JP5825057B2 - Smoke barrier with buffer function - Google Patents

Description

  The present invention relates to a smoke barrier wall that temporarily blocks the flow of smoke generated during a fire or the like.

  Conventional smoke barriers have been constructed by fitting the upper end of a glass plate into a ceiling rail provided on the ceiling and building the glass plate in sequence (see, for example, Patent Document 1). However, such a smoke-proof wall has a glass plate fixed to the building, so if it undergoes in-plane or out-of-plane deformation due to an earthquake or the like, the glass plate cannot withstand these deformations and breaks. There was also a risk that the passerby would fall and be injured.

  Therefore, as described in Patent Document 2, a smoke barrier wall has been devised that uses a non-combustible sheet instead of a glass plate that is easily damaged. This smoke proof wall is obtained by fixing a smoke proof wall panel having a non-combustible sheet attached to a frame body to a ceiling rail disposed on the ceiling surface.

Utility Model Registration No. 3045590 JP 2006-335775 A

  However, after observing the site where the smoke barriers described in Patent Document 2 were constructed, the ceiling rail was bent due to the occurrence of a huge earthquake, the ceiling surface and the wall surface were damaged, and the incombustible sheet was torn Was scattered.

  Therefore, as a result of earnest examination of the mechanism that the ceiling rail bends and the mechanism that damages the ceiling surface, wall surface, non-combustible sheet, etc. (among multiple ceiling rails fixed to the ceiling surface), When a force in the compression direction (hereinafter referred to as “compression force”) is applied, the ceiling rail is pushed and bent by the compression force and deforms while pushing and bending the adjacent ceiling rail. It was found that the ceiling surface, wall surface, non-combustible sheet, etc. would be damaged.

  In such a case, the deformed ceiling rail or the torn non-combustible sheet cannot be reused. For this reason, a new ceiling rail or non-combustible sheet must be recreated to form a smoke-proof hanging wall, and a damaged ceiling surface or wall surface must be repaired.

  Even if a tensile force (hereinafter referred to as “tensile force”) is applied to the ceiling rail arranged on the wall surface side from the wall surface, the ceiling rail and the adjacent ceiling rail are not pushed and bent. Just removing from the surface did not damage the ceiling surface, wall surface, incombustible sheet, etc.

  Accordingly, an object of the present invention is to provide a smoke-proof hanging wall that can be easily repaired without deformation of the ceiling rail due to a large impact such as an earthquake.

  The smoke-proof hanging wall with a buffer function according to the present invention includes a flexible rectangular incombustible sheet, a ceiling rail that extends to the ceiling surface and to which the upper end of the incombustible sheet is attached, and one end side of the ceiling rail. And a support member disposed on the other end side of the ceiling rail and fixed to the ceiling surface so that the ceiling rail can be buffered with respect to the stand and the support member. It is arranged.

  Here, the wall surface means a surface perpendicular to the ceiling surface, and includes a wall surface, a column surface, and the like. “Fixed to the wall surface” means directly fixed to the wall surface or indirectly fixed to the wall surface via an interior material or the like. As a mode which can be buffered with respect to a vertical and a support member, for example, a mode in which a compressive force applied to a ceiling rail from a wall surface is released by rotating a ceiling rail with respect to the vertical and a support member, a vertical and a support Forming a space between the member and the ceiling rail so as not to apply a compressive force from the wall surface to the ceiling rail, or inserting the elastic member filling between the vertical and supporting members and the ceiling rail from the wall surface An aspect in which the compressive force applied to the ceiling rail is reduced. In addition, when forming a space between the stand and the support member and the ceiling rail, from the viewpoint of preventing the passage of smoke, attach a cover that covers the gap between the stand and the support member and the ceiling rail. Is preferred.

  According to the smoke-proof hanging wall with a buffer function according to the present invention, the vertical and supporting members are fixed to the wall surface and the ceiling surface, but the ceiling rail is disposed in a buffered state between the vertical and the supporting members. Therefore, it is possible to prevent the ceiling rail from being deformed even by a large impact such as an earthquake. As a result, even if an earthquake occurs, the ceiling rail can be reused, and the ceiling surface and wall surface can be prevented from being damaged by the ceiling rail that has been pushed and bent as before, so that it can be easily restored. be able to.

  Further, in the present invention, the ceiling rail is formed with a through-hole penetrating in the vertical direction, and is rotatably held by a holding member fixed to the ceiling surface and inserted into the through-hole, and at least one of the ceiling rails The end surface of the ceiling rail is formed in an inclined surface directed to the side of the ceiling rail, and a space in the extending direction of the ceiling rail is formed between the through hole and the holding member. it can.

  In this way, the ceiling rail is rotatably held by the holding member, and by forming an inclined surface on at least one end surface of the ceiling rail, a part of the compressive force applied from the wall surface to the ceiling rail holds the ceiling rail. Since it is converted into a force that rotates around the axis of the member, the ceiling rail can be rotated around the axis of the holding member when a compressive force is applied from the wall surface to the ceiling rail. In addition, since the space formed between the through hole and the holding member allows movement in the direction in which the compression force of the ceiling rail is applied to the ceiling surface, rotation of the ceiling rail can be easily started. Thereby, since the compressive force applied to a ceiling rail is escaped appropriately, a deformation | transformation of a ceiling rail can be prevented. In this case, the end portion of the ceiling rail formed on the inclined surface has a pointed shape, but by forming only the end surface on the support member side of the ceiling rail on the inclined surface, the sharp end portion is It is possible to prevent the wall surface from being damaged by colliding with the wall surface.

  In the present invention, the supporting member side end surface of the opposing ceiling rail and the ceiling rail side end surface of the supporting member may be formed on inclined surfaces directed in opposite directions. In this manner, the opposing support member side end surface and the ceiling rail side end surface are formed in inclined surfaces directed in opposite directions, so that the ceiling rail can be more easily applied when a compressive force is applied from the wall surface to the ceiling rail. It can be rotated smoothly.

  Further, in the present invention, the support member may be an adjacent ceiling rail to which the upper end portion of the non-combustible sheet is attached adjacent to the ceiling rail. By comprising in this way, a support member can be manufactured easily. In this case, the upper end portion of the incombustible sheet can be attached across the ceiling rail and the adjacent ceiling rail. In addition, an intermediate stand extending downward from the adjacent ceiling rail in the vertical direction can be attached to the lower portion of the adjacent ceiling rail.

  In the present invention, the support member may be an intermediate stand disposed between the ceiling rail and the adjacent ceiling rail to which the upper end portion of the adjacent non-combustible sheet adjacent to the non-combustible sheet is attached. By configuring in this way, the edge between the ceiling rail arranged on the vertical side and the other ceiling rail can be cut, so that the compressive force applied to the ceiling rail from the wall surface is transmitted to the other ceiling rail. Can be prevented.

  In the present invention, at least one of the ceiling rail and the support member may be provided with a lid portion that covers the gap between the ceiling rail and the support member. With this configuration, smoke can be prevented from passing through the gap between the ceiling rail and the support member.

  In the present invention, the non-combustible sheet can be attached to the ceiling rail and the stand so as to be separable. Thus, by attaching the incombustible sheet so as to be separable from the ceiling rail and the vertical, it is possible to prevent the incombustible sheet from tearing when the ceiling rail rotates.

  According to the present invention, the ceiling rail can be easily repaired without being deformed by a large impact such as an earthquake.

It is a top view which shows the smoke-proof hanging wall with a buffer function which concerns on 1st Embodiment. It is a bottom view which shows the smoke-proof hanging wall with a buffer function which concerns on 1st Embodiment. It is a figure which shows the ceiling rail for fixation, (a) is a bottom view, (b) is the side view seen from the arrow b direction shown to (a). It is a figure which shows the ceiling rail for rotation, (a) is a bottom view, (b) is the side view seen from the arrow b direction shown to (a). It is a figure which shows operation | movement of the smoke barrier with a buffer function which concerns on 1st Embodiment. It is a top view which shows the smoke-proof hanging wall with a buffer function which concerns on 2nd Embodiment. It is a bottom view which shows the smoke-proof hanging wall with a buffer function which concerns on 2nd Embodiment. It is a figure which shows operation | movement of the smoke-proof hanging wall with a buffer function which concerns on 2nd Embodiment. It is a bottom view which shows the other smoke-proof hanging wall with a buffer function which concerns on embodiment.

  Hereinafter, with reference to drawings, the suitable embodiment of the smoke-proof hanging wall with a buffer function concerning the present invention is described in detail. In all the drawings, the same or corresponding parts are denoted by the same reference numerals, and redundant description is omitted.

[First Embodiment]
FIG. 1 is a plan view showing a smoke-proof hanging wall with a buffer function according to the first embodiment, and FIG. 2 is a bottom view showing the smoke-proof hanging wall with a buffer function according to the first embodiment. As shown in FIGS. 1 and 2, the smoke-proof hanging wall 1 with a buffer function according to this embodiment is fixed to a vertical wall 2 fixed to one wall surface W1 and the other wall surface W2 facing the wall surface W1. A vertical wall 3, a fixed ceiling rail 4 that extends from the vertical wall 2 toward the vertical wall 3, and a vertical wall 3 that extends from the vertical wall 3 to the vertical wall 2. A rotating ceiling rail 5 extending toward the surface, and a non-combustible sheet 6 suspended from the fixing ceiling rail 4 and the rotating ceiling rail 5 are provided.

  3A and 3B are diagrams showing a fixing ceiling rail, where FIG. 3A is a bottom view, and FIG. 3B is a side view as seen from the direction of an arrow b shown in FIG. In FIG. 3B, the ceiling surface C is illustrated for easy understanding of the vertical direction of the fixing ceiling rail. As shown in FIGS. 1 to 3, the fixing ceiling rail 4 is a long rail material made of a metal such as nonflammable aluminum or stainless steel, and is formed of a mold material having substantially the same cross section over the entire length. Has been. The fixed ceiling rail 4 is formed in a U-shaped cross section that opens downward in the vertical direction, and is directed downward in the vertical direction from the ceiling portion 4a that is in contact with the ceiling surface C and from both edges of the ceiling portion 4a. And a pair of side wall portions 4b and 4c.

  The ceiling portion 4a is formed with a plurality of round holes 4d penetrating in the vertical direction. The round hole 4d is a hole into which the screw material 7 to be screwed into the ceiling surface C is inserted. The fixing ceiling rail 4 is held on the ceiling surface C by screwing the screw material 7 inserted into each round hole 4d into the ceiling surface C.

  One end face 4 e on the vertical 2 side of the fixing ceiling rail 4 is in contact with the vertical 2. The one end face 4e is formed in a shape corresponding to the contact surface of the vertical 2 in order to increase the contact area with the vertical 2 and prevent smoke from leaking between the vertical 2 and the vertical 2. Preferably it is.

  The other end surface 4f of the fixing ceiling rail 4 on the rotating ceiling rail 5 side (the vertical 3 side) is formed as an inclined surface directed toward the side of the fixing ceiling rail 4 on the side wall 4b side. That is, the other end surface 4f is directed to the side of the side wall 4b side of the fixing ceiling rail 4 that is orthogonal to the extending direction of the fixing ceiling rail 4 in the horizontal direction (vertical direction in FIG. 3A). It is formed on the inclined surface.

  The side wall 4b is notched on the rotating ceiling rail 5 side by a predetermined length, and is retracted from the other end face 4f to the vertical 2 side. For this reason, the other end face 4f is formed only by the ceiling part 4a and the side wall part 4c.

  4A and 4B are diagrams showing the rotating ceiling rail, in which FIG. 4A is a bottom view, and FIG. 4B is a side view seen from the direction of the arrow b shown in FIG. In FIG. 4B, the ceiling surface C is illustrated for easy understanding of the vertical direction of the rotating ceiling rail. As shown in FIGS. 1, 2, and 4, the rotating ceiling rail 5 is a long rail material made of a metal such as non-combustible aluminum or stainless steel, and is a fixed ceiling rail over the entire length. 4 is formed of a mold material having substantially the same cross section as that of No. 4. The rotating ceiling rail 5 is formed in a U-shaped cross section that is open downward in the vertical direction, and is directed downward in the vertical direction from the ceiling portion 5a that is in contact with the ceiling surface C and from both edges of the ceiling portion 5a. And a pair of side wall portions 5b and 5c.

  A long hole 5d penetrating in the vertical direction is formed in one place on the ceiling 5a. The long hole 5d is a hole into which the screw material 8 to be screwed into the ceiling surface C is inserted. Then, the screw material 8 inserted into one long hole 5d is screwed into the ceiling surface C, so that the rotating ceiling rail 5 is held rotatably around the axis of the screw material 8 with respect to the ceiling surface C. Is done. Further, the long hole 5 d is formed long in the extending direction of the rotating ceiling rail 5, and a space in the extending direction of the rotating ceiling rail 5 is formed between the elongated hole 5 d and the screw material 8. For this reason, the rotation ceiling rail 5 is slidable in the extending direction of the rotation ceiling rail 5 with respect to the screw material 8.

  One end face 5 e on the vertical 3 side of the rotating ceiling rail 5 is in contact with the vertical 3. The one end surface 5e is formed in a shape corresponding to the abutment surface of the vertical 3 in order to increase the contact area with the vertical 3 and prevent smoke from leaking from the vertical 3. Preferably it is.

  The other end surface 5f on the fixed ceiling rail 4 side (the vertical 2 side) of the rotating ceiling rail 5 is formed as an inclined surface directed to the side of the rotating ceiling rail 5 on the side wall 5c side. That is, the other end face 5f is directed to the side of the side wall 5c side of the rotating ceiling rail 5 that is orthogonal to the extending direction of the rotating ceiling rail 5 in the horizontal direction (vertical direction in FIG. 4A). It is formed on the inclined surface.

  The other end face 4f and the other end face 5f are in contact with each other, and the fixing ceiling rail 4 and the rotating ceiling rail 5 are arranged in the same straight line.

  The inclination angle of the other end surface 4f with respect to the extending direction of the fixing ceiling rail 4 and the other end surface 5f with respect to the extending direction of the rotating ceiling rail 5 is not particularly limited, but is preferably 30 ° or more and 60 ° or less, 35 ° to 55 ° is more preferable, and 40 ° to 50 ° is particularly preferable. If this inclination angle is smaller than 30 °, the frictional force generated between the other end face 4f and the other end face 5f when the compressive force is applied from the vertical 3 to the rotating ceiling rail 5 becomes too large. There is a high possibility that the rotating ceiling rail 5 will not rotate. On the other hand, if the inclination angle is larger than 60 °, the tip becomes too sharp, and the handleability of the fixed ceiling rail 4 and the rotating ceiling rail 5 decreases. Therefore, by setting the inclination angle within the above range, the rotation ceiling rail 5 can be smoothly rotated while suppressing the handling of the fixing ceiling rail 4 and the rotation ceiling rail 5 from being deteriorated. In order to increase the contact area between the other end face 4f and the other end face 5f and prevent smoke from leaking between the other end face 4f and the other end face 5f, the inclination angles of the other end face 4f and the other end face 5f are: It is preferable that they are the same.

  The rotating ceiling rail 5 is formed with a lid portion 5g that covers a gap between the other end surface 4f and the other end surface 5f. That is, the side wall part 5b protrudes from the other end face 5f to the fixing ceiling rail 4 side by a predetermined length on the fixing ceiling rail 4 side, and the side wall part 5b protruding from the other end face 5f to the fixing ceiling rail 4 side. The projecting portion of this becomes the lid portion 5g.

  The length of the lid 5g is the same as the dimension in which the side wall 5b of the fixing ceiling rail 4 is cut out. For this reason, when the other end surface 4f and the other end surface 5f are brought into contact with each other and the fixing ceiling rail 4 and the rotating ceiling rail 5 are arranged in the same straight line, the lid portion 5g is cut away from the side wall portion 5b. The front end of the lid part 5g contacts the side wall part 5b, and the side surface of the lid part 5g on the side wall part 5c side contacts the ceiling part 4a. Thereby, the clearance gap between the other end surface 4f and the other end surface 5f is covered with the cover part 5g.

  The incombustible sheet 6 is formed in a rectangular sheet shape from a material having incombustibility and flexibility.

  The upper end portion of the incombustible sheet 6 is separably attached to the fixing ceiling rail 4 and the rotating ceiling rail 5.

  The attachment position of the non-combustible sheet 6 with respect to the fixed ceiling rail 4 and the rotating ceiling rail 5 is not particularly limited, but in this embodiment, the side wall 4b and the side wall facing the side wall 4c and the side wall 5c. It is attached to the inner surface of 5b.

  The incombustible sheet 6 can be attached to the fixed ceiling rail 4 and the rotating ceiling rail 5 as long as the incombustible sheet 6 can be detachably attached to the fixing ceiling rail 4 and the rotating ceiling rail 5. Also good. For example, a mode in which the non-combustible sheet 6 is held with respect to the fixing ceiling rail 4 and the rotating ceiling rail 5 using magnets or magic tape (registered trademark), or the fixing ceiling rail 4 and the rotating ceiling rail 5 are formed. For example, the incombustible sheet 6 is inserted into the recessed portion and the incombustible sheet 6 is locked with an elastic body such as a leaf spring. In this case, the attachment of the incombustible sheet 6 to the fixing ceiling rail 4 and the rotating ceiling rail 5 does not necessarily need to be separable over the entire fixing ceiling rail 4 and rotating ceiling rail 5. Depending on the mounting position of the non-combustible sheet 6 with respect to the fixed ceiling rail 4 and the rotating ceiling rail 5, the inclination direction of the other end surface 4f and the other end surface 5f, etc., but at least the rotating ceiling rail 5 side of the fixing ceiling rail 4 It is only necessary that the vicinity of the end portion or the vicinity of the end portion on the fixed ceiling rail 4 side of the rotating ceiling rail 5 can be separated.

  Both end portions of the incombustible sheet 6 are separably attached to the vertical 2 and the vertical 3. The nonflammable sheet 6 is attached to the vertical 2 and the vertical 3 in the same manner as the nonflammable sheet 6 is attached to the fixed ceiling rail 4 and the rotating ceiling rail 5. Any mode may be adopted as long as 6 can be separably attached. In this case, the attachment of the incombustible sheet 6 to the vertical 2 and the vertical 3 does not necessarily need to be separable over the entire vertical 2 and vertical 3. It is sufficient that at least the vicinity of the upper end portion of the rotating ceiling rail 5 is separable.

  As the non-combustible sheet 6, for example, a glass fiber reinforced sheet is used. This glass fiber reinforced sheet is composed of a glass fiber fabric and a resin coating layer obtained by impregnating and curing the glass fiber fabric with a resin. Examples of the woven structure of the glass fiber woven fabric include plain weave, satin weave, twill weave, oblique weave, and woven weave. Examples of the resin constituting the resin coating layer constituting the glass fiber reinforced sheet include vinyl ester resins, unsaturated polyester resins, and phenol resins. In addition, it is preferable that additives, such as a flame retardant, a ultraviolet absorber, a filler, an antistatic agent, are included in the said resin as a resin coating layer.

Moreover, in order to improve a nonflammability and rigidity, it is preferable that a glass fiber reinforced resin sheet is the following. That is, the count of the glass fiber yarn constituting the glass fiber fabric is preferably 5 to 70 tex, more preferably 10 to 35 tex. Moreover, 1-20 micrometers is preferable and, as for the diameter of the filament (glass fiber) contained in a glass fiber thread | yarn, 3-12 micrometers is still more preferable. The mass of the glass fiber fabric per unit area is preferably from 10 to 300 g / ^{m 2,} more preferably 20 to 300 g / ^{m 2.} Moreover, as for the mass of the resin coating layer per unit area, 10-500 g / m < ² > is preferable. The glass fiber fabric is preferably surface-treated with a glass fiber treating agent.

  Next, with reference to FIG. 5, operation | movement of the smoke-proof hanging wall 1 with a buffer function when compression force is applied to the ceiling rail 5 for rotation from the wall surface W2 by big impacts, such as an earthquake, is demonstrated. FIG. 5 is a diagram illustrating an operation of the smoke proof wall with a buffer function according to the first embodiment.

  As shown in FIG. 5A, in a normal state, the fixing ceiling rail 4 and the rotating ceiling rail 5 are arranged in a straight line, and the other end face 4f and the other end face 5f are in close contact with each other. At this time, the upper end portion of the incombustible sheet 6 is attached to the fixing ceiling rail 4 and the rotating ceiling rail 5, and both end portions of the incombustible sheet 6 are attached to the vertical 2 and the vertical 3. Further, a gap between the other end surface 4f and the other end surface 5f is covered with a lid portion 5g.

  As shown in FIG. 5B, when the wall surface W2 moves to the rotating ceiling rail 5 side due to a large impact such as an earthquake, a compressive force is applied to the rotating ceiling rail 5 from the wall surface W2. Then, due to the inclined surfaces of the other end surface 4f and the other end surface 5f, a part of the compressive force applied from the wall surface W2 to the rotating ceiling rail 5 is converted into a force for rotating the rotating ceiling rail 5 around the axis of the screw material 8. In addition, since the long hole 5d allows the rotation of the rotation ceiling rail 5 to the fixing ceiling rail 4 side, the rotation ceiling rail 5 is screwed while sliding toward the fixing ceiling rail 4 side. It starts to rotate around the axis of the material 8.

  Then, the end of the vertical ceiling 3 on the rotating ceiling rail 5 moves toward the side wall 5c, so that the non-combustible sheet 6 is pulled toward the side wall 5c of the rotating ceiling rail 5 on the upper end side of the vertical 3 Therefore, the incombustible sheet 6 is separated from the vicinity of the upper end portion of the vertical 3. Further, the end of the rotating ceiling rail 5 on the fixed ceiling rail 4 side moves to the side wall 5b side, so that the non-combustible sheet 6 is rotated on the fixing ceiling rail 4 side of the rotating ceiling rail 5. Therefore, the incombustible sheet 6 is separated from the vicinity of the end of the rotating ceiling rail 5 on the fixing ceiling rail 4 side. Thereby, the rotation ceiling rail 5 rotates without the noncombustible sheet 6 being torn, and the compressive force applied to the rotation ceiling rail 5 from the wall surface W2 is released.

  Moreover, since the side wall part 4b arrange | positioned in the direction which the edge part by the side of the ceiling rail 4 for fixation in the ceiling rail 5 for rotation moves moves, the front end by the side of the ceiling rail 5 for rotation is notched, A nonflammable sheet The maximum rotation angle of the rotating ceiling rail 5 that allows the rotating ceiling rail 5 to rotate without tearing 6 increases.

  As shown in FIG. 5C, even if the amount of movement of the wall surface W2 toward the rotating ceiling rail 5 increases, the amount of separation of the non-combustible sheet 6 from the vertical 3 and the rotating ceiling rail 5 increases. The rotating ceiling rail 5 rotates without the noncombustible sheet 6 being torn, and the compressive force applied to the rotating ceiling rail 5 from the wall surface W2 is released.

  Thus, according to the smoke-proof hanging wall 1 with a buffer function according to the present embodiment, when a compressive force is applied from the wall surface W2 to the rotating ceiling rail 5, the rotating ceiling rail 5 is moved around the axis of the screw member 8. Furthermore, since the movement of the rotating ceiling rail 5 toward the fixed ceiling rail 4 with respect to the ceiling surface C is allowed by the long hole 5d, the rotation of the rotating ceiling rail 5 can be easily started. Thereby, since the compressive force applied to the ceiling rail 5 for rotation is released appropriately, the deformation | transformation of the ceiling rail 5 for rotation and the ceiling rail 4 for fixation can be prevented.

  Moreover, by forming the inclined surface on the other end surface 5f opposite to the vertical 2 and the vertical 3, it is possible to prevent the wall surface W2 from being damaged.

  In addition, the other end face 4f and the other end face 5f are formed in inclined surfaces directed in opposite directions, and when the compressive force is applied from the wall surface W2 to the rotating ceiling rail 5, the rotating ceiling rail 5 is made smoother. Can be rotated.

  In addition, the non-combustible sheet 6 is separably attached to the vertical 2, vertical 3, fixed ceiling rail 4 and rotating ceiling rail 5 so that the non-combustible sheet 6 is rotated when the rotating ceiling rail 5 rotates. It is possible to prevent tearing.

[Second Embodiment]
FIG. 6 is a plan view showing a smoke-proof hanging wall with a buffer function according to the second embodiment, and FIG. 7 is a bottom view showing the smoke-proof hanging wall with a buffer function according to the second embodiment. As shown in FIGS. 6 and 7, the smoke-proof hanging wall 11 with a buffer function according to the present embodiment is fixed to a vertical wall 2 fixed to one wall surface W1 and the other wall surface W2 facing the wall surface W1. The vertical stand 3, the intermediate stand 12 disposed between the stand 2 and the stand 3 and fixed to the ceiling surface C, and the vertical stand 2 and the intermediate stand 12 disposed on the ceiling C Hanging on the fixed ceiling rail 13 extending between, the rotating ceiling rail 14 disposed on the ceiling surface C and extending between the intermediate vertical 12 and the vertical 3, and the fixed ceiling rail 4 A non-combustible sheet 6a, and a non-combustible sheet 6b that is suspended from the rotating ceiling rail 5 and is adjacent to the non-combustible sheet 6a.

  The fixing ceiling rail 13 is basically formed in the same manner as the fixing ceiling rail 4 of the smoke-proof hanging wall 1 with a buffer function according to the first embodiment. That is, the fixing ceiling rail 13 includes a ceiling portion 13a that is in contact with the ceiling surface C, and a pair of side wall portions 13b and side wall portions 13c that extend downward from both ends of the ceiling portion 13a in the vertical direction. The ceiling portion 13a is formed with a plurality of round holes into which the screw material 7 is inserted.

  The one end surface 13e on the vertical 2 side of the fixing ceiling rail 13 is in contact with the vertical 2, and the other end surface 13f on the intermediate vertical 12 side of the fixing ceiling rail 13 is on the intermediate vertical 12. It is in contact. The one end face 13e and the other end face 13f increase the contact area with the vertical 2 and the intermediate vertical 12 to prevent smoke from leaking between the vertical 2 and the intermediate vertical 12. It is preferably formed in a shape corresponding to the abutment surface of the upright 2 and the intermediate vertical 12.

  The rotating ceiling rail 14 is basically formed in the same manner as the rotating ceiling rail 5 of the smoke-proof hanging wall 1 with a buffer function according to the first embodiment. That is, the rotation ceiling rail 14 includes a ceiling portion 14a that is in contact with the ceiling surface C, and a pair of side wall portions 14b and 14c that extend downward from both ends of the ceiling portion 14a in the vertical direction. In addition, an elongated hole 14d into which the screw material 8 is inserted is formed in one place on the ceiling portion 14a. The elongated hole 14 d is formed long in the extending direction of the rotating ceiling rail 14, and a space in the extending direction of the rotating ceiling rail 14 is formed between the elongated hole 14 d and the screw member 8.

  One end face 14 e on the vertical 3 side of the rotating ceiling rail 14 is in contact with the vertical 3. The one end face 14e is formed in a shape corresponding to the contact surface of the vertical 3 in order to increase the contact area with the vertical 3 and prevent smoke from leaking from the vertical 3 Preferably it is.

  The other end surface 14f on the intermediate vertical 12 side of the rotating ceiling rail 14 is formed as an inclined surface directed to the side of the rotating ceiling rail 14 on the side wall portion 14c side. That is, the other end surface 14f is an inclined surface directed to the side of the side wall 14c side of the rotating ceiling rail 14 that is orthogonal to the extending direction of the rotating ceiling rail 14 in the horizontal direction (vertical direction in FIG. 7). Is formed.

  The intermediate stand 12 is disposed between the fixing ceiling rail 13 and the rotating ceiling rail 14 so as to separate the fixing ceiling rail 13 and the rotating ceiling rail 14, and is fixed to the ceiling surface C. Yes.

  One end face 12 a on the fixing ceiling rail 13 side (the vertical 2 side) of the intermediate stand 12 is formed in a plane perpendicular to the extending direction of the fixing ceiling rail 13. On the other hand, the other end surface 12b of the intermediate vertical 12 on the side of the rotating ceiling rail 14 (the side of the vertical 3) is formed as an inclined surface directed to the side of the side wall 14b of the rotating ceiling rail 14. That is, the other end surface 12b is an inclined surface directed to the side on the side of the side wall portion 14b of the rotating ceiling rail 14 that is orthogonal to the extending direction of the rotating ceiling rail 14 in the horizontal direction (vertical direction in FIG. 7). Is formed.

  The other end face 12b and the other end face 14f are brought into contact with each other, and the fixing ceiling rail 13, the intermediate stand 12 and the rotating ceiling rail 14 are arranged in the same straight line.

  Although the inclination angle of the other end surface 12b and the other end surface 14f with respect to the extending direction of the rotating ceiling rail 14 is not particularly limited, it is preferably 30 ° or more and 60 ° or less, as in the first embodiment, and 35 More preferably, the angle is from 50 ° to 55 °, and particularly preferably from 40 ° to 50 °. In order to increase the contact area between the other end surface 12b and the other end surface 14f and prevent smoke from leaking between the other end surface 12b and the other end surface 14f, the inclination angles of the other end surface 12b and the other end surface 14f are: It is preferable that they are the same.

  The non-combustible sheet 6a and the non-combustible sheet 6b are formed in a rectangular sheet shape by a material having non-combustibility and flexibility, similarly to the non-combustible sheet 6 of the smoke proof wall 1 with a buffer function according to the first embodiment. Yes.

  The upper end portion of the incombustible sheet 6 a is attached to the fixing ceiling rail 13, and both end portions of the incombustible sheet 6 a are attached to the vertical 2 and the intermediate vertical 12.

  The upper end portion of the incombustible sheet 6b is separably attached to the rotating ceiling rail 14, and both side end portions of the incombustible sheet 6b are separably attached to the intermediate stand 12 and the stand 3. The attachment of the non-combustible sheet 6b to the rotating ceiling rail 14, the intermediate vertical 12 and the vertical 3 need not necessarily be separable over the entire rotating ceiling rail 14, the intermediate vertical 12 and the vertical 3. No. It suffices that at least the vicinity of both ends of the ceiling rail 14 for rotation, the vicinity of the upper end of the intermediate stand 12, and the vicinity of the upper end of the stand 3 can be separated.

  The attachment positions of the non-combustible sheet 6a and the non-combustible sheet 6b with respect to the fixing ceiling rail 13 and the rotating ceiling rail 14 are not particularly limited, but in the present embodiment, the positions are opposite to the side wall 13b and the side wall 13b. The side wall part 13c and the outer surface of the side wall part 13c are attached.

  Next, with reference to FIG. 8, the operation of the smoke proof wall 11 with a buffer function when a compressive force is applied from the wall surface W2 to the rotating ceiling rail 14 due to a large impact such as an earthquake will be described. FIG. 8 is a diagram illustrating the operation of the smoke proof wall with a buffer function according to the second embodiment.

  As shown in FIG. 8A, in a normal state, the fixing ceiling rail 13, the intermediate stand 12 and the rotating ceiling rail 14 are arranged in a straight line, and the other end face 12b and the other end face 14f are in close contact with each other. Yes. At this time, the upper end portion of the incombustible sheet 6 b is attached to the ceiling rail 14 for rotation, and both end portions of the incombustible sheet 6 b are attached to the intermediate stand 12 and the stand 3.

  As shown in FIG. 8B, when the wall surface W2 moves to the rotating ceiling rail 14 side due to a large impact such as an earthquake, a compressive force is applied from the wall surface W2 to the rotating ceiling rail 14. Then, due to the inclined surfaces of the other end surface 12b and the other end surface 14f, a part of the compressive force applied from the wall surface W2 to the rotating ceiling rail 14 is converted into a force for rotating the rotating ceiling rail 14 around the axis of the screw material 8. In addition, since the movement of the rotating ceiling rail 14 toward the intermediate vertical 12 side is permitted by the long hole 14d, the rotating ceiling rail 14 slides toward the intermediate vertical 12 side, and the screw material 8 Begin to rotate around the axis.

  Then, the end portion on the vertical 3 side of the rotating ceiling rail 14 moves to the side wall portion 14 c, whereby the noncombustible sheet 6 b is pulled to the side wall portion 14 c side of the rotating ceiling rail 14 at the upper end portion of the vertical 3. Therefore, the non-combustible sheet 6b is separated from the vertical 3. Further, the end of the rotating ceiling rail 14 on the side of the intermediate vertical 12 moves to the side wall portion 14 b, so that the non-combustible sheet 6 b becomes the side wall of the rotating ceiling rail 14 on the intermediate vertical 12 side of the rotating ceiling rail 14. Since it is pulled to the part 14 b side, the non-combustible sheet 6 is separated from the vicinity of the end of the rotating ceiling rail 14 on the intermediate vertical 12 side. Thereby, the rotation ceiling rail 14 rotates without the noncombustible sheet 6b being torn, and the compressive force applied to the rotation ceiling rail 14 from the wall surface W2 is released.

  In addition, since the non-combustible sheet 6b is attached to the outer surface of the side wall 13c and the side wall 13c on the opposite side to the direction in which the end on the intermediate vertical 12 side of the rotating ceiling rail 14 moves, By separating the incombustible sheet 6 from the rotating ceiling rail 14, the rotating ceiling rail 5 can be rotated without tearing the incombustible sheet 6.

  As shown in FIG. 8C, even when the amount of movement of the wall surface W2 toward the rotating ceiling rail 14 increases, the amount of separation of the non-combustible sheet 6 from the vertical 3 and the rotating ceiling rail 5 increases. The rotating ceiling rail 5 rotates without the noncombustible sheet 6 being torn, and the compressive force applied to the rotating ceiling rail 14 from the wall surface W2 is released.

  As described above, according to the smoke proof wall 11 with the buffer function according to the present embodiment, in addition to the effect of the smoke proof wall 1 with the buffer function according to the first embodiment, the intermediate vertical 12 can be used for rotation. Since the edge of the ceiling rail 14 and the fixing ceiling rail 13 can be cut, it is possible to prevent the compressive force applied to the rotating ceiling rail 14 from the wall surface W2 from being transmitted to the fixing ceiling rail 13.

  The preferred embodiment of the present invention has been described above, but the present invention is not limited to the above embodiment.

  For example, in the first embodiment, the description has been given on the assumption that the lid 5g is provided on the rotating ceiling rail 5. However, like the smoke-proof hanging wall 21 with a buffer function shown in FIG. It is good also as what provides the cover part 22g. In this case, it is preferable that the other end surface 22f of the fixed ceiling rail 22 and the other end surface 23f of the rotating ceiling rail 23 are inclined surfaces facing in a direction opposite to the lid portion 22g. Further, when the non-combustible sheet is attached to the inside of the pair of side walls of the fixing ceiling rail 22 and the rotating ceiling rail 23, a lid 22g is provided to increase the maximum rotation angle of the rotating ceiling rail 23. It is preferable to attach to the inner side of the side wall portion.

  Moreover, in the said embodiment, although demonstrated as what makes the end surface on the opposite side to the wall surface in the ceiling rail for rotation as an inclined surface, it is for rotation like the smoke-proof hanging wall 21 with a buffer function shown in FIG.9 (b). The end surface 33a on the wall surface side of the ceiling rail 33 may be an inclined surface. In this case, it is preferable that the contact surface 32a of the vertical 32 that contacts the end surface 33a is also an inclined surface opposite to the end surface 33a.

  In the first embodiment, both the other end surface 4f and the other end surface 5f are formed on an inclined surface. In the second embodiment, both the other end surface 12b and the other end surface 14f are formed on an inclined surface. However, only one of the other end surface 4f and the other end surface 5f may be an inclined surface, and only one of the other end surface 12b and the other end surface 14f may be an inclined surface.

  Moreover, although the said embodiment demonstrated as what employ | adopts the ceiling rail 4 for fixation, and the intermediate stand 12 as a supporting member, it is good also as what uses the stand 2 fixed to the wall surface W1, for example.

  Moreover, although the vertical 2 and the vertical 3 were demonstrated as what is fixed to a wall surface in the said embodiment, it is good also as what is fixed to a wall surface and a ceiling surface.

  DESCRIPTION OF SYMBOLS 1 ... Smoke-proof wall with buffer function, 2 ... Standing, 3 ... Standing, 4 ... Fixed ceiling rail (support member, adjacent ceiling rail), 4a ... Ceiling part, 4b ... Side wall part, 4c ... Side wall part, 4d ... round hole, 4e ... one end face, 4f ... other end face, 5 ... rotating ceiling rail (ceiling rail), 5a ... ceiling part, 5b ... side wall part, 5c ... side wall part, 5d ... long hole (through hole), 5e: One end face, 5f: The other end face, 5g: Lid, 6 ... Non-combustible sheet, 6a ... Non-combustible sheet, 7 ... Non-combustible sheet, 7 ... Screw material, 8 ... Screw material (holding member), 11 ... Anti-buffering function Smoke wall, 12 ... middle upright (support member), 12a ... one end face, 12b ... the other end face, 13 ... fixing ceiling rail, 13a ... ceiling part, 13b ... side wall part, 13c ... side wall part, 13e ... one end face , 13f ... the other end face, 14 ... a ceiling rail for rotation, 14a ... a ceiling part, 14b ... a side wall part, 4c ... side wall part, 14d ... elongate hole, 14e ... one end face, 14f ... other end face, 21 ... smoke-proof hanging wall with buffer function, 22 ... ceiling rail for fixing, 22f ... other end face, 22g ... lid part, 23 ... rotation Ceiling rail, 23f ... the other end surface, 32 ... vertical, 32a ... abutment surface, 33 ... rotating ceiling rail, 33a ... end surface, C ... ceiling surface, W1 ... wall surface, W2 ... wall surface.

Claims (6)

A rectangular incombustible sheet having flexibility;
A ceiling rail that extends to the ceiling surface and to which the upper end of the incombustible sheet is attached;
A stand arranged on one end of the ceiling rail and fixed to the wall;
A support member disposed on the other end side of the ceiling rail and fixed to the ceiling surface;
Have
The ceiling rail is disposed so as to be able to cushion the stand and the support member ,
The ceiling rail is formed with a through-hole penetrating in the vertical direction, and is rotatably held by a holding member fixed to the ceiling surface and inserted into the through-hole.
At least one end surface of the ceiling rail is formed in an inclined surface directed to the side of the ceiling rail,
Wherein between the through hole and the holding member, that have a space is formed in the extending direction of the ceiling rail,
Smoke barrier with buffer function. The support member side end surface of the facing ceiling rail and the ceiling rail side end surface of the support member are formed on inclined surfaces directed in opposite directions.
The smoke-proof hanging wall with a buffer function according to claim 1 . The support member is an adjacent ceiling rail to which the upper end portion of the non-combustible sheet is attached adjacent to the ceiling rail.
The smoke-proof hanging wall with a buffer function according to claim 1 or 2 . The support member is an intermediate stand disposed between the ceiling rail and an adjacent ceiling rail to which an upper end portion of an adjacent non-combustible sheet adjacent to the non-combustible sheet is attached.
The smoke-proof hanging wall with a buffer function according to claim 1 or 2 . At least one of the ceiling rail and the support member is provided with a lid that covers a gap between the ceiling rail and the support member.
Buffering function with Bokemurishidekabe according to any one of claims 1-4. The incombustible sheet is separably attached to the ceiling rail and the vertical.
Buffering function with Bokemurishidekabe according to any one of claims 1-5.

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