. Next, the reinforcing reinforcing bar 26 to which the anchor fitting 244 is welded is placed in the mold. Next, a siliceous raw material and a calcareous raw material, which are the main raw materials of the lightweight cellular concrete 24, a foaming agent, water, and various additives as necessary are kneaded with a mixer. Next, the slurry obtained by kneading is poured into a mold in which the reinforcing steel bars 26 are arranged. Next, the semi-cured material obtained with the slurry having a predetermined hardness is demolded and cut into a predetermined size. Next, the semi-cured body having a predetermined size is cured with high-temperature and high-pressure steam. Thereby, the ALC panel 212 is obtained. The ALC panel 212 may be subjected to various types of processing after being cured.

  Usually, the mold is arranged so that the length direction of the ALC panel 212 is the horizontal direction and the width direction of the ALC panel 212 is the vertical direction. When the formwork is arranged in this way, the slurry foams in the formwork and swells (expands and rises) in the width direction of the ALC panel 212. Since both ends of the tubular body 246 of the anchor metal fitting 244 welded to the reinforcing reinforcing bar 26 are opened along the width direction of the ALC panel 212, the foaming and rising slurry can pass through the hollow of the tubular body 246. . Thereby, the foaming rise of a slurry is not prevented. Further, since the increase in foaming of the slurry is not hindered, it is possible to reduce the possibility that voids are generated in the ALC panel 212. In addition, a decrease in strength of the ALC panel 212 due to this can be suppressed.

  As a siliceous raw material used as a main raw material of the lightweight cellular concrete 24, silica stone or quartz sand is common, as a calcareous raw material, quick lime and cement are common, and as a foaming agent, metallic aluminum is common. .

  For example, the ALC panel 212 can be attached to the building housing 14 as follows. First, an insertion hole 232 having a predetermined size and a predetermined depth is formed in the upper end facet 212a of the ALC panel 212 at a position communicating with the hole 256 of the cylindrical body 248 of the anchor metal fitting 244 embedded. Next, the rod-shaped portion 20 of the rod-shaped body 16 is inserted into the insertion hole 232 and the hole 256 of the cylindrical body 248. Next, the upper end facet 212a of the ALC panel 212 is opposed to the flat bar 22 fixed to the building housing 14 with a predetermined interval. Next, the rod-shaped portion 20 of the rod-shaped body 16 is slid upward to bring the pedestal portion 18 into contact with the flat bar 22. Next, the pedestal 18 is welded to the flat bar 22. Thereafter, if necessary, a sealing material may be filled in the gap between the upper end of the ALC panel 212 and the building housing 14 for the purpose of waterproofing or the like.

  According to the ALC panel mounting structure 210 having the above-described configuration, the rod-like body 16 is fixed to the building housing 14 and is inserted into the insertion hole 232 formed in the upper end facet 212 a of the ALC panel 212 and the insertion hole 232. Since it is loosely inserted in the cylindrical body 248 of the anchor metal fitting 244 communicated with the ALC panel 212, it is arranged in the region of the upper end facet 212 a of the ALC panel 212. Thus, the rod-like body 16 for attaching the upper end of the ALC panel 212 to the building housing 14 is not exposed to the outside of the wall surface 212c of the ALC panel 212. Therefore, there is no possibility that the aesthetic appearance of the attached ALC panel 212 may be impaired by the metal fitting for attaching the upper end of the ALC panel 212 to the building housing 14. In addition, since the metal fitting for attaching the upper end of the ALC panel 212 to the building housing 14 is not exposed to the outside of the wall surface 212c of the ALC panel 212, this metal fitting is affected by wind and rain even when the ALC panel 212 is installed outdoors. It is hard to receive. Therefore, rust is unlikely to occur in this metal fitting. Thereby, even when used outdoors, the appearance quality of the attached ALC panel 212 can be favorably maintained.

  Further, since the rod-like body 16 is loosely inserted in the insertion hole 232 and the cylindrical body 248 communicating with the insertion hole 232, when the building housing 14 is deformed between layers by an earthquake, the rod-like body 16 is inserted in the insertion hole 232 and It slides up and down in the cylindrical body 248. Thereby, since the ALC panel 212 can be locked smoothly, the ALC panel 212 is also excellent in follow-up performance with respect to interlayer deformation.

  In the ALC panel mounting structure 210 according to the third embodiment, unlike the ALC panel mounting structure 10 according to the first embodiment, anchor fittings 244 are embedded in the ALC panel 212, and the rod-shaped body 16 is Through the insertion hole 232, the anchor fitting 244 is loosely inserted into the hole 256 of the cylindrical body 248. Therefore, the attachment strength at the upper end of the ALC panel 212 is also excellent. Accordingly, the present invention can also be applied to an ALC panel 212 for outdoor use that requires a mounting strength that can withstand rain and wind. Further, in the ALC panel mounting structure 210 of the third embodiment, the main reinforcement 26a is applied to the welded surface portions 250a, 250b of the tubular body 246 of the anchor fitting 244. Thereby, the attachment strength at the upper end of the ALC panel 212 can be further improved. For example, in the ALC panel mounting structure 210, a shear pulling strength of 6000 N or more can be obtained with two anchor fittings 244 for one main reinforcing bar 26a.

  Next, an ALC panel mounting structure according to the fourth embodiment will be described.

  As shown in FIG. 11, the ALC panel mounting structure 310 according to the fourth embodiment uses two rod-shaped bodies 116, two mounting brackets 134, and two anchor brackets 244 to connect the upper end of the ALC panel 212 to the building. It consists of what was attached to the housing 14.

  Since the ALC panel 212 has the same configuration as that of the third embodiment, description thereof is omitted. Moreover, since the rod-shaped body 116 is the same structure as the thing of 2nd embodiment, description is abbreviate | omitted. Furthermore, since the mounting bracket 134 has the same configuration as that of the second embodiment, description thereof is omitted.

  In the ALC panel mounting structure 310 according to the fourth embodiment, like the ALC panel mounting structure 110 according to the second embodiment, the bar-shaped portion 120 of the bar-shaped body 116 is engaged with the engaging surface portion of the mounting bracket 134 up to its proximal end. The through hole 140 is inserted from the inside of 136, and the pedestal portion 118 of the rod-like body 116 is accommodated in the concave portion 142 of the mounting bracket 134 and engaged with the engagement surface portion 136. And the front-end | tip 138a of the leg part 138 of the attachment metal fitting 134 is being fixed to the metal flat bar 22 fixed to the building housing 14 by welding etc. As shown in FIG. That is, the rod-like body 116 is fixed to the flat bar 22 via the mounting bracket 134.

  Further, in the ALC panel mounting structure 310 according to the fourth embodiment, the anchor metal fitting 244 is embedded in the ALC panel 212, similarly to the ALC panel mounting structure 210 according to the third embodiment. The cylindrical body 248 communicates with the insertion hole 232 provided from the upper end small edge surface 212 a of the ALC panel 212 toward the inside of the ALC panel 212. The rod-shaped portion 120 of the rod-shaped body 116 is loosely inserted into the insertion hole 232 and is also loosely inserted into the cylindrical body 248 communicated with the insertion hole 232.

  The insertion length of the rod-like body 116 into the ALC panel 212, the size of the inner diameter of the insertion hole 232, the position of the insertion hole 232 in the width direction of the ALC panel 212, etc. are the same as those of the ALC panel mounting structure 10 of the first embodiment. It may be set similarly. Further, the arrangement of the anchor metal fittings 244 in the ALC panel 212 may be set similarly to the ALC panel mounting structure 210 of the third embodiment.

  For example, the ALC panel 212 can be attached to the building housing 14 as follows. First, an insertion hole 232 having a predetermined size and a predetermined depth is formed in the upper end facet 212a of the ALC panel 212 at a position communicating with the hole 256 of the cylindrical body 248 of the anchor metal fitting 244 embedded. Next, the rod-shaped portion 120 of the rod-shaped body 116 is inserted into the through hole 140 of the engagement surface portion 136 from the inside of the engagement surface portion 136 of the mounting bracket 134. Next, the rod-shaped portion 120 of the rod-shaped body 116 is inserted into the insertion hole 232 and the hole 256 of the cylindrical body 248 communicated therewith. Next, the upper end facet 212a of the ALC panel 212 is opposed to the flat bar 22 fixed to the building housing 14 with a predetermined interval. Next, the tip 138 a of the leg portion 138 of the mounting bracket 134 is brought into contact with the flat bar 22. Next, the tip 138 a of the leg portion 138 of the mounting bracket 134 is welded to the flat bar 22. Thereafter, a sealing material can be filled in the gap between the upper end of the ALC panel 212 and the building housing 14 for the purpose of waterproofing or the like, if necessary.

  In the ALC panel mounting structure 310 having the above-described configuration, the rod-shaped body 116 is fixed to the building housing 14 via the mounting bracket 134 and is inserted into the insertion hole 232 drilled in the upper end facet 212a of the ALC panel 212. Since it is loosely inserted into the cylindrical body 248 of the anchor metal fitting 244 communicated therewith, it is arranged in the region of the upper end edge surface 212a of the ALC panel 212. Thus, the rod-shaped body 116 for attaching the upper end of the ALC panel 212 to the building housing 14 is not exposed to the outside of the wall surface 212c of the ALC panel 212. Further, the mounting bracket 134 used together with the rod-like body 116 is configured to have a size that does not protrude outside (contains within the region) from the region of the upper end facet 212a of the ALC panel 212. Therefore, there is no possibility that the aesthetic appearance of the attached ALC panel 212 may be impaired by the metal fitting for attaching the upper end of the ALC panel 212 to the building housing 14. In addition, since the metal fitting for attaching the upper end of the ALC panel 212 to the building housing 14 is not exposed to the outside of the wall surface 212c of the ALC panel 212, this metal fitting is affected by wind and rain even when the ALC panel 212 is installed outdoors. It is hard to receive. Therefore, rust is unlikely to occur in this metal fitting. Thereby, even when used outdoors, the appearance quality of the attached ALC panel 212 can be favorably maintained.

  In addition, since the rod-like body 116 is loosely inserted in the insertion hole 232 and the cylindrical body 248, the rod-like body 116 is communicated with the inside of the insertion hole 232 and this when the building housing 14 undergoes interlayer deformation due to an earthquake. It slides up and down in the cylindrical body 248. Thereby, since the ALC panel 212 can be locked smoothly, the ALC panel 212 is also excellent in follow-up performance with respect to interlayer deformation.

  In addition, in the ALC panel mounting structure 310 of the fourth embodiment, the pedestal portion 118 of the rod-shaped body 116 is a metal flat fixed to the building housing 14 as in the ALC panel mounting structure 110 of the second embodiment. The bar 22 is not directly fixed, but is fixed to the building frame 14 via the mounting bracket 134. Therefore, when the building housing 14 undergoes interlayer deformation, the rod-like body 116 slides in the vertical direction and swings in the horizontal direction within the insertion hole 232 and the cylindrical body 248 of the anchor metal fitting 244 communicated therewith. In the concave portion 142, it can slide smoothly in the horizontal direction between the pedestal portion 118 of the rod-shaped body 116 and the engagement surface portion 136 of the mounting bracket 134. Thereby, the followability with respect to the interlayer deformation of the ALC panel 212 is further improved.

  Further, in the ALC panel mounting structure 310 of the fourth embodiment, the anchor metal fitting 244 is embedded in the ALC panel 212 as in the ALC panel mounting structure 210 of the third embodiment. It is loosely inserted into the hole 256 of the cylindrical body 248 of the anchor fitting 244 via the insertion hole 232. Therefore, the attachment strength at the upper end of the ALC panel 212 is excellent. Accordingly, the present invention can also be applied to an ALC panel 212 for outdoor use that requires a mounting strength that can withstand rain and wind. Also in the ALC panel mounting structure 310 of the fourth embodiment, the main reinforcement 26a is applied to the welded surface portions 250a, 250b of the tubular body of the anchor fitting 244. Thereby, the attachment strength at the upper end of the ALC panel 212 can be further improved.

  Next, the attachment structure of the lower end of the ALC panel will be described.

  As shown in FIG. 12, the mounting structure 510 at the lower end of the ALC panel includes an ALC panel 512 at one location using one lower anchor fitting 544, one lower end fitting 534, and one male screw member (bolt) 558. The lower end of the slab is attached to the floor slab 514.

  The lower end anchor fitting 544 has a structure similar to the structure of the anchor fitting 244 shown in FIG. 9 described in the ALC panel mounting structure 210 of the third embodiment. That is, the lower end anchor fitting 544 includes a tubular body 546 formed in a square tubular shape and a cylindrical body 548 formed in a cylindrical shape. Compared with the anchor fitting 244 shown in FIG. 9, the inner peripheral surface of the cylindrical body 248 of the anchor fitting 244 shown in FIG. A female screw (hole) 556 is formed on the inner peripheral surface of the lower end anchor metal 544, and the cylindrical body 548 of the lower end anchor fitting 544 is different only in having a female screw hole 556. The other configuration of the lower end anchor fitting 544 is the same as that of the anchor fitting 244 shown in FIG.

  As shown in FIG. 12B, the lower end anchor fitting 544 is disposed between a pair of reinforcing bar mats 28 a and 28 b embedded in the ALC panel 512. Also, as shown in FIGS. 12A and 12B, the end of the ALC panel 512 in the length direction, which is near the lower end facet 512b of the ALC panel 512 at the center in the width direction and the center in the thickness direction of the ALC panel 512. One (one) per panel is arranged at the (lower end).

  The welded surface portions 550 a and 550 b of the tubular body 546 of the lower end anchor fitting 544 are arranged in parallel to the wall surface 512 c of the ALC panel 512. Further, the connecting surface portions 552 a and 552 b of the tubular body 546 are arranged in parallel to the lower end fore edge surface 512 b of the ALC panel 512. Both open ends of the tubular body 546 are opened in the width direction of the ALC panel 512.

  The thickness of the lower end anchor fitting 544 is the length in the thickness direction of the ALC panel 512, and corresponds to the distance between the welded surface portions 550a and 550b of the tubular body 546. The welded surface portions 550a and 550b are sub-rebars. It is made into the length matched with the distance between rebar mats so that it may touch 26b, or it may be near to auxiliary muscle 26b to such an extent that it can be welded.

  As shown in FIG. 12A, the welded surface portions 550a and 550b of the tubular body 546 have a width equal to or greater than the distance between the main reinforcing bars 26a of the reinforcing bar mats 28a and 28b. The main muscle 26a of the book is applied. Further, the welded surface portions 550a and 550b of the tubular body 546 have a length equal to or longer than the distance between the secondary reinforcing bars 26b of the reinforcing bar mats 28a and 28b. It depends. One welded surface portion 550a of the tubular body 546 is welded to the two accessory bars 26b of the one reinforcing bar mat 28a, and the other welded surface portion 550b of the tubular body 546 is welded to the two accessory bars 26b of the other reinforcing bar mat 28b. It is welded to. Therefore, the tubular body 546 is welded to the accessory bar 26b of the reinforcing bar mat 28a and is also welded to the accessory bar 26b of the reinforcing bar mat 28b.

  The cylindrical body 548 of the lower end anchor metal fitting 544 is welded to the connecting surface portions 552a and 552b at both ends so as to bridge between the connecting surface portions 552a and 552b of the tubular body 546. The cylindrical body 548 is arranged so that its axial direction is parallel to the length direction of the ALC panel 512.

  A communication hole 532 is formed from the lower end small edge surface 512b of the ALC panel 512 into the ALC panel 512, and the communication hole 532 is a cylindrical body 548 of the lower end anchor fitting 544 embedded in the lower end of the ALC panel 512. It is communicated to. Accordingly, the male screw member 558 can be screwed with the female screw of the cylindrical body 548 through the communication hole 532.

  The lower end mounting bracket 534 has a structure similar to the structure of the mounting bracket 134 shown in FIG. 7 described in the ALC panel mounting structure 110 of the second embodiment. Specifically, the lower end mounting bracket 534 has a mounting portion 536 having a mounting surface on which the ALC panel 512 is mounted, and extends from both ends of the mounting portion 536 and is bent from both ends. And a pair of legs 538. A through hole 540 having an inner diameter large enough to allow insertion of the male screw portion 560 of the male screw member 558 is formed in the center of the mounting portion 536. Further, the distal end 538 a of the leg portion 538 is bent so as to open outward in a direction parallel to the placement portion 536. The lower end mounting bracket 534 can be manufactured, for example, by bending both ends of a metal plate and further drilling in the center of the plate.

  The lower end mounting bracket 534 is configured to have a size that does not protrude from the area of the lower end facet 512b of the ALC panel 512 (contains within that area). For example, as shown in FIG. 12A, when the lower end mounting bracket 534 is arranged along the width direction of the ALC panel 512, the width of the lower end mounting bracket 534 does not exceed the thickness of the ALC panel 512. It is. When the lower end mounting bracket 534 is arranged along the thickness direction of the ALC panel 512, the length of the lower end mounting bracket 534 does not exceed the thickness of the ALC panel 512.

  The male screw portion 560 of the male screw member 558 is inserted into the through hole 540 from the inside of the mounting portion 536 of the lower end mounting bracket 534 to the base end, and further, the female screw in the cylindrical body 548 of the lower end anchor bracket 544 It is screwed. Further, the front ends 538a of the leg portions 538 of the lower end mounting bracket 534 are fixed to a metal plate 522 previously embedded in the floor slab 514 by welding or the like.

  The attachment of the lower end of the ALC panel 512 to the floor slab 514 can be performed as follows, for example. First, at a position communicating with the female screw hole 556 of the cylindrical body 548 of the lower end anchor metal fitting 544 embedded in the ALC panel 512, the ALC panel 512 has a predetermined size and a predetermined depth at the lower end facet 512b. Thus, the communication hole 532 is formed. Next, the male screw portion 560 of the male screw member 558 is inserted into the through hole 540 of the mounting portion 536 from the inside of the mounting portion 536 of the lower end mounting bracket 534. Next, the male screw portion 560 of the male screw member 558 is screwed into the female screw hole 556 of the cylindrical body 548 of the lower end anchor metal fitting 544, and the lower end attachment metal fitting 534 is attached to the lower end small edge surface 512 b of the ALC panel 512. Next, the ALC panel 512 is erected on the floor slab 514 via the lower end mounting bracket 534. Next, the tip 538 a of the leg 538 of the lower end mounting bracket 534 is brought into contact with the metal plate 522 embedded in the floor slab 514 in advance. Next, the front ends 538 a of the leg portions 538 of the lower end mounting bracket 534 are welded to the metal plate 522. Thereafter, a sealing material can be filled in the gap between the lower end of the ALC panel 512 and the floor slab 514 as necessary for the purpose of waterproofing or the like.

  As described above, the lower end of the ALC panel 512 is attached to the floor slab 514 at one place in the center in the width direction of the ALC panel 512. Further, a gap about the size of the lower end fitting 534 is generated between the lower end of the ALC panel 512 and the floor slab 514. Therefore, the attached ALC panel 512 is smoothly locked against the shaking of the building due to an earthquake or the like, and therefore has excellent follow-up performance against interlayer deformation. Thereby, since the shaking of the building due to an earthquake or the like can be absorbed, the ALC panel 512 can be prevented from being destroyed or dropped off due to the earthquake or the like.

  Further, the ALC panel 512 is attached to the floor slab 514 at the lower end facet 512b of the ALC panel 512. The lower end mounting bracket 534 is configured to have a size that does not protrude outside the region of the lower end small edge surface 512b of the ALC panel 512 (contains within the region). Therefore, the attachment portion at the lower end of the ALC panel 512 is difficult to see from the outside. Therefore, there is no possibility that the aesthetic appearance of the attached ALC panel 512 is impaired by the metal fitting for attaching the lower end of the ALC panel 512 to the floor slab 514. In addition, since the metal fitting for attaching the lower end of the ALC panel 512 to the floor slab 514 is not exposed to the outside of the wall surface 512c of the ALC panel 512, this metal fitting is affected by wind and rain even when the ALC panel 512 is attached outdoors. It is hard to receive. Therefore, rust is unlikely to occur in this metal fitting. Thereby, even when used outdoors, the appearance quality of the attached ALC panel 512 can be favorably maintained.

  Furthermore, since the lower end of the ALC panel 512 is attached to the floor slab 514 via a lower end attachment fitting 534 attached to a lower end anchor fitting 544 embedded in the ALC panel 512, Excellent shear pull-out strength. Specifically, the lower end anchor fitting 544 is applied to the two main bars 26a, and a shear pulling strength of 6000 N or more is obtained. Moreover, since this lower end anchor metal fitting 544 is applied to the main reinforcement 26a in the ALC panel 512, it is further excellent in shear pull-out strength.

  Here, the lower end of the ALC panel 512 has a male screw between a lower end anchor bracket 544 embedded in the ALC panel 512 and a lower end mounting bracket 534 fixed to the floor slab 514 at one center in the width direction of the ALC panel 512. Since it is attached to the floor slab 514 by connecting with the member 558, the attached ALC panel 512 is easy to rotate in the horizontal direction (outward direction of the wall surface) only by looking at the attachment structure at the lower end. In contrast to the mounting structure 510 at the lower end of the ALC panel, the upper end of the ALC panel 512 is attached to the building frame 514 at two locations using two rod-shaped bodies 16 as shown in FIG. In the attachment structure 510 at the lower end of the ALC panel, the ALC panel 512 can be prevented from rotating.

  In addition, in FIG. 12, although the thing of 1st embodiment is shown as an attachment structure of the upper end of ALC panel 512, it is not limited to this, From said 2nd embodiment to 4th embodiment. This lower end mounting structure can be applied to any of the mounting structures.

  The ALC panel according to the present invention is suitably used as a wall material for buildings such as outer walls, partition walls, partition walls, and sleeve walls. In particular, it is suitable for an ALC panel used outdoors such as a wall separated from a neighboring door on a veranda in a high-rise building such as an apartment house or a sleeve wall in a passage around the entrance.

  Although the embodiments of the present invention have been described in detail above, the present invention is not limited to the above-described embodiments, and various modifications can be made without departing from the gist of the present invention.

  For example, although two rod-shaped bodies are used in any of the first embodiment to the fourth embodiment, three or more rod-shaped bodies can be used in these. When three or more rod-shaped bodies are used, it is preferable that the same number of insertion holes as the number of the rod-shaped bodies are drilled from the top edge surface of the ALC panel into the ALC panel. Moreover, when using three or more rod-shaped bodies in the third embodiment and the fourth embodiment, the same number of anchor fittings as the number of rod-shaped bodies can be used. Furthermore, when using three or more rod-shaped bodies in the second embodiment and the fourth embodiment, the same number of mounting brackets as the number of rod-shaped bodies can be used.

  Further, for example, in any of the first embodiment to the fourth embodiment, a beam or the like can be used as the building frame. And as a member which fixes the base part of a rod-shaped body, instead of the flat bar fixed to the building frame, the building frame itself may be used, or a horizontal plate arranged in the horizontal direction and the horizontal plate are erected. An L-shaped angle may be provided in which the vertical plate is embedded in the building frame along the vertical direction, and the horizontal plate is arranged along the building frame.

  Further, in any of the first embodiment to the fourth embodiment, instead of the method of attaching the lower end of the ALC panel to a floor slab or the like using the lower end mounting bracket attached to the lower end edge of the ALC panel, for example, An ALC panel is erected on an L-shaped horizontal plate fixed to the floor slab with a flat rocking spacer in between, and one end of the lightning plate is attached to a vertical plate that stands upright from the L-shaped horizontal plate. A method of attaching the lower end of the ALC panel to a floor slab or the like by welding and fixing the other end to the lower end of the wall surface of the ALC panel with a bolt or the like can also be adopted. In this case, since the lightning plate that connects the L-shaped angle fixed to the floor slab and the ALC panel is not attached to the bottom edge of the ALC panel, the ALC panel can be locked. A horizontal rotation of the ALC panel is less likely to occur.

  In any of the first to fourth embodiments, the insertion hole can be formed when the ALC panel is manufactured, or can be formed when the ALC panel is attached after the ALC panel is manufactured. it can. Also, in the mounting structure 510 at the lower end of the ALC panel, the communication hole 532 can be formed at the time of manufacturing the ALC panel, and is formed when the ALC panel is mounted on the floor slab 514 after the ALC panel is manufactured. You can also.

  Furthermore, in said 1st embodiment and 2nd embodiment, the shape of the base part of a rod-shaped body may be a disk shape instead of a square disk shape, and may be a polygonal disk shape other than a square disk shape. good. In the third embodiment and the fourth embodiment, the shape of the pedestal portion of the rod-like body may be a polygonal disk shape such as a square disk shape instead of the disk shape.

  In the second and fourth embodiments using the mounting bracket, instead of the mounting bracket 134 having the shape shown in FIG. 13A, the mounting bracket 634 shown in FIG. 13B or FIG. A mounting bracket 734 shown in c) can also be used.

  A mounting bracket 634 shown in FIG. 13B is extended to both ends of the plate-like engagement surface portion 636 with which the base portion 618 on one end side of the rod-like body 616 is engaged, and the engagement surface portion 636. And a pair of legs 638 bent from both ends. A through hole 640 having an inner diameter large enough to allow insertion of the rod-shaped portion 620 of the rod-shaped body 616 is formed at the center of the engaging surface portion 636. Further, the distal end 638 a of the leg portion 638 is bent so as to close inward in a direction parallel to the engagement surface portion 636. The tips 638a of the legs 638 are butted and joined. As a result, the mounting bracket 634 has a generally rectangular cross section. A recess 642 is formed by the engaging surface portion 636 and the leg portion 638.

  In order to engage the rod-shaped body 616 with the mounting bracket 634, for example, the rod-shaped portion 620 of the rod-shaped body 616 and the base portion 618 of the rod-shaped body 616 are formed as separate members, and a male screw is formed at the base end of the rod-shaped portion 620. It is preferable that a female screw hole is formed in the center of the pedestal portion 618 and the male screw and the female screw are screwed to be integrated with each other. Then, the pedestal portion 618 of the rod-shaped body 616 is disposed in the recess 642, and the base end of the rod-shaped portion 620 of the rod-shaped body 616 is inserted from the outside of the engagement surface portion 636 into the through-hole 640 of the engagement surface portion 636. The rod-shaped body 616 can be engaged with the mounting bracket 634 by screwing the male screw of the rod-shaped portion 620 and the female screw of the pedestal portion 618 inside.

  A mounting bracket 734 shown in FIG. 13 (c) has a plate-like engagement surface portion 736 with which the pedestal portion 118 of the rod-like body 116 is engaged, and extends at both ends of the engagement surface portion 736 and is folded from both ends. And a pair of leg portions 738 formed with a bend. A through hole 740 having an inner diameter large enough to allow insertion of the rod-shaped portion 120 of the rod-shaped body 116 is formed at the center of the engaging surface portion 736. Unlike the mounting bracket 134 having the shape shown in FIG. 13A, the tip end of the leg portion 738 is not bent outward, and the mounting bracket 734 is formed in a U-shaped cross section as a whole. A recess 742 is formed by the engaging surface portion 736 and the pair of leg portions 738.

  Further, in the third embodiment and the fourth embodiment using the anchor fitting, the welded surface portion of the anchor fitting is applied to one main bar, but the welded surface portion is applied to two main bars. good. In this case, the attachment strength at the upper end of the ALC panel can be further increased. Moreover, the welding surface part may be applied to three or more main bars, respectively.

  Further, in the third embodiment and the fourth embodiment using the anchor fitting, instead of the anchor fitting 244 provided with one cylindrical body 248 in the inner space of the tubular body 246, as shown in FIG. An anchor fitting 644 provided with two cylindrical bodies 648 in the internal space of the tubular body 646 may be used. Furthermore, you may use the anchor metal fitting provided with three or more cylindrical bodies in the internal space of a tubular body.

  When the anchor fitting 644 shown in FIG. 14 is used, two anchors 648 are provided for each anchor fitting 644, and therefore, one anchor fitting 644 may be used for two rod-like bodies. At this time, from the viewpoint of improving the shear pulling strength against the building frame at the upper end of the ALC panel 612, the welded surface portion 650 of the anchor fitting 644 is disposed so as to cover at least two main bars 26a as shown in FIG. It is preferable.

  Further, in the third embodiment and the fourth embodiment using the anchor fitting, the anchor fitting of the rod-shaped portion of the rod-shaped body is improved by improving the shape of the rod-shaped portion of the rod-shaped body and the shape of the cylindrical shape of the anchor fitting. You may take measures to prevent it from coming off.

  For example, as shown in FIG. 15, the rod-shaped body 816 is provided with a protrusion 862 at a predetermined position on the outer peripheral surface of the rod-shaped portion 820, and the cylindrical body 848 of the anchor fitting 844 into which the rod-shaped portion 820 is inserted has a rod-shaped body. A notch 864 having a size that allows the protrusion 862 of the bar-shaped portion 820 to pass along the axial direction is provided along the axial direction, and a notch step portion 866 formed by shifting the notch 864 in the circumferential direction in the middle of the shaft. It may be provided.

  In this case, in order to insert the rod-shaped portion 820 of the rod-shaped body 816 into the tubular body 848 of the anchor fitting 844, first, the protrusion 862 of the rod-shaped portion 820 is aligned with the notch 864 of the tubular body 848. Next, the rod-shaped portion 820 is inserted into the interior of the tubular body 848 while sliding the projection 862 of the rod-shaped portion 820 along the cutout portion 864 provided in the axial direction of the tubular body 848. When the protrusion 862 of the rod-shaped portion 820 contacts the notch step portion 866 shifted in the circumferential direction, the rod-shaped body 816 is rotated in the circumferential direction, and the protrusion of the rod-shaped portion 820 along the notch portion 864 provided in the circumferential direction. Slide 862. The projection 862 of the rod-shaped part 820 is slid along the notch part 864 provided in the axial direction again. As a result, the rod-shaped portion 820 of the rod-shaped body 816 is loosely inserted into the tubular body 848 of the anchor fitting 844. In a state where the rod-shaped portion 820 of the rod-shaped body 816 is loosely inserted into the cylindrical body 848 of the anchor metal fitting 844, if a tensile force is generated in the rod-shaped body 816, the protrusion 862 of the rod-shaped portion 820 is caught by the notch step portion 866. Therefore, it is possible to prevent the rod-like body 816 from coming off the anchor fitting 844.

  For example, as shown in FIG. 16, the rod-shaped body 816 is provided with a protrusion 862 at a predetermined position on the outer peripheral surface of the rod-shaped portion 820, and the cylindrical body 948 of the anchor metal fitting 944 into which the rod-shaped portion 820 is inserted has A protrusion 862 of the rod-shaped portion 820 is provided along the axial direction from the insertion port into which the rod-shaped portion 820 is inserted to the diameter-expanded step portion 966 that is provided with a diameter-expanded step portion 966 that expands in the middle portion toward the back in the axial direction. You may provide the notch part 964 of the magnitude | size which can pass.

  In this case, in order to insert the rod-shaped portion 820 of the rod-shaped body 816 into the tubular body 948 of the anchor metal fitting 944, first, the protrusion 862 of the rod-shaped portion 820 is aligned with the notch 964 of the tubular body 948. Next, the rod-shaped portion 820 is inserted into the interior of the tubular body 948 while sliding the protrusion 862 of the rod-shaped portion 820 along the notch 964 provided in the axial direction of the tubular body 948. When the protrusion 862 of the rod-shaped portion 820 reaches the diameter-increasing step portion 966, the protrusion 862 of the rod-shaped portion 820 enters the inside of the diameter-expanded step portion 966 through the notch portion 964, and the restriction by the notch portion 964 is released. At this time, if the rod-shaped body 816 is rotated in the circumferential direction, the position of the notch 964 and the position of the projection 862 are shifted in the circumferential direction, so that the projection 862 of the rod-shaped portion 820 does not have an enlarged step unless these positions are matched again. It is possible to prevent the rod-shaped body 816 from being caught by the portion 966 and coming off from the anchor fitting 944.

  If the combination of the rod-shaped body and the anchor fitting shown in FIGS. 15 and 16 is used, the rod-shaped portion of the rod-shaped body is prevented from coming off from the tubular body of the anchor fitting. Then, even if pressure is applied to the wall of the ALC panel due to an earthquake or the like and the ALC panel may be bent in the middle of the length direction, the upper end of the ALC panel is caught in the building frame, and the ALC panel is still Since it is supported by the upper end and the lower end, the ALC panel can be further prevented from collapsing. Thereby, the secondary disaster by an earthquake etc. can be prevented.

  Moreover, in the said 3rd embodiment and 4th embodiment using an anchor metal fitting, although the tubular body is a square tubular shape, it is not limited to this, The both ends of a cylindrical body are attached to the surrounding surface. As long as it can be supported, it may be a round tube, or an elliptical tube or a rectangular tube other than a square tube. Moreover, the edge part of a cylindrical body may protrude outside the connection surface part or welding surface part of a tubular body.

10, 110, 210, 310 ALC panel mounting structure 12 ALC panel 14 Building housing 16 Rod-shaped body 18 Pedestal portion 20 Rod-shaped portion 32 Insertion hole 134 Mounting bracket 136 Engagement surface portion 138 Leg portion 140 Through-hole 244 Anchor bracket 246 Tubular body 248 Cylindrical body

Claims (12)

An ALC panel mounting structure in which an ALC panel is mounted on a building frame,
The ALC panel is disposed such that an upper end facet of the ALC panel faces the building frame with a space therebetween, and the building case has a pedestal portion having a size that fits within a region of the upper end facet of the ALC panel and the pedestal. A plurality of rod-like bodies each having a rod-like portion standing upright from a portion are directly fixed by welding at a pedestal portion on one end side thereof, and the rod-like portions of the fixed plurality of rod-like bodies are the ALC panel ALC is characterized in that it is loosely inserted into a plurality of insertion holes drilled from the upper end small edge surface of the ALC panel into the ALC panel, and the pedestal portion is within the area of the upper edge small edge surface of the ALC panel. Panel mounting structure. An ALC panel mounting structure in which an ALC panel is mounted on a building frame,
The building housing includes a plurality of rod-like bodies each having a pedestal portion and a rod-like portion erected from the pedestal portion. The engaging surface portion having a through hole having an inner diameter large enough to allow insertion of the rod-shaped portion, and extending to both ends thereof. And a pair of legs bent from both ends of the ALC panel. An attachment metal that fits within the area of the end facet and that has the leg welded and fixed to the building frame The rod-shaped portion is inserted into the through hole of the tool, and the pedestal portion is engaged with the engagement surface portion. The plurality of rod-shaped bodies are indirectly fixed, and the fixed plurality of rod-shaped bodies The rod-shaped portion has a plurality of holes drilled from the top edge of the ALC panel into the ALC panel. An ALC panel mounting structure characterized by being loosely inserted into an insertion hole. And wherein the building base portion of the rod-shaped body fixed metal flat bar precursor is Ri by to be welded directly to the plurality of bar-like member before SL building structures is fixed The ALC panel mounting structure according to claim 1. The legs of the mounting bracket are welded and fixed to a metal flat bar fixed to the building frame. The plurality of rod-shaped bodies are fixed to the building frame. The ALC panel mounting structure according to claim 2. The rod-like body is further made of an upper end anchor metal fitting welded to a reinforcing bar in the ALC panel. The ALC panel according to any one of claims 1 to 4, wherein the ALC panel is loosely inserted into a hole. Mounting structure. An anchor fitting provided with a tubular body and a tubular body disposed in the inner space of the tubular body and supported at both ends of the ALC panel on the peripheral surface of the tubular body is embedded in the ALC panel. are embedded in the tubular body according positioned to have the main reinforcement that is, the rod-shaped body, according to claim 5, characterized in that it is further loosely inserted into the cylindrical body in the pores of the anchor ALC panel mounting structure. The plurality of insertion holes are provided inside the reinforcing reinforcing bars embedded in the ALC panel in the width direction of the ALC panel, according to any one of claims 1 to 6 . ALC panel mounting structure. The insertion length of the ALC panel of the rod-shaped body, from claim 1, wherein longer than the distance from the upper end small surface of the ALC panel to reinforcing rebar is embedded in the ALC panel 7 The ALC panel mounting structure according to any one of the above. The insertion hole, said in the width direction of the ALC panels, mounting structure of ALC panel according to any one of claims 1 to 8, characterized in that it is arranged one by one on both sides of a central position. The ALC panel mounting structure according to any one of claims 1 to 9 , wherein the plurality of insertion holes are arranged at equal positions on both sides of a center position in the width direction of the ALC panel. . The lower end of the ALC panel is sized to fit within the area of the lower end edge surface of the ALC panel, and is fixed to the floor slab via a lower end mounting bracket attached to the center in the width direction and thickness direction of the lower end edge surface The mounting structure for an ALC panel according to any one of claims 1 to 10 , wherein the mounting structure is an ALC panel. The lower end mounting bracket is a lower end anchor bracket welded to a reinforcing bar in the ALC panel. And is attached to the center in the width direction and the thickness direction on the lower end facet. The mounting structure for an ALC panel according to claim 11.

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