JP5431216B2 - Fireproof board support structure for curtain wall and building - Google Patents

Description

  The present invention relates to a fireproof board support structure for a curtain wall and a building.

  In the Building Standards Law, technical standards for exterior walls are applied to the part between windows on the upper and lower floors (hereinafter referred to as “spandrels”) for curtain walls used in buildings exceeding a certain height and scale. However, for the purpose of preventing the spread of fire to the upper floor, it is obliged to provide an interlayer partition member having a height of 900 mm or more.

  In an aluminum curtain wall, a fireproof board is generally used as an interlayer partition member in a spandrel portion. This refractory board is made of soft material (brittle material) such as fiber mixed calcium silicate board, gypsum board, rock wool board, ceramic fiber board, etc. ).

  However, since the aluminum frame has low fire resistance, a support structure for the fireproof board that increases the mounting strength of the fireproof board has been proposed (for example, Patent Document 1). In the fireproof board support structure of Patent Document 1, as shown in FIG. 18, the peripheral portion of the fireproof board 100 is supported by an aluminum frame composed of a vertical 110 and a seamless 112. A vertical bracket 116 is fixed to the vertical 110 with a bolt 119. The vertical bracket 116 is arranged across the fireproof boards 100 that are horizontally adjacent to each other with the vertical 110 interposed therebetween, and bolts 118 are attached to insert nuts (not shown) embedded in the widthwise ends of the fireproof boards 100. It is fixed to the fireproof board 100 by tightening. On the other hand, a fastener 114 is fixed to the slab 102 on the indoor side of the building with a bolt 117, and a vertical bracket 116 is fixed to the fastener 114 with a bolt 120.

  However, since the support structure of the fireproof board of Patent Document 1 is configured to fix the vertical bracket 116 by fastening the bolt 118 to the insert nut embedded in the fireproof board 100, stress concentrates on the embedded portion of the insert nut. In addition, the embedded portion of the insert nut of the fireproof board 100 may be damaged or damaged.

  On the other hand, Patent Document 2 discloses an interlaminar blocking structure in which a fireproof board for a beam material provided between a fireproof board for an outer wall and floor concrete is fixed to a rising portion of a floor concrete casting form with screws. Has been.

  However, the interlayer blocking structure of Patent Document 2 supports the fireproof board for the beam material, and does not support the fireproof board for the outer wall. Further, even if the fireproof board for the outer wall is fixed to the rising portion of the floor concrete casting form with screws, stress is concentrated on the screw mounting portion as in the fireproof board support structure of Patent Document 1, There is a risk of damage and damage to the fireproof board screw mounting.

JP-A-7-324415 JP-A-11-36479

  In view of the above facts, the present invention aims to suppress breakage and damage of the fireproof board and improve the support performance of the fireproof board.

  The curtain wall fireproof board support structure according to claim 1 is attached to an upper part of a structural member, and is held by holding the front and back surfaces of the held portion of the fireproof board arranged with a gap from the structural member. And a restricting means for restricting displacement of the fireproof board in a direction approaching the structural member by contacting the rear surface of the fireproof board below the held portion.

  According to the first aspect of the present invention, the holding means holds the fireproof board by sandwiching the front and back surfaces of the held portion of the fireproof board. Therefore, for example, the stress acting on the held portion can be reduced by bringing the holding means into surface contact with the front and back surfaces of the held portion of the fireproof board and increasing the contact area with the held portion. As a result, since the breakage and damage of the held portion of the fireproof board are suppressed, the support performance of the fireproof board is improved.

  Further, the displacement in the direction approaching the structural member of the fireproof board is restricted by the restricting means that contacts the rear surface of the fireproof board below the held portion of the fireproof board. Here, in the configuration not provided with the restricting means, when the aluminum frame that restrains the peripheral portion of the fireproof board is melted in the event of a fire, the fireproof board may tilt or rotate toward the structural member with the holding means as a fulcrum.

  On the other hand, in the present invention, the restricting means comes into contact with the rear surface of the fireproof board below the held portion of the fireproof board, so that the displacement in the direction approaching the structural member of the fireproof board is restricted, and the holding means is the fulcrum. Inclination and rotation of the fireproof board toward the structural member side are suppressed. Therefore, the support performance of the fireproof board is improved not only at normal times but also at the time of fire.

  Furthermore, since it is possible to omit the aluminum frame that restrains the peripheral edge of the fireproof board, cost reduction can be achieved.

  The fireproof board support structure for a curtain wall according to claim 2 is the fireproof board support structure for a curtain wall according to claim 1, wherein the restricting means is attached to the structural member, and the fireproof board extends from the structural member. It has an overhang part which protrudes toward and contacts the back surface of the fireproof board.

  According to the invention which concerns on Claim 2, the overhang | projection part which protrudes toward a fireproof board from a structural member contacts the back surface of a fireproof board. This overhanging part restricts the displacement in the direction approaching the structural member of the fireproof board, and suppresses the inclination and rotation of the fireproof board with the holding means as a fulcrum toward the structural member. By attaching the holding means and the regulating means to the same structural member in this way, the labor for attaching the holding means and the regulating means is reduced. Therefore, the workability is improved.

  The fireproof board support structure for a curtain wall according to claim 3 is the fireproof board support structure according to claim 1 or 2, wherein the overhanging portion supports an interlayer plugging material provided in the gap. .

  According to the third aspect of the present invention, since the interlayer sealing material provided in the gap between the fireproof board and the structural member is supported by the overhanging portion, the support member for supporting the interlayer sealing material can be omitted. Therefore, cost reduction can be achieved.

  The fireproof board support structure for a curtain wall according to claim 4 is the fireproof board support structure for a curtain wall according to claim 2 or claim 3, wherein the restricting means is located above and below the front end in the overhang direction of the overhang portion. It has a contact portion that extends in the direction and contacts the back surface of the fireproof board.

  According to the invention which concerns on Claim 4, the control means has a contact part extended to an up-down direction from the protrusion direction front-end | tip part of an extension part. By making the contact portion come into surface contact with the back surface of the fireproof board and increasing the contact area with the fireproof board, the stress generated in the fireproof board is reduced. Therefore, breakage and damage of the held portion of the fireproof board can be suppressed. Furthermore, the refractory board can be stably supported by increasing the contact area with the refractory board.

  The fireproof board support structure for a curtain wall according to claim 5 is the fireproof board support structure for a curtain wall according to claim 4, wherein the restricting means extends from the contact portion to a lower surface of the fireproof board. A support portion for supporting the board from below is provided.

  According to the invention which concerns on Claim 5, the control means has a support part extended from the contact part to the lower surface of a fireproof board. The fireproof board is supported from below by this support portion. Thereby, a fireproof board can be supported further stably.

  The fireproof board support structure for a curtain wall according to claim 6 includes a joining means for joining the fireproof board and the contact portion in the fireproof board support structure for a curtain wall according to claim 4 or 5. ing.

  According to the invention according to claim 6, by joining the refractory board and the contact portion by the joining means, the inclination or rotation in the direction away from the structural member of the refractory board due to the internal pressure or the like at the time of earthquake or fire. Is suppressed. Accordingly, the support performance of the fireproof board is improved. Furthermore, since the repeated stress acting on the held portion of the fireproof board held by the holding means is reduced, breakage and damage to the held portion of the fireproof board are suppressed. Therefore, the durability of the fireproof board is improved.

  The fireproof board support structure for a curtain wall according to claim 7 is the fireproof board support structure for a curtain wall according to any one of claims 2 to 6, wherein the structural member is a concrete slab, and the restriction means Has a mounting portion that is attached to the upper surface of the concrete slab, and a facing portion that extends downward from the mounting portion and is disposed in the gap and faces the fireproof board, wherein the overhanging portion is the facing portion. Projecting toward the fireproof board.

  According to the seventh aspect of the present invention, by attaching the attachment portion of the restriction means to the upper surface of the concrete slab as the structural member, compared to the configuration in which the attachment portion of the restriction means is attached to the lower surface of the concrete slab, Installation work becomes easy. This is because the attaching operation of the regulating means can be performed downward. Therefore, the workability is improved.

  The fireproof board support structure for a curtain wall according to claim 8 is the fireproof board support structure for a curtain wall according to any one of claims 1 to 7, wherein the holding means is formed on the fireproof board. A female screw portion to be inserted into the through hole, a first holding portion that projects from the female screw portion in the radial direction of the female screw portion and contacts the surface of the fireproof board, and a second that contacts the back surface of the fireproof board A holding part and a fastening bolt fastened to the female screw part through an attachment hole formed in the second holding part.

  According to the invention which concerns on Claim 8, the front and back of the to-be-held part of a refractory board is made into the female screw part inserted in the through-hole of the refractory board by tightening a fastening bolt through the attachment hole of a 2nd holding part. It is sandwiched between the first holding part and the second holding part. By causing the first holding part and the second holding part to be in surface contact with the fireproof board and increasing the contact area with the fireproof board, the stress acting on the held part of the fireproof board can be reduced. As a result, since the breakage and damage of the held portion of the fireproof board are suppressed, the support performance of the fireproof board is improved.

  Moreover, since it is the structure which inserts an internal thread part in the through-hole formed in the fireproof board, workability improves compared with the structure which embeds an insert nut like the past (for example, patent document 1).

  A building described in claim 9 includes the fireproof board support structure for a curtain wall according to any one of claims 1-8.

  According to the invention which concerns on Claim 9, since the support performance of a fireproof board improves by providing the fireproof board support structure for curtain walls of any one of Claims 1-8, the fireproof performance of a building improves.

  Since this invention set it as said structure, it can suppress the failure | damage of a fireproof board, damage, and can improve the support performance of a fireproof board.

It is the figure which looked at the curtain wall which concerns on one Embodiment of this invention from the outdoor side. FIG. 2 is a sectional view taken along line 2-2 of FIG. FIG. 3 is a sectional view taken along line 3-3 in FIG. 1. FIG. 3 is an enlarged view of a main part of FIG. 2. It is a perspective view which shows the holding means and regulation means which concern on one Embodiment of this invention. It is a figure equivalent to FIG. 4 which shows the modification of the control means which concerns on one Embodiment of this invention. It is a figure equivalent to FIG. 4 which shows the modification of the control means which concerns on one Embodiment of this invention. It is a figure equivalent to FIG. 4 which shows the modification of the control means which concerns on one Embodiment of this invention. It is a figure equivalent to FIG. 4 which shows the modification of the control means which concerns on one Embodiment of this invention. It is a figure equivalent to FIG. 4 which shows the modification of the control means which concerns on one Embodiment of this invention. It is a principal part enlarged view equivalent to FIG. 4 which shows the modification of the holding means which concerns on one Embodiment of this invention. It is a figure equivalent to FIG. 4 which shows the modification of the holding means which concerns on one Embodiment of this invention. It is a principal part enlarged view equivalent to FIG. 3 which shows the modification of the holding means which concerns on one Embodiment of this invention. It is a principal part enlarged view equivalent to FIG. 3 which shows the modification of the holding means which concerns on one Embodiment of this invention. It is a principal part enlarged view equivalent to FIG. 4 which shows the modification of the holding means which concerns on one Embodiment of this invention. It is a principal part enlarged view equivalent to FIG. 4 which shows the modification of the holding means which concerns on one Embodiment of this invention. It is a figure equivalent to Drawing 4 showing the modification of the structural member concerning one embodiment of the present invention. It is a figure which shows a prior art.

  A curtain wall fireproof board support structure according to an embodiment of the present invention will be described below with reference to the drawings.

  First, the configuration of the curtain wall fireproof board support structure 10 will be described.

<Composition of curtain wall>
FIG. 1 shows a curtain wall 12 to which the curtain wall fireproof board support structure 10 is applied. The curtain wall 12 includes a plurality of vertices 14 standing in the horizontal direction at intervals, and a plurality of invisible lines 16 erected between the stances 14 at intervals in the vertical direction. These verticals 14 and the meshes 16 are made of aluminum and connected in a lattice shape, and a window glass 18 is disposed in the lattice frame.

  As shown in FIGS. 2 and 3, the upright 14 is disposed adjacent to the concrete slab (structural member) 20 and supported by the concrete slab 20 via the upright bracket 22 and the fastener 24.

  The vertical bracket 22 has an L-shaped cross section and is fixed to both side surfaces of the vertical 14 with bolts 26. The fastener 24 has an L-shaped cross section and is fixed to the upper surface of the concrete slab 20 with bolts 28. The curtain wall 12 is supported by the concrete slab 20 by fixing the vertical bracket 22 to the fastener 24 with bolts 30 and nuts 31. The concrete slab 20 is supported by a steel beam 32 (see FIG. 2).

  The spandrel between the upper floor window and the lower floor window of the curtain wall 12 is provided with a fireproof board 34 as an interlayer partition member. The fireproof board 34 is provided on the indoor side of the window glass 18 and is disposed in an aluminum frame surrounded by the vertical 14 and the mesh 16. The fireproof board 34 is composed of a fiber mixed calcium silicate board, a gypsum board, a rock wool board, a ceramic fiber board, and the like, and its peripheral part is disposed in a rail 36 provided on the vertical 14 and the mesh 16. ing. The rails 36 hold the fireproof board 34 with the concrete slab 20 and the gap D (see FIG. 2) therebetween.

<Configuration of holding means>
As shown in FIG. 4, the fireproof board 34 is supported by the concrete slab 20 via the holding means 40. The holding means 40 includes a nut member 42 attached to the fireproof board 34, an attachment member 44 attached to the upper surface of the concrete slab 20, and a fastening bolt 38 fastened to the nut member 42. For convenience of explanation, the outdoor side surface of the fireproof board 34 will be described as a front surface 34A, and the indoor side surface will be described as a back surface 34B.

  As shown in FIG. 5, the nut member 42 has a female screw portion 42A and a first holding portion 42B provided at an end of the female screw portion 42A. The female screw portion 42A has a cylindrical shape, and a female screw is cut inside thereof, so that a fastening bolt 38 can be fastened. The first holding portion 42B is a disc shape, is disposed coaxially with the female screw portion 42A, and protrudes from the end portion of the female screw portion 42A in a radial shape in the radial direction of the female screw portion 42A.

  On the other hand, through holes 48 are formed at both ends in the width direction of the fireproof board 34 to which the nut member 42 is attached. A counterbore 50 having a diameter larger than that of the through hole 48 is formed on the edge of the through hole 48 on the surface 34 </ b> A side of the fireproof board 34. The female screw portion 42A of the nut member 42 is inserted into the through hole 48 so as not to protrude from the back surface 34B of the fireproof board 34, and the first holding portion 42B of the nut member 42 is in surface contact with the bottom surface of the counterbore 50. It is stored in the state. The first holding portion 42B is stored in the spot facing 50 so as to be substantially flush with the surface 34A of the fireproof board 34. Thereby, the appearance of the fireproof board 34 from the outdoor side is improved.

  An attachment member 44 is provided at a position facing the nut member 42. The mounting member 44 is made of a steel plate having an L-shaped cross section, and projects from the upper surface of the concrete slab 20 toward the fireproof board 34. The attachment member 44 includes an attachment portion 44A attached to the concrete slab 20, and a second holding portion 44B bent upward along the fireproof board 34 from the projecting end of the attachment portion 44A. It arrange | positions in the state which made the 2nd holding | maintenance part 44B surface-contact with the back surface 34B. By tightening the fastening bolt 38 into the female screw portion 42A of the nut member 42 through the mounting hole 52 formed in the second holding portion 44B, the first holding portion 42B of the nut member 42 and the second holding of the mounting member 44 are retained. The front surface 34A and the back surface 34B of the held portion 34X (see FIG. 4) of the fireproof board 34 are held between the portion 44B and the portion 44B.

  The front surface 34 </ b> A and the back surface 34 </ b> B of the fireproof board 34 are concepts including a surface recessed from the front surface 34 </ b> A of the fireproof board 34, such as the bottom surface of the spot facing 50. Further, the held portion 34X of the fireproof board 34 means a portion of the fireproof board 34 sandwiched between the first holding portion 42B and the second holding portion 44B, and in the present embodiment, both ends in the width direction of the fireproof board 34. Are provided respectively. The held portion 34 </ b> X can be appropriately provided at a necessary portion of the fireproof board 34 according to the support conditions of the fireproof board 34.

  An attachment hole 54 is formed in the attachment portion 44 </ b> A of the attachment member 44, and the attachment member 44 is secured by tightening a bolt 56 penetrating through the attachment hole 54 into an anchor nut 58 embedded in the upper surface of the concrete slab 20. Is fixed to the upper surface of the concrete slab 20. The attachment hole 54 is a long hole extending in the extending direction (arrow A direction) of the attachment portion 44 </ b> A, and the gap D between the fireproof board 34 and the concrete slab 20 can be adjusted. The attachment hole 54 may be a long hole extending in a direction orthogonal to the extending direction of the attachment portion 44A.

<Composition of regulation means>
Further, as shown in FIG. 4, a regulating means 60 is attached to the concrete slab 20. The restricting means 60 is configured by bending a steel plate in a Z-shape, and has a mounting portion 60A, a facing portion 60B, and an overhang portion 60C. The attachment portion 60 </ b> A is disposed between the upper surface of the concrete slab 20 and the attachment portion 44 </ b> A of the attachment member 44, and is attached to the upper surface of the concrete slab 20 together with the attachment member 44.

  Specifically, a mounting hole 62 is formed in the mounting portion 60 </ b> A of the regulating means 60, and a bolt 56 penetrating through the mounting hole 62 and the mounting hole 54 of the mounting member 44 is embedded in the upper surface of the concrete slab 20. By tightening the anchor nut 58, the restricting means 60 and the attachment member 44 are fixed to the upper surface of the concrete slab 20. Further, the mounting hole 62 of the mounting portion 60A of the regulating means 60 is a long hole extending in the protruding direction (arrow A direction) of the protruding portion 60C described later, and adjusts the gap D between the fireproof board 34 and the concrete slab 20. It is possible. In addition, this attachment hole 62 is good also as a long hole extended in the direction orthogonal to the overhang | projection direction of 60 C of overhang | projection parts.

  An opposing portion 60B that is bent downward along the end surface of the concrete slab 20 from the end portion is provided at the end portion of the attachment portion 60A on the fireproof board 34 side. The facing portion 60 </ b> B is disposed in the gap D between the fireproof board 34 and the concrete slab 20 and faces the concrete slab 20.

  A projecting portion 60C that projects from the lower end portion toward the fireproof board 34 is provided at the lower end portion of the facing portion 60B. The overhanging portion 60C is disposed substantially horizontally so as to be substantially flush with the lower surface of the concrete slab 20, and the end portion of the overhanging direction (arrow A direction) is below the held portion 34X of the fireproof board 34 and the fireproof board 34. It is in contact with the back surface 34B. Thereby, the inclination and rotation (arrow B direction) of the direction which approaches the concrete slab 20 of the fireproof board 34 which used the nut member 42 or the attachment member 44 as a fulcrum are controlled.

  Further, a plate material 64 that closes the gap D between the fireproof board 34 and the concrete slab 20 is placed on the overhanging portion 60C. The plate material 64 is disposed along the gap D between the fireproof board 34 and the concrete slab 20, and is passed between the overhang portions 60 </ b> C of the adjacent regulating means 60. On this plate material 64, an interlayer sealing material 66 such as rock wool that fills the gap D between the fireproof board 34 and the concrete slab 20 is placed. The interlayer plug 66 suppresses hot air and flames flowing from the lower floor of the concrete slab 20 to the upper floor of the concrete slab 20 through the gap D between the fireproof board 34 and the concrete slab 20 in the event of a fire.

  Next, the effect | action of the fireproof board support structure 10 for curtain walls which concerns on one Embodiment is demonstrated.

  A nut member 42 is attached to the held portion 34 </ b> X of the fireproof board 34. By tightening the fastening bolt 38 through the mounting hole 52 formed in the second holding portion 44B of the mounting member 44 into the female screw portion 42A of the nut member 42, the first holding portion 42B of the nut member 42 and the mounting member 44 are connected. The front surface 34A and the back surface 34B of the held portion 34X are sandwiched and held between the second holding portions 44B.

  Here, in the configuration in which the insert nut is embedded in the fireproof board 34 as in the past (for example, Patent Document 1), stress concentrates on the embedded portion of the insert nut, and the embedded portion may be broken or damaged. In contrast, in the present embodiment, the front surface 34A and the back surface of the held portion 34X are provided by the first holding portion 42B and the second holding portion 44B that are in surface contact with the front surface 34A and the back surface 34B of the held portion 34X of the fireproof board 34. Since it is held across 34B, stress acting on the front surface 34A and the back surface 34B of the held portion 34X is reduced, and it acts on the inner peripheral surface of the through hole 48 into which the female screw portion 42A of the nut member 42 is inserted. Stress is reduced.

  In addition, when the fireproof board 34 vibrates due to an external force such as hot air at the time of a fire, wind, earthquake, or the like, stress is repeatedly applied to the held part 34X of the fireproof board 34. In the present embodiment, the first holding part 42B and the first holding part 42B 2 Since the holding portion 44B comes into surface contact with the front surface 34A and the back surface 34B of the held portion 34X of the fireproof board 34, the repeated stress is dispersed and transmitted to the held portion 34X. Therefore, since the breakage and damage of the held portion 34X of the fireproof board 34 are suppressed, the support performance of the fireproof board 34 is improved.

  Furthermore, since the stress acting on the held portion 34X of the fireproof board 34 is reduced, the strength and rigidity required for the held portion 34X can be kept small. Therefore, the material cost etc. of the fireproof board 34 can be reduced.

  Furthermore, since it is the structure which attaches the nut member 42 to the fireproof board 34 by inserting the internal thread part 42A in the through-hole 48 formed in the fireproof board 34, conventionally (for example, patent document 1), Compared to the structure in which the insert nut is embedded in the fireproof board, the labor for attaching the nut member 42 is reduced.

  Here, since the uprights 14 and the meshes 16 of the curtain wall 12 that support the fireproof board 34 are generally made of aluminum, there is a risk of melting due to a temperature rise during a fire. When these verticals 14 and the mesh 16 are melted and the restraint of the peripheral portion of the fireproof board 34 by the rail 36 (see FIGS. 2 and 3) is released, the holding means 40 bears the entire weight of the fireproof board 34. Will be. At this time, as in the present embodiment, in the configuration in which the fireproof board 34 is supported by the holding means 40 projecting from the concrete slab 20 toward the fireproof board 34, the mounting member 44 is bent by the weight of the fireproof board 34, or the nut The fireproof board 34 around the member 42 is crushed, and the fireproof board 34 tilts in a direction approaching the concrete slab 20 (in the direction of arrow B in FIG. 4) with the mounting member 44 or the nut member 42 as a fulcrum. Or it may rotate.

  As a countermeasure, in the present embodiment, a restriction means 60 is provided on the concrete slab 20. The regulating means 60 has a projecting portion 60C projecting from the concrete slab 20 toward the fireproof board 34, and the projecting direction (in the direction of arrow A) of the projecting portion 60C is from the held portion 34X of the fireproof board 34. In addition, by contacting the lower surface 34B of the fireproof board 34 at the lower side, the inclination and rotation of the fireproof board 34 in the direction approaching the concrete slab 20 (arrow B direction) are suppressed. Thereby, the support performance of the fireproof board 34 at the time of a fire can be improved not only at all times.

  Moreover, since the inclination and rotation of the fireproof board 34 are suppressed by the restricting means 60, the rail 36 and the like that restrain the peripheral edge of the fireproof board 34 can be omitted. Accordingly, since the structure of the curtain wall 12 is simplified, the manufacturing cost can be reduced.

  Furthermore, the overhanging portion 60C of the restricting means 60 is disposed in the gap D between the fireproof board 34 and the concrete slab 20, and the plate material 64 and the interlayer plugging material 66 are supported by the overhanging portion 60C. Thus, by using the overhanging portion 60C as a support member for the interlayer plugging material 66, the support member for supporting the interlayer plugging material 66 can be omitted, so that cost reduction can be achieved.

  Furthermore, in this embodiment, attaching the holding means 40 and the regulating means 60 to the upper surface of the concrete slab 20 facilitates the attaching operation of the holding means 40 and the regulating means 60. This is because the attaching work of the holding means 40 and the regulating means 60 can be performed downward. Further, in order to fix the holding means 40 and the regulating means 60 to the upper surface of the concrete slab 20 with one bolt 56, the holding means 40 and the regulating means 60 are compared with a configuration in which the holding means 40 and the regulating means 60 are separately mounted. This reduces the labor of mounting the work. Therefore, the workability is improved.

  Thus, by providing the curtain wall fireproof board support structure 10 according to the present embodiment, the fireproof board 34 can be prevented from being damaged and damaged, and the fireproof board 34 can be prevented from tilting and rotating in the event of a fire. Support performance is improved. As a result, the fire resistance performance of the building is improved.

  Next, a modified example of the curtain wall fireproof board support structure 10 according to the embodiment will be described. In addition, the thing of the same structure as the said embodiment attaches | subjects the same code | symbol, and abbreviate | omits suitably and demonstrates.

  First, a modified example of the restricting means will be described.

  In the above-described embodiment, the tip end portion of the overhang portion 60C provided in the restricting means 60 is brought into contact with the back surface 34B of the fireproof board 34. However, the present invention is not limited thereto, and extends vertically to the tip end portion of the overhang portion 60C. A contact portion may be provided to increase the contact area with the fireproof board 34.

  Specifically, as shown in FIG. 6, the restricting means 60 is provided with a contact portion 60 </ b> D that is bent downward along the back surface 34 </ b> B of the fireproof board 34 from the front end portion of the overhang portion 60 </ b> C. . When the contact portion 60D comes into surface contact with the back surface 34B of the fireproof board 34, the stress generated in the fireproof board 34 is reduced. Therefore, breakage and damage of the fireproof board 34 are suppressed. Furthermore, since the contact portion 60D increases the contact area with the fireproof board 34, the fireproof board can be stably supported, so that the support performance of the fireproof board 34 is improved.

  In the configuration shown in FIG. 6, the contact portion 60D extending downward from the distal end portion of the overhang portion 60C is provided, but a contact portion extending upward from the distal end portion of the overhang portion 60C may be provided. Furthermore, you may provide the contact part extended upwards and downwards from the protrusion direction front-end | tip part of the overhang | projection part 60C so that it may become a T-shaped cross section.

  Further, as shown in FIG. 7, the contact portion 60 </ b> D and the fireproof board 34 may be joined by the joining means 72. The joining means 72 includes an insert nut 74 embedded in the fireproof board 34 and a bolt 76 tightened on the insert nut 74. The fireproof board 34 and the contact portion 60D are joined to the insert nut 74 by tightening a bolt 76 through a through hole 78 formed in the contact portion 60D.

  Here, when the vertical 14 and the mesh 16 are melted at the time of a fire, the fire-resistant board 34 is separated from the concrete slab 20 by using the nut member 42 or the mounting member 44 as a fulcrum due to internal pressure caused by hot air generated inside the fire-resistant board 34. There is a risk of tilting or rotating in the direction of separation (direction of arrow C).

  On the other hand, in this modification, by joining the fireproof board 34 and the contact portion 60D by the joining means 72, the inclination of the fireproof board 34 in the direction away from the concrete slab 20 with the nut member 42 or the attachment member 44 as a fulcrum. And rotation is suppressed. Therefore, the support performance of the fireproof board 34 at the time of a fire improves. Furthermore, since the vibration of the fireproof board 34 caused by wind, earthquake or the like is also suppressed, the repeated stress acting on the held portion 34X of the fireproof board 34 is reduced. Therefore, since the breakage and damage of the held portion 34X of the fireproof board 34 are suppressed, the support performance and durability of the fireproof board 34 are improved.

  In this modification, the fireproof board 34 and the contact portion 60D are joined by the insert nut 74 and the bolt 76, but may be joined by a tapping screw, a pin, an adhesive, or the like. Further, the nut member 42 may be attached to the fireproof board 34 and joined with the fastening bolt 38. According to this configuration, breakage and damage of the fireproof board 34 can be suppressed.

  Further, as shown in FIG. 8, the contact portion 60 </ b> D may be extended to the lower end portion of the fireproof board 34, and a support portion 60 </ b> E extending to the lower surface of the fireproof board 34 may be provided on the contact portion 60 </ b> D. The support part 60E is bent in the horizontal direction along the lower surface of the fireproof board 34 from the lower end part of the contact part 60D. Further, a folded portion 60F that is bent upward along the surface 34A of the fireproof board 34 is provided at the tip of the support portion 60E so as to go around to the surface 34A side of the fireproof board 34. The fireproof board 34 is supported from below by the support portion 60E, and the horizontal displacement of the fireproof board 34 is restricted by the folded portion 60F and the contact portion 60D. Thereby, the fireproof board 34 can be supported more stably.

  Furthermore, in the said embodiment, although the control means 60 was attached to the upper surface of the concrete slab 20, it is not restricted to this. The restricting means 60 only needs to be able to contact the back surface of the fireproof board 34 below the held portion 34X of the fireproof board 34, and may be attached to the lower surface of the concrete slab 20, for example, as shown in FIG. .

  In the configuration shown in FIG. 9, a steel plate 80 as a regulating means is attached to the lower surface of the concrete slab 20. The steel plate 80 projects from the lower surface of the concrete slab 20 toward the fireproof board 34, and the front end portion in the projecting direction is in contact with the back surface 34 </ b> B of the fireproof board 34. On the other hand, a mounting hole 82 is formed at the end of the steel plate 80 on the concrete slab 20 side, and the bolt 86 is tightened into the anchor nut 84 embedded in the lower surface of the concrete slab 20 through the mounting hole 82. A steel plate 80 is fixed to the lower surface of the concrete slab 20. Furthermore, a plate material 64 that supports the interlayer plugging material 66 is placed on the steel plate 80.

  Further, as shown in FIG. 10, a steel plate 90 as a restricting means may be attached to the steel beam 32 that supports the concrete slab 20. One end portion of the steel plate 90 is fixed to the lower flange 32B of the steel beam 32 by welding, an adhesive, or the like, and the other end portion projects from the lower flange 32B toward the fireproof board 34, and the held portion 34X of the fireproof board 34 is supported. It is in contact with the back surface 34B of the refractory board 34 below. The plate member 64 that supports the interlayer plugging material 66 is supported by a support member such as a reinforcing bar (not shown).

  In this way, by increasing the distance L between the holding means 40 for holding the fireproof board 34 and the support point of the steel plate 90 as the restricting means, that is, by increasing the length of the arm of the moment, Tilt and rotation can be efficiently suppressed.

  In this modification, the steel plate 90 is fixed to the lower flange 32B of the steel beam 32. However, the steel plate 90 may be fixed to the web 32A of the steel beam 32. Further, the steel plate 90 may be fixed not to the steel beam 32 but to a steel column or the like adjacent to the fireproof board 34.

  Next, a modified example of the holding means will be described.

  As shown in FIG. 11, a decorative plate 92 made of the same material as the fireproof board 34 may be arranged in the spot facing 50 formed on the fireproof board 34 to close the spot facing 50. Thereby, since the nut member 42 is hidden by the decorative board 92, the appearance of the fireproof board 34 is improved.

  Further, between the through hole 48 of the fireproof board 34 and the female screw portion 42A of the nut member 42, between the bottom surface of the spot facing 50 and the first holding portion 42B, the back surface 34B of the fireproof board 34 and the second holding portion 44B. Between them, a functional material such as an adhesive, a cushioning material, or a seal member may be provided.

  Here, since the bonding strength between the fireproof board 34 and the nut member 42 is increased by providing an adhesive as the functional material, the support strength of the fireproof board 34 is improved. Moreover, since the nut member 42 is prevented from falling off when the fireproof board 34 is conveyed, the workability is improved.

  In addition, as an adhesive agent, it can be used regardless of an organic type inorganic type. In the case of an organic system, a surface treatment (sealer treatment) on the fiber-mixed calcium silicate plate is required. Of the inorganic adhesives, it is desirable to use ceramic or sodium silicate based on fire resistance, and sodium silicate is generally used for fiber-mixed calcium silicate plates.

  Further, by providing the cushioning material or the seal member as the functional material, rattling of the fireproof board 34 is suppressed, and the shock absorbing board 34 or the seal member absorbs an impact on the fireproof board 34, so that the support performance of the fireproof board 34 is improved. improves.

  In addition, as a shock absorbing material, natural rubber, synthetic rubber, a viscoelastic body, etc. can be used, for example. In addition, as the sealing member, for example, a silicon-based filler, a thermally expandable refractory filler, or a molded product thereof can be used. Further, examples of the molded product of the thermally expandable refractory material include a rubber material and a sponge material.

  Moreover, in the said embodiment, although the attachment member 44 was directly attached to the upper surface of the concrete slab 20, it is not restricted to this. For example, as shown in FIG. 12, the attachment member 44 may be attached to the concrete slab 20 via an adjustment member 94 for adjusting the attachment height. The adjustment member 94 is formed by bending a steel plate in a Z shape, and has an attachment portion 94A and a connection portion 94B having different heights. The adjustment member 94 is arranged such that its attachment portion 94A is overlapped on the attachment portion 60A of the regulating means 60 and the connection portion 94B projects from the concrete slab 20 toward the fireproof board 34.

  A mounting hole 96 is formed in the mounting portion 94 </ b> A, and a bolt 56 penetrating through the mounting hole 96 and the mounting hole 62 of the mounting portion 60 </ b> A of the restricting means 60 is attached to an anchor nut 58 embedded in the upper surface of the concrete slab 20. By tightening, the adjusting member 94 and the regulating means 60 are fixed to the upper surface of the concrete slab 20.

  Further, the attachment hole 96 of the attachment portion 94A of the adjustment member 94 is a long hole extending in the protruding direction (arrow A direction) of the connecting portion 94B, and the gap D between the fireproof board 34 and the concrete slab 20 (see FIG. 2). ) Is adjustable. In addition, this attachment hole 96 is good also as a long hole extended in the direction orthogonal to the overhanging direction of the connection part 94B.

  An attachment portion 44A of the attachment member 44 is overlaid on the connecting portion 94B disposed at a position higher than the attachment portion 94A with respect to the concrete slab 20. A through hole 98 is formed in the connecting portion 94B, and the connecting portion 94B and the attaching portion 44A are connected by a bolt 121 and a nut 122 that pass through the through hole 98 and the attaching hole 54 of the attaching portion 44A.

  Thus, the attachment height of the fireproof board 34 can be adjusted by attaching the attachment member 44 to the concrete slab 20 via the adjustment member 94. Thereby, since the construction error of the curtain wall 12 and the construction error of the concrete slab 20 can be absorbed by the adjusting member 94, the workability is improved.

  Furthermore, as shown in FIG. 13, the attachment member 44 may be attached to the concrete slab 20 via the fastener 24 that supports the fireproof board 34. An angle 124 having an L-shaped cross section is arranged on the fastener 24. The angle 124 is disposed substantially in parallel with the fireproof board 34, and both ends of the angle 124 project from the fastener 24 to both sides in the horizontal direction.

  The angle 124 is fixed to the upper surface of the concrete slab 20 together with the fastener 24 by a bolt 28 that fixes the fastener 24 to the concrete slab 20. Attachment portions 44A of the attachment member 44 are attached to both ends of the angle 124. The attachment member 44 is disposed so as to be substantially orthogonal to the angle 124, and the attachment portion 44 </ b> A is overlapped with both ends of the angle 124. Connection holes (not shown) are formed at both ends of the angle 124, and the attachment members 44 are connected by connection bolts 126 and nuts (not shown) that pass through the connection holes and the attachment holes 54 of the attachment portion 44A. It is fixed to the angle 124. The attachment member 44 is projected from the angle 124 toward the fireproof board 34 and is disposed in a state where the second holding portion 44B is in contact with the back surface 34B of the fireproof board 34.

  Thus, by attaching the attachment member 44 via the fastener 24, the anchor nut 58 (see FIG. 4) embedded in the concrete slab 20 can be omitted, so that the labor of the attachment work is reduced. Therefore, the workability is improved.

  Further, the shape of the attachment member 44 is not limited to the L-shaped cross section. For example, as shown in FIG. 14, an attachment member 140 having a Z-shaped cross section may be used. The attachment member 140 is attached to the upper surface of the concrete slab 20 via an angle 142. The angle 142 has an L-shaped cross section, a mounting portion 142A provided at one end thereof is fixed to the upper surface of the concrete slab 20 with a bolt 144, and a connecting portion 142B provided at the other end is connected from the concrete slab 20 to the fireproof board 34. It is arranged in a state of projecting toward.

  The attachment member 140 is configured by bending a steel plate in a Z-shape, and has an attachment portion 140A and a second holding portion 140B having different heights, and the longitudinal direction thereof is arranged in the horizontal direction. The mounting member 140 has its mounting portion 140A overlapped with the connecting portion 142B of the angle 142, and the second holding portion 140B disposed on the fireproof board 34 side of the mounting portion 140A is in surface contact with the back surface 34B of the fireproof board 34. In this state, it is supported by the angle 142. An attachment hole 146 and a through hole (not shown) are formed in the attachment part 140A and the connecting part 142B of the angle 142, respectively, and are attached by bolts 148 and nuts 149 that pass through the attachment hole 146 and the through hole. Part 140A is connected to connecting part 142B.

  The mounting hole 146 formed in the mounting portion 140A of the mounting member 140 is a long hole extending in a direction orthogonal to the protruding direction of the angle 142 (direction of arrow A), and the horizontal direction of the angle 142 and the fireproof board 34 It is possible to absorb construction errors, etc. The mounting hole 146 may be a long hole extending in the vertical direction. Similarly, the through hole formed in the connecting portion 142B of the angle 142 may be a long hole.

  A mounting hole 145 is formed in the second holding portion 140B in surface contact with the back surface 34B of the fireproof board 34, and a fastening bolt 38 is attached to the female thread portion 42A (see FIG. 4) of the nut member 42 through the mounting hole 145. By tightening, the held portion 34X of the fireproof board 34 is held.

  Thus, the shape of the attachment member 140 and the direction in which it can be arranged can be changed as appropriate. Further, by making the longitudinal direction of the mounting member 140 horizontal, it is possible to easily absorb construction errors in the horizontal direction between the concrete slab 20 and the fireproof board 34.

  Moreover, in the said embodiment, although the attachment member 44 was attached to the upper surface of the concrete slab 20, it is not restricted to this. The attachment member 44 should just be attached to the upper part of the concrete slab 20, for example, may be attached to the upper part of the end surface of the concrete slab 20. As shown in FIG.

  Furthermore, in the said embodiment, although the nut member 42 was attached to the fireproof board 34, it is not restricted to this. The holding means 40 only needs to be able to hold the front surface 34A and the back surface 34B of the held portion 34X of the fireproof board 34, that is, any structure that holds the fireproof board 34 from both sides in the thickness direction of the fireproof board 34. For example, as shown in FIG. 15, a contact plate 128 as a first holding portion is brought into surface contact with the surface 34A of the fireproof board 34, and the held portion is interposed between the contact plate 128 and the second holding portion 44B. The front surface 34A and the back surface 34B of 34X may be sandwiched.

  Specifically, through holes 130 and 132 are formed in the holding portion 34X of the contact plate 128 and the fireproof board 34, respectively, and pass through the through holes 130 and 132 and the mounting holes 52 of the second holding portion 44B. The front surface 34 </ b> A and the back surface 34 </ b> B of the held portion 34 </ b> X of the fireproof board 34 are sandwiched by narrowing the distance between the contact plate 128 and the second holding portion 44 </ b> B by the bolt 134 and the nut 136. Thereby, the effect similar to the holding means 40 which concerns on the said embodiment can be acquired.

  Further, in the nut member 42 according to the above-described embodiment, the first holding portion 42B is provided at the end of the female screw portion 42A. For example, a plurality of female screw portions 42A may be provided in the disc-shaped first holding portion 42B having a large diameter. Thereby, since the stress which acts on the to-be-held part 34X of the fireproof board 34 is further disperse | distributed, the failure | damage and damage of the to-be-held part 34X of the fireproof board 34 are suppressed. Further, the first holding portion 42B is not limited to a disc shape, and may be a rectangle.

  In addition, as shown in FIG. 16, the plate member 64 may be omitted, and the interlayer plug 66 may be directly supported by the overhanging portion 60C. In this configuration, the overhang portion 60C may be formed in a plate shape along the gap D (see FIG. 2).

  Furthermore, in the said embodiment, although the holding means 40 and the control means 60 were attached to the concrete slab 20 as a structural member, it is not restricted to this. For example, as shown in FIG. 17, the holding means 40 and the regulating means 60 may be attached to the concrete beam 138. Moreover, it is applicable not only to the concrete slab 20 but also to a deck composite slab, a deck composite slab, or a deck structure slab. The fireproof board 34 is not limited to a soft material (brittle material) such as a fiber mixed calcium silicate board, gypsum board, rock wool board, or ceramic fiber board, but also a hard material such as a PC board, an ALC panel, or an extruded cement board. It is also possible to apply to.

  As mentioned above, although one Embodiment of this invention was described, this invention is not limited to such Embodiment, Of course, in the range which does not deviate from the summary of this invention, it can implement in a various aspect.

10 Curtain Wall Fireproof Board Support Structure 20 Concrete Slab (Structural Member)
34 fireproof board 34A front surface 34B back surface 34X held portion 38 fastening bolt (holding means)
40 holding means 42A female thread portion (holding means)
42B 1st holding | maintenance part (holding means)
44B 2nd holding | maintenance part (holding means)
48 through-hole 52 mounting hole 60 regulating means 60A mounting part 60B facing part 60C overhanging part 60D contact part 60E support part 66 interlayer plug 72 joining means 74 insert nut (joining means)
76 bolts (joining means)
80 Steel plate (regulatory means)
90 Steel plate (regulatory means)
128 Catch plate (first holding part)
134 bolts (holding means)
136 Nut (holding means)
138 Concrete beams (structural members)
140B Second holding part (holding means)
D gap

Claims (9)

Holding means attached to the upper part of the structural member and holding the front and back surfaces of the held portion of the fireproof board arranged with a gap from the structural member;
A regulating means that contacts the back surface of the refractory board below the held portion and regulates displacement of the refractory board in a direction approaching the structural member;
Fireproof board support structure for curtain wall with   2. The fireproof board support structure for a curtain wall according to claim 1, wherein the restricting means includes a projecting portion that is attached to the structural member, projects from the structural member toward the fireproof board, and contacts the rear surface of the fireproof board.   The fireproof board support structure according to claim 1 or 2, wherein the overhanging portion supports an interlayer sealing material provided in the gap.   4. The fireproof board support structure for a curtain wall according to claim 2, wherein the restricting means includes a contact portion that extends in a vertical direction from a front end portion of the overhang portion in the overhang direction and contacts a back surface of the fireproof board.   5. The fireproof board support structure for a curtain wall according to claim 4, wherein the restricting means has a support portion that extends from the contact portion to a lower surface of the fireproof board and supports the fireproof board from below.   The fireproof board support structure for a curtain wall according to claim 4 or 5, further comprising joining means for joining the fireproof board and the contact portion. The structural member is a concrete slab;
The regulating means is
An attachment portion attached to the upper surface of the concrete slab;
Extending downward from the mounting portion and disposed in the gap, facing the fireproof board; and
Have
The fireproof board support structure for a curtain wall according to any one of claims 2 to 6, wherein the projecting portion projects from the facing portion toward the fireproof board. The holding means is
A female screw portion inserted into a through hole formed in the fireproof board;
A first holding portion that protrudes in a radial direction of the female screw portion from the female screw portion and contacts a surface of the fireproof board;
A second holding portion that contacts the back surface of the fireproof board;
A fastening bolt fastened to the female screw portion through an attachment hole formed in the second holding portion;
The fireproof board support structure for curtain walls according to any one of claims 1 to 7.   A building comprising the fire wall support structure for a curtain wall according to any one of claims 1 to 8.

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