JP6886788B2 - Seismic ceiling structure - Google Patents

Description

The present invention relates to a seismic ceiling structure including a ceiling material of a building and a hanging support material for the ceiling material provided in an attic space located above the ceiling material.

In general, as a ceiling of a clean room or an office, it is widely practiced to attach a ceiling material such as a ceiling board below a floor frame on an upper floor via a field edge or a field edge receiver.
For example, Patent Document 1 discloses a suspended ceiling base structure 101 as shown in FIG. The suspended ceiling base structure 101 includes a field edge 102, a field edge receiver 103 arranged orthogonally to the field edge 102, a hanging bolt 105 for suspending the field edge receiver 103, and a field edge receiver 103 and a hanging bolt. A hanging metal fitting 106 connecting 105, a hanging metal fitting reinforcing metal fitting 112 for reinforcing the hanging metal fitting 106, a horizontal member 107 for connecting two or more hanging metal fittings reinforcing metal fittings 112, and a horizontal member 107 and a hanging bolt 105. It is provided with a brace material 108 that is diagonally connected.

Since the suspended ceiling base structure 101 as described above is not a structure that is expected to bear a vertical load or an earthquake load, it may be greatly deformed when an earthquake occurs and the ceiling material may fall.
On the other hand, for example, Patent Document 2 discloses a ceiling suspension structure 110 as shown in FIG. In the suspension structure 110, the ceiling 112 is suspended from the superstructure 111 via the suspension member 113. The hanging member 113 is rigidly joined to the superstructure 111. As the hanging member 113, a member that exerts a history attenuation effect when the ceiling 112 connected to the lower end portion is displaced in the horizontal direction during an earthquake is used. With such a configuration, it is possible to reduce the horizontal force (seismic force) acting on the ceiling during an earthquake and the horizontal displacement of the ceiling.

However, in the ceiling suspension structure 110 disclosed in Patent Document 2, the suspension member 113 is joined to the lower surface of the floor skeleton on the upper floor, which is the upper structure 111, perpendicularly to the lower surface. When the seismic force is large, this joint cannot function as a rigid joint but functions as a pin joint against the horizontal force acting on the ceiling 112, and the ceiling 112 sways in the horizontal direction, resulting in the ceiling. There was a possibility that 112 would fall.
Further, Patent Document 3 discloses a seismic ceiling structure in which a field edge receiver in the attic space of the ceiling and a PC steel material in which tension is introduced erected between the building frames are tightly connected.

Japanese Unexamined Patent Publication No. 2008-50784 Japanese Unexamined Patent Publication No. 2003-306990 Japanese Patent No. 5925098

An object to be solved by the present invention is to provide a seismic ceiling structure having high rigidity and high seismic safety even if the number of parts is small and a steel material having a relatively small cross-sectional area is used.

The present invention employs the following means in order to solve the above problems. That is, the present invention is a seismic ceiling structure of a building rigidly joined to the beam skeleton of the ceiling space, and is rigidly joined to the side surface of the beam skeleton with the ceiling material provided in the upper part of the living room space of the building. A vertical steel material and a ceiling material direct-attached metal fitting for joining the vertical steel material and the ceiling material are provided, and the ceiling material direct-attached metal fitting includes a wall portion extending upward to be joined to the vertical steel material and a wall portion extending upward. It is characterized in that it is composed of a horizontal portion for fixing the ceiling material.
According to the above configuration, the vertical steel material that supports the ceiling material is rigidly joined to, for example, the side surface of the beam skeleton of the floor that protrudes downward from the floor skeleton of the upper floor. That is, the vertical steel material is provided along the side surface of the beam skeleton, and is rigidly joined to the beam skeleton at a plurality of positions in the vertical direction, for example, by a post-construction anchor or the like, instead of being pin-joined.
In addition, the vertical steel material is installed between the ceiling surface and the side surface of the beam skeleton on the floor, which has a shorter section length than between the ceiling surface and the lower surface of the floor skeleton on the upper floor. High rigidity is provided by reducing the amount of bending moment acting on the joint with the building frame (beam frame) to which the ceiling material is attached, which is calculated by multiplying the acting horizontal load by the length of the vertical steel material. It has a seismic ceiling structure. In addition, the ceiling material is joined to a vertical steel material that is rigidly joined to the beam frame in the attic space with metal fittings directly attached to the ceiling material, and a seismic ceiling structure is realized with a small number of parts.
In other words, in the seismic ceiling structure of the present invention, the vertical steel material is rigidly joined to the beam skeleton and integrated, so that the beam skeleton extends downward to the lower end of the vertical steel material via the vertical steel material. It can be read as, and high seismic safety is ensured by joining the metal fittings directly attached to the ceiling material to the beam frame extending to the lower end of the vertical steel material.
The above effects are synergistic, and a seismic ceiling structure with high rigidity and high strength has been realized.

Further, in one aspect of the present invention, in the seismic ceiling structure of a building rigidly joined to the beam skeleton in the attic space, the vertical steel materials are provided in pairs on both side surfaces of the beam skeleton. It is characterized by that.
According to this aspect, in addition to the above-mentioned effect, the cross-sectional area of the vertical steel material is increased by arranging the vertical steel materials on both sides of the beam skeleton width so as to form a pair on both sides of the beam skeleton. It is possible to realize a vertical member (vertical steel material) having high rigidity and high rigidity, which is particularly excellent in resistance to twisting.

Further, in the seismic ceiling structure of a building rigidly joined to the beam frame of the attic space according to the new aspect of the present invention, the metal fitting directly attached to the ceiling material is via a connecting steel material having a hole for height adjustment. The wall portion of the metal directly attached to the ceiling material is joined to the vertical steel material.
According to this aspect, in addition to the above-mentioned effects, the ceiling material directly attached metal fittings joined to the ceiling material are joined to the vertical steel material rigidly joined to the beam skeleton via a connecting steel material having holes for height adjustment. By doing so, it is possible to realize a seismic ceiling structure in which the ceiling surface is provided at the initially planned ceiling height position even if the ceiling material is joined with the metal fittings directly attached to the ceiling material in advance.

According to the present invention, it is possible to provide a seismic-resistant ceiling structure having high rigidity and high seismic safety by using a small number of parts using a steel material having a relatively small cross-sectional area.

The seismic ceiling structure of the first embodiment of the present invention is shown, (a) is a front vertical sectional view, and (b) is a side view. It is a horizontal sectional view of the seismic ceiling structure of the 1st Embodiment of this invention at different height positions. (A) is a plan view and (b) is a side view of the connecting steel material in the seismic ceiling structure of the first embodiment of the present invention. It is a perspective view of the metal fitting directly attached to the ceiling material in the seismic ceiling structure of the 1st Embodiment of this invention. The seismic ceiling structure according to the first modification of the present invention is shown, (a) is a front vertical sectional view, and (b) is a side view. It is a horizontal sectional view of the seismic ceiling structure according to the modification 1 of this invention at different height positions. It is a perspective view of the metal fitting directly attached to the ceiling material of the earthquake-resistant ceiling structure according to the modification 1 of this invention. A seismic ceiling structure according to a second modification of the present invention is shown, (a) is a front vertical sectional view, and (b) is a side view. It is (a) (b) horizontal sectional view at different height position, (c) perspective view of the metal fitting directly attached to the ceiling material which shows the seismic ceiling structure according to the modification 1 of this invention. It is a top view of the seismic ceiling structure of the 2nd Embodiment of this invention. (A) is an enlarged perspective view and (b) is a side view of the seismic ceiling structure of the second embodiment of the present invention. It is explanatory drawing which shows the conventional suspended ceiling base structure. It is explanatory drawing which shows the suspension structure of the conventional ceiling.

In the seismic ceiling structure of the present invention, the lower end of the vertical steel material rigidly joined to one side surface or both side surfaces of the beam member is lowered to the vicinity of the ceiling surface without resisting the horizontal load acting on the ceiling material by the brace. It is a ceiling structure that is joined to the metal directly attached to the ceiling material that is joined to the material. The feature of the present invention is that it is not necessary to install diagonal members (braces) in the attic space, and the ceiling structure can be made earthquake-resistant without limiting the arrangement position of equipment and equipment piping provided in the attic space as much as possible. it can.
In the present invention, as a hanging connection method between the ceiling material and the beam skeleton in the attic space, a pair of left and right pair type metal fittings directly attached to the ceiling material and rigidly joined to both side surfaces of the beam skeleton. The first embodiment (FIGS. 1 to 4) in which the connecting member is arranged between the vertical steel material, and the modified example 1 (FIG. 5) of the ceiling material directly attached metal fitting and the vertical steel material excluding the connecting member according to the first embodiment. ~ FIG. 7), and there are deformation examples 2 (FIGS. 8 and 9) of the metal directly attached to the ceiling material and the vertical steel material rigidly joined to only one side surface of the beam frame.
Further, in the second embodiment, the metal fittings directly attached to the ceiling material bonded to the ceiling material are supported by a PC steel material erected in the space behind the ceiling (FIGS. 10 and 11).
Hereinafter, the content of the invention will be described with reference to the drawings in the order of the first embodiment, the modified example 1, the modified example 2, and the second embodiment.

(First Embodiment)
FIG. 1A is a front vertical sectional view of the seismic ceiling structure 1 shown as an embodiment of the present invention, and FIG. 1B is a side view. More specifically, FIG. 1A is a sectional view taken along the line AA of FIG. 1B. 2A, 2B, and 2C are horizontal cross-sectional views taken along the line BB, CC, and DD of FIGS. 1A and 1B, respectively.
The seismic ceiling structure 1 is provided in the attic space S formed between the lower surface 2a of the floor skeleton 2 on the upper floor and the upper surface 4a of the ceiling material 4 located below the floor skeleton 2 on the upper floor. , The ceiling material 4 is joined to the floor skeleton 2 on the upper floor. More strictly, in the present embodiment, the seismic ceiling structure 1 is rigidly joined to the beam skeleton 3 of the attic space S protruding downward from the lower surface 2a of the floor skeleton 2 on the upper floor. In the present embodiment, the beam skeleton 3 is made of reinforced concrete, but it may be made of steel-framed reinforced concrete.
The seismic ceiling structure 1 includes a pair of left and right vertical steel materials 5 rigidly joined to both side surfaces 3a of the beam frame 3, a ceiling material directly attached metal fitting 7 installed on the upper surface 4a of the ceiling material 4, a vertical steel material 5 and a ceiling material. It includes a connecting steel material 6 for joining the direct-attached hardware 7. Rigid joining here means joining vertical steel materials at multiple positions in the vertical direction on the beam frame surface using anchor bolts, and fixing the vertical steel materials in a pin-joined state that allows horizontal movement. Instead, it is defined as a joined state in which the vertical steel material is restrained so that it does not move in the horizontal and vertical directions.
Hereinafter, each of these members will be described in detail.

The vertical steel material 5 is, for example, a long steel material formed by cutting channel steel. The vertical steel material 5 has a rectangular web 5a and two flanges that are joined perpendicularly to the web 5a at both ends extending in the length direction of the web 5a, that is, in the vertical direction Z in FIG. It has 5b. Each of the two flanges 5b is joined so as to rise from the web 5a in the same direction.
In FIG. 1A, the beam skeleton 3 is provided so as to extend in the depth direction Y of the paper surface, and the direction X orthogonal to the extending direction Y of the beam skeleton 3 in the horizontal plane, that is, the beam skeleton 3 It is provided with two side surfaces 3a facing opposite sides in the width direction X. In the vertical steel material 5, the outer surface 5d, which is the surface of the web 5a opposite to the direction in which the flange 5b rises, is in contact with and along the side surface 3a with respect to each of the two side surfaces 3a. The web 5a is provided so that the length direction coincides with the vertical direction Z.
As shown in FIG. 2A, a beam fixing hole 5e is provided in a portion of the web 5a of the vertical steel material 5 that contacts the side surface 3a of the beam skeleton 3. The beam fixing holes 5e are provided at three locations at intervals in the length direction of the web 5a.
Anchor bolts 10 having a male screw portion formed on the surface are provided so as to insert the beam fixing holes 5e corresponding to each of the beam fixing holes 5e. One end 10a of the anchor bolt 10 is driven into the concrete forming the beam skeleton 3, and the protruding end 10b at the other end is a space between two flanges 5b of the vertical steel material 5 through the beam fixing hole 5e. It protrudes into. A nut 11 is doubly screwed to the protruding end 10b.

As shown in FIG. 3, the connecting steel material 6 is, for example, a steel material formed by cutting the C channel. The connecting steel material 6 has a rectangular web 6a, two flanges 6b and two flanges 6b, which are joined perpendicularly to the web 6a at both ends extending in the length direction of the web 6a. It has two lips 6c extending in opposite directions from the end opposite to the web 6a. Each of the two flanges 6b is joined so as to rise from the web 6a in the same direction. The web 6a has a width substantially equal to that of the web 5a of the vertical steel material 5.
As shown in FIGS. 1 and 2B, the connecting steel material 6 is the outer surface of the web 6a on the side opposite to the direction in which the flange 6b rises with respect to each of the two vertical steel materials 5. 6d is provided so as to be in contact with and along the outer surface 5d of the web 5a of the vertical steel material 5 and so that the length direction of the web 6a coincides with the vertical direction Z. The connecting steel material 6 is provided near the lower end 5g of the vertical steel material 5, and the lower side of the connecting steel material 6 is provided so as to project downward from the lower end 5g of the vertical steel material 5.
As shown in FIG. 3B, the portion of the web 6a of the connecting steel material 6 in contact with the web 5a of the vertical steel material 5 is located near the upper end 6h of the connecting steel material 6 at the center position in the width direction of the web 6a. Below this, fixing holes (height adjustment holes) 6e, which are elongated holes extending in the vertical direction, are provided at two locations that sandwich the central position in the horizontal direction, for a total of three locations. ..
As shown in FIG. 2B, a connecting member fixing hole 5f is provided at a position corresponding to the above-mentioned fixing hole 6e in the vicinity of the lower end 5g of the web 5a of the vertical steel material 5, and the connecting steel material 6 The fixing hole 6e and the connecting member fixing hole 5f of the vertical steel material 5 are provided so as to communicate with each other. The hexagon bolt 12 is provided so that the shaft portion 12a of the hexagon bolt 12 is inserted between the holes 6e and 5f from the connecting steel material 6 side. A nut 13 is screwed to the shaft portion 12a of the hexagon bolt 12 from the vertical steel material 5 side.

The metal fitting 7 directly attached to the ceiling material has a U-shape that opens upward and is composed of a first wall portion and a second wall portion that extend upward and a horizontal portion that fixes the ceiling material. Details will be described below.
FIG. 4 is a perspective view of the metal fitting 7 directly attached to the ceiling material. The horizontal portion 7a is a substantially rectangular steel plate having four corners cut out in a rectangular shape. Horizontal portion 7a has a length in the longitudinal direction X ₁ is formed so as to be substantially equal to the width of Ryomukurotai 3 in the direction X in FIG. 1 (a). The two long sides 7b extending in the longitudinal direction X ₁ of the horizontal portion 7a, respectively, side wall portions 7c so as to rise from the horizontal portion 7a vertically are joined.
Of the horizontal portion 7a, the two short sides 7d extending in the width direction Y ₁ perpendicular to the longitudinal direction X ₁ in the horizontal plane, respectively, so as to rise from the horizontal portion 7a vertically, the first wall of the rectangular The portion 7e and the second wall portion 7f are joined. The first wall portion 7e and the second wall portion 7f, the length in the width direction Y ₁ of the horizontal portion 7a is formed so that the width substantially equal to the web 6a of the connecting steel 6 shown in FIG. 3 ..
The first wall portion 7e and the second wall portion 7f, in each side 7g extending in the vertical direction Z ₁ are each to be perpendicular to the first wall portion 7e and the second wall portion 7f, Moreover, the rectangular reinforcing plate portion 7h is joined so as to extend to the outside, that is, in the direction opposite to the horizontal portion 7a.
A plurality of ceiling material fixing holes 7i are provided in the horizontal portion 7a. Further, a plurality of connecting steel material fixing holes 7j are provided in the first wall portion 7e and the second wall portion 7f.
The ceiling material direct-attached metal fitting 7 is formed by making a notch in a single steel plate having fixing holes 7i and 7j, for example, having a thickness of about 1.6 mm, and bending it.

As shown in FIGS. 1 and 2 (c), the ceiling material direct-attached metal fitting 7 has a length direction X ₁ , a width direction Y ₁ , and a vertical direction Z ₁ of the ceiling material direct-attached metal fitting 7, respectively. It is oriented so as to coincide with the X, the direction Y, and the vertical direction Z, and is joined to the connecting steel material 6.
More specifically, the ceiling material direct-attached metal fitting 7 is on the side opposite to the direction in which the reinforcing plate portion 7h extends on the first wall portion 7e and the second wall portion 7f with respect to each of the two connecting steel materials 6. The inner surface 7k, which is the surface of the connecting steel material 6, is positioned along the portion of the outer surface 6d of the web 6a of the connecting steel material 6 that protrudes downward from the lower end 5g of the vertical steel material 5.
Then, the drilling screw 14 is screwed into the connecting steel material 6 by inserting the connecting steel material fixing hole 7j from the first wall portion 7e and the second wall portion 7f side toward the connecting steel material 6. It is joined.

As shown in FIG. 1, the ceiling material 4 is positioned so that the lower surface of the horizontal portion 7a of the ceiling material direct-attached metal fitting 7 and the upper surface 4a of the ceiling material 4 are in contact with each other, and the ceiling material direct-attached metal fitting 7 is horizontal. As shown in FIG. 2C, from above the portion 7a, the ceiling material fixing hole 7i is inserted and the tapping screw 15 is screwed into the ceiling material directly attached to the metal fitting 7.

Next, the method of constructing the seismic ceiling structure 1 will be described with reference to FIGS. 1 to 4.
First, anchor bolts 10 are driven into each of the two side surfaces 3a of the beam skeleton 3.
Next, the vertical steel material 5 is moved relative to the beam skeleton 3, and the anchor bolts 10 fixed to the beam skeleton 3 are inserted into the beam fixing holes 5e of the web 5a of the vertical steel material 5 while being inserted into the beam fixing holes 5e. 5 so that the outer surface 5d of the web 5a contacts the side surface 3a and follows each of the two side surfaces 3a of the beam skeleton 3, and the length direction of the web 5a coincides with the vertical direction Z. To position. Then, by screwing the nut 11 to the protruding end 10b of the anchor bolt 10, each vertical steel material 5 is fixed to both side surfaces 3a of the beam skeleton 3.
Further, the connecting steel material 6 is aligned with the outer surface 6d of the web 6a in contact with the outer surface 5d of the web 5a of the vertical steel material 5 with respect to each vertical steel material 5, and the length direction of the web 6a is aligned. Position it so that it coincides with the vertical direction Z. Then, the shaft portion 12a of the hexagon bolt 12 is inserted from the connecting steel material 6 side into the fixing hole 6e of the connecting steel material 6 and the connecting member fixing hole 5f of the vertical steel material 5, and the nut 13 is screwed from the vertical steel material 5 side. The connecting steel material 6 is fixed to each vertical steel material 5 by the above method.

Then, the metal fitting 7 directly attached to the ceiling material is attached to the inner surface 7k of the first wall portion 7e and the second wall portion 7f from the lower end 5g of the vertical steel material 5 of each of the outer surfaces 6d of the web 6a of the two connecting steel materials 6. Position it so that it contacts and follows the downwardly protruding part. Then, by inserting the connecting steel material fixing hole 7j from the first wall portion 7e and the second wall portion 7f side toward the connecting steel material 6 and screwing the drilling screw 14, the ceiling material direct-attached metal fitting 7 is attached to the connecting steel material 6. Fix it.
Finally, the ceiling material 4 is positioned so that the lower surface of the horizontal portion 7a of the ceiling material direct-attached metal fitting 7 and the upper surface 4a of the ceiling material 4 are in contact with each other, and from above the horizontal portion 7a of the ceiling material direct-attached metal fitting 7. The ceiling material 4 is fixed to the metal fitting 7 directly attached to the ceiling material by inserting the ceiling material fixing hole 7i and screwing the tapping screw 15.

Next, the effect of the seismic ceiling structure 1 will be described.

In the seismic ceiling structure 1 as described above, the vertical steel material 5 that supports the ceiling material 4 is rigidly joined to the side surface 3a of the beam skeleton 3 that protrudes downward from the building skeleton such as the floor skeleton 2 on the upper floor. That is, the vertical steel material 5 is provided along the side surface 3a of the beam skeleton 3, and is joined to the beam skeleton 3 not by pin joining but by rigid joining by anchor bolts 10 at a plurality of positions in the vertical direction.
Further, the vertical steel material 5 is installed between the ceiling surface and the side surface 3a of the beam skeleton 3 on the floor, which has a shorter section length than between the ceiling surface and the lower surface 2a of the floor skeleton 2 on the upper floor. Then, the amount of bending moment acting on the joint portion with the building skeleton (beam skeleton 3) to which the ceiling material 4 is attached, which is calculated by multiplying the horizontal load acting on the ceiling material 4 by the length of the vertical steel material, is reduced. There is. More specifically, as shown in FIG. 1 (a), the length L ₁ of the vertical steel protruding downward from the junction the lower end of the lower surface 3b That Ryomukurotai 3 Ryomukurotai 3 with vertical steel 5, the building structures the lower surface 2a, perpendicular to the lower surface 2a, than the length L ₂ of the vertical steel in the case of joining the vertical steel is shorter by the amount of RyoNaru H of Ryomukurotai 3 projecting downward. As a result, the amount of bending moment applied to the joint portion, which is calculated by multiplying the horizontal load acting on the ceiling material 4 by the length of the vertical steel material protruding downward from the joint portion, is reduced. As a result, the seismic ceiling structure 1 has high rigidity. Further, the ceiling material 4 is joined to the vertical steel material 5 rigidly joined to the beam frame 3 of the attic space S with a metal fitting 7 directly attached to the ceiling material, and the seismic ceiling structure 1 is realized with a small number of parts. ..
In other words, in the seismic ceiling structure 1, the vertical steel material 5 is rigidly joined to the beam skeleton 3 and integrated, so that the beam skeleton 3 is lowered to the lower end portion 5 g of the vertical steel material 5 via the vertical steel material 5. It can be read as extending to the side, and the ceiling material direct-attached metal fitting 7 is joined to the beam skeleton 3 extending to the lower end portion 5 g of the vertical steel material 5.
Further, the ceiling material 4 is joined to a pair of left and right vertical steel materials 5 via a metal fitting 7 directly attached to the ceiling material and a connecting steel material 6. That is, the ceiling material 4 is joined by two pairs of left and right vertical steel materials 5 via a metal fitting 7 directly attached to the ceiling material, and has a structure capable of resisting a horizontal load acting on the ceiling material 4.
Further, since the vertical steel material 5 is joined to the beam frame 3 by anchor bolts 10 at a plurality of height positions, it can sufficiently oppose the horizontal load acting on the ceiling material 4.
The above effects are synergistic, and it becomes possible to realize a seismic ceiling structure that can realize high rigidity and high strength.

Further, the seismic ceiling structure 1 can realize high rigidity and high strength as described above. Therefore, it is not necessary to install a brace material for bearing a horizontal load, and the cross-sectional area of the vertical steel material 5 for resisting the amount of bending moment acting can be reduced. Further, the structure of the seismic ceiling structure 1 is simple and the number of parts is small. From the above, it is possible to reduce the amount of steel material and reduce the construction cost.

Further, since the seismic ceiling structure 1 does not need to install a brace material as described above, interference with equipment and equipment piping installed in the attic space S is reduced, and design and construction are facilitated. ..

Further, a vertical steel material in which the ceiling material direct-attached metal fitting 7 joined to the ceiling material 4 is rigidly joined to the beam skeleton 3 via a connecting steel material 6 provided with a fixing hole (height adjustment hole) 6e which is a long hole. By joining with 5, even if the ceiling material 4 is joined with the ceiling material directly attached metal fitting 7 in advance, it is possible to realize the earthquake-resistant ceiling structure 1 having the ceiling surface at the initially planned ceiling height position. ..

(Modification example 1)
5 and 7 show the seismic ceiling structure according to the first modification of the first embodiment. FIG. 5A is a front vertical sectional view of the seismic ceiling structure 30 shown as a modification 1, and FIG. 5B is a side view. More specifically, FIG. 5 (a) is a cross-sectional view taken along the line EE of FIG. 5 (b). 6 (a), (b), and (c) are horizontal cross-sectional views of FIGS. 5 (a) and 5 (b) in the FF, GG, and HH portions, respectively. FIG. 7 is a perspective view of a metal fitting 17 directly attached to the ceiling material used in the seismic ceiling structure 30. The seismic ceiling structure of the first modification excludes the connecting member in the first embodiment, and the vertical steel material 5 rigidly joined to the beam frame 3 and the ceiling direct-attached metal fitting 17 joined to the ceiling material 4 are directly joined. It was made to do.
The configuration according to the first modification and its structural features will be described by comparing with the first embodiment and paying attention to the differences.
In the seismic ceiling structure of the first modification, as shown in FIGS. 5 to 7, the ceiling material 4 and the beam skeleton 3 of the ceiling space S are a pair of left and right vertical steel materials rigidly joined to both side surfaces 3a of the beam skeleton 3. The ceiling direct-attached metal fitting 17 joined to the ceiling material 4 is joined to 5.
The ceiling material direct-attached metal fitting 17 has a U-shape open upward, which is composed of a first wall portion 17e and a second wall portion 17f extending upward, and a horizontal portion 17a for fixing the ceiling material 4.
The ceiling-mounted hardware 17 is formed by fixing the height-adjusting elongated holes (height-adjusting holes) 17j provided in the wall portions 17e and 17f of the ceiling-mounted hardware 17 and the connecting member provided in the vertical steel material 5. A bolt 12 is passed through the hole 5f, the height position of the bolt 12 penetrating the elongated hole 17j for height adjustment is adjusted, and then nuts 13 provided at both ends of the bolt 12 are tightened to tighten the ceiling. The direct-attached metal fitting 17 and the vertical steel material 5 were joined.

According to the first modification, elongated holes 17j are provided in the wall portions 17e and 17f of the metal fitting 17 directly attached to the ceiling, and both are joined to each other while adjusting the height with the vertical steel material 5 rigidly joined to the beam frame 3. As a result, the connecting members constituting the seismic ceiling structure of the first embodiment can be omitted, the number of members can be reduced, and the work process can be shortened.
Further, in the first modification, the ceiling material 4 and the beam skeleton are joined to the beam skeleton 3 by joining the ceiling material direct-attached metal fitting 17 joined to the ceiling material 4 without arranging the connecting member. The length of the section between 3 and 3 becomes shorter, and the amount of bending moment acting on the joint portion of the beam skeleton 3 to which the ceiling structure is joined becomes smaller. Therefore, seismic safety can be further enhanced.
In the case of constructing the seismic ceiling structure 30 of the first modification, the ceiling material 4 to which the ceiling material direct-attached metal fitting 17 is bonded in advance to the lower end 5 g side of the vertical steel material 5 rigidly joined to the beam frame 3 is described above. A method of tightening and fixing while checking the height position of the bolt 12 penetrating the elongated holes 17j provided in the wall portions 17e and 17f of the metal fitting 17 directly attached to the ceiling material, and the ceiling material directly attached to the lower end 5 g side of the vertical steel material 5. After attaching the metal fitting 17, the ceiling material 4 may be attached to the horizontal portion 17a of the metal fitting 17 directly attached to the ceiling material.
In the method of constructing the seismic ceiling structure 30 of the first modification in both directions, the ceiling material direct-attached metal fitting 17 and the vertical steel material 5 are joined via a long hole 17j for adjusting the height of the ceiling material direct-attached metal fitting 17. The ceiling material 4 can be easily attached at a predetermined height position.
It goes without saying that the seismic ceiling structure 30 of the modified example 1 similarly exerts other effects of the seismic ceiling structure 1 of the first embodiment.

(Modification 2)
8 and 9 show the seismic ceiling structure according to the second modification of the first embodiment. FIG. 8A is a front vertical sectional view of the seismic ceiling structure 40 shown as a modification 2, and FIG. 8B is a side view. More specifically, FIG. 8 (a) is a cross-sectional view taken along the line II of FIG. 8 (b). 9 (a) and 9 (b) are horizontal cross-sectional views of the JJ and KK portions of FIGS. 8 (a) and 8 (b), respectively. FIG. 9C is a perspective view of a metal fitting 37 directly attached to the ceiling material used in the seismic ceiling structure 40. Deformation example 2 The seismic ceiling structure has a vertical steel material 5 rigidly joined only to one side surface 3a of the beam frame 3, and a metal fitting directly attached to the ceiling joined to the ceiling material 4 at the lowermost end 5 g of the vertical steel material 5. 37 is provided.
The configuration according to the second modification and its structural features will be described in comparison with the first embodiment and the first modification, focusing on the differences.
In the seismic ceiling structure 40 of the second modification, as shown in FIGS. 8 and 9, the ceiling material 4 and the beam skeleton 3 of the ceiling space S are rigidly joined to only one side surface 3a of the beam skeleton 3. Inverted T-shaped metal fittings 37 directly attached to the ceiling, which are joined to the ceiling material 4, are joined to the ceiling material 4.
The metal fitting 37 directly attached to the ceiling material is composed of a wall portion 37e extending upward and a horizontal portion 37a for fixing the ceiling material 4.
Similar to the first modification, the wall portion 37e of the metal fitting 37 directly attached to the ceiling is provided with a long hole (height adjustment hole) 37j for height adjustment, and the bolt 12 inserted through the long hole 37j is used. It is joined to the vertical steel material 5.
Further, as shown in FIG. 9C, the metal fitting 37 directly attached to the ceiling has horizontal portions 37a formed on both sides of the wall portion 37e, and the ceiling material 4 is provided directly below the horizontal portion 37a, and the horizontal portion is provided. The ceiling material 4 is fixed by tapping screws that penetrate the ceiling material fixing holes provided in 37a.

In the metal fitting 37 directly attached to the ceiling of the second modification, since the horizontal portions 37a are provided on both sides of the wall portion 37e, the ceiling material 4 is attached to the horizontal portion 37a without applying an eccentric load to the metal fitting 37 directly attached to the ceiling. Can be joined.
It goes without saying that the seismic ceiling structure 40 of the modified example 1 similarly exerts other effects that the seismic ceiling structure 1 of the first embodiment has.

(Second Embodiment)
10 and 11 show the configuration and features of the seismic ceiling structure 20 according to the second embodiment.
FIG. 10 is a plan view of the seismic ceiling structure 20 looking down from the space behind the ceiling. 11 (a) is an enlarged perspective view of the M portion of FIG. 10, and FIG. 11 (b) is a side view of FIG. 11 (a).
The seismic ceiling structure 20 includes first and second PC steel materials 22 and 23 fixed to the wall frame 21 (21A, 21B, 21C, 21D) of the building. The ceiling material 26 is fixed to the wall skeleton 21 formed of concrete via the first and second PC steel materials 22 and 23 and the ceiling material directly attached metal fitting 27 described later. The PC steel material referred to here is a PC steel wire, a PC steel stranded wire, and a threaded reinforcing bar.

The first PC steel 22 Kabemukurotai 21A facing in the horizontal direction _{X 2} in FIG. 10, which is bridged between 21B. In the present embodiment, the first PC steel material 22 is, for example, a threaded reinforcing bar having a diameter of 20 mm. The end of the first PC steel material 22 on the wall skeleton 21A side is joined to anchor bolts 24 fixed to the wall skeleton 21A. The end portion on the wall skeleton 21B side is tensioned by a PC fixing tool 25 provided in the vicinity of the wall skeleton 21B, and is joined to an anchor bolt 24 fixed to the wall skeleton 21B. A plurality of the first PC steel materials 22 are provided at intervals _{in the vertical direction Y 2 in FIG.}
Second PC steel 23, Kabemukurotai 21C facing in the vertical direction _{Y 2} in FIG. 10, which is bridged between 21D. In the present embodiment, the second PC steel material 23 is, for example, a PC steel wire or a PC steel stranded wire having a diameter smaller than that of the first PC steel material 22. The end of the second PC steel material 23 on the wall skeleton 21D side is joined to the anchor bolt 24 fixed to the wall skeleton 21D. The end portion on the wall skeleton 21C side is tensioned by a PC fixing tool 25 provided in the vicinity of the wall skeleton 21C and is joined to an anchor bolt 24 fixed to the wall skeleton 21C. A plurality of the second PC steel materials 23 are provided at intervals _{in the left-right direction X 2 in FIG.}
As shown in FIG. 11, the second PC steel material 23 is orthogonal to the first PC steel material 22 below the first PC steel material 22 to the extent that it comes into contact with the first PC steel material 22. It is provided.

The ceiling material 26 is fixed to the first PC steel material 22 via a metal fitting 27 directly attached to the ceiling material. As shown in FIG. 11, the ceiling material direct-attached metal fitting 27 is composed of a first wall portion 27e and a second wall portion 27f extending upward, and a horizontal portion 27a for fixing the ceiling material 26.
The horizontal portion 27a has a substantially rectangular shape, and the first wall portion rises vertically upward from each of the two short sides of the horizontal portion 27a located on opposite sides of the horizontal portion 27a. The 27e and the second wall portion 27f are joined. As a result, the metal fitting 27 directly attached to the ceiling material has a U-shape that opens upward.
The first wall portion 27e and the second wall portion 27f, respectively, so as to extend in the vertical direction _{Z 2} long hole 27l is opened.
A plurality of ceiling material fixing holes are provided in the horizontal portion 7a.

Ceiling material Brazed hardware 27, the length direction of the horizontal portion 27a, it is oriented such that the first PC steel 22 coincides with the direction X ₂ which are bridged. The first PC steel material 22 is inserted into the elongated holes 27l formed in each of the first wall portion 27e and the second wall portion 27f of the metal fitting 27 directly attached to the ceiling material. Nuts 28 are provided on both side surfaces of the first wall portion 27e and the second wall portion 27f so as to sandwich the wall portions 27e and 27f. The nut 28 is screwed to a male threaded portion formed on the surface of the first PC steel material 22 which is a threaded reinforcing bar, and each of the wall portions 27e and 27f is connected to the wall portions 27e from both side surfaces thereof. By tightening toward 27f, the ceiling material direct-attached metal fitting 27 is fixed to the first PC steel material 22.
The second PC steel material 23 is positioned so as to pass between the first wall portion 27e and the second wall portion 27f of the ceiling material direct-attached metal fitting 27 and cross the horizontal portion 27a in the width direction.

The ceiling material 26 is positioned so that the lower surface of the horizontal portion 27a of the ceiling material direct-attached metal fitting 27 and the upper surface 26a of the ceiling material 26 are in contact with each other, and the ceiling material 26 is positioned from above the horizontal portion 27a of the ceiling material direct-attached metal fitting 27. By inserting the fixing hole and screwing the tapping screw 29, it is fixed to the metal fitting 27 directly attached to the ceiling material.

Next, the method of constructing the seismic ceiling structure 20 will be described with reference to FIGS. 10 and 11.
First, the anchor bolts 24 are driven into the wall frame 21 (21A, 21B, 21C, 21D).
Next, the first PC steel material 22 is inserted into a plurality of ceiling material direct-attached metal fittings 27 and nuts 28. Four nuts 28 are prepared for each ceiling material direct-attached metal fitting 27, and the wall portions 27e and 27f are positioned so as to be sandwiched from both side surfaces, and the first PC steel material 22 is inserted therethrough.
Thus the end of the first PC steel 22 is inserted through the ceiling material Brazed hardware 27 and the nut 28, Kabemukurotai 21A facing in the horizontal direction _{X 2} in FIG. 10, in the 21B, one Kabemukurotai 21A After joining to the anchor bolt 24 fixed to the wall skeleton 24, tension is applied by pulling the other end with the PC fixing tool 25 to join to the anchor bolt 24 fixed to the wall skeleton 21B facing the wall skeleton 21A.
Further, one end of the second PC steel 23, Kabemukurotai 21C facing in the vertical direction _{Y 2} in FIG. 10, in the 21D, after bonding the anchor bolt 24 which is fixed to one Kabemukurotai 21D, the other end Is pulled by the PC fixing tool 25 to give tension to the anchor bolts 24 fixed to the wall skeleton 21C facing the wall skeleton 21D. At this time, the second PC steel material 23 is positioned below the first PC steel material 22 so as to be orthogonal to the first PC steel material 22 so as to come into contact with the first PC steel material 22.

Then, the ceiling material 26 is positioned so that the lower surface of the horizontal portion 27a of the ceiling material direct-attached metal fitting 27 and the upper surface 26a of the ceiling material 26 are in contact with each other, and the ceiling is placed from above the horizontal portion 27a of the ceiling material direct-attached metal fitting 27. The ceiling material 26 is fixed to the metal fitting 27 directly attached to the ceiling material by inserting the material fixing hole and screwing the tapping screw 29.
Finally, the relative height position of the ceiling material direct-attached metal fitting 27 with respect to the first PC steel material 22 fixed to the wall frame 21 is finely adjusted by moving the ceiling material direct-attached metal fitting 27 up and down. The first PC steel 22 is inserted, a ceiling material first wall portion 27e and the hole which is opened to the second wall portion 27f of the direct mounting hardware 27, a long hole 27l extending in the vertical direction Z ₂ Therefore, such a fine adjustment of the height position is possible by changing the insertion position of the first PC steel material 22 in the elongated hole 27l in the vertical direction. After adjusting the height position, the nut 28 is tightened toward both side surfaces of the wall portions 27e and 27f, and the ceiling material direct-attached metal fitting 27 is fixed to the first PC steel material 22.

Next, the effect of the seismic ceiling structure 20 will be described.

In the seismic ceiling structure 20 as described above, the first PC steel material 22 that supports the ceiling material 26 is rigidly joined to the wall skeleton 21 by being tensioned by the PC fixing tool 25.
Further, the first PC steel material 22 that supports the ceiling material 26 is supported from below by a second PC steel material 23 that is provided so as to be orthogonal to the first PC steel material 22.
Further, the ceiling material 26 is joined to the first PC steel material 22 slightly above the ceiling material 26 via a metal fitting 27 directly attached to the ceiling material. That is, the joint between the first PC steel 22 and the ceiling member Brazed hardware 27 which supports the ceiling material 26, the distance L ₃ in the height direction of the ceiling material 26 is very small. As a result, the amount of bending moment applied to the joint portion is reduced, and the structure is capable of countering the horizontal load acting on the ceiling material 26.
By synergizing the above effects, the ceiling material direct-attached metal fitting 27 using a steel material having a relatively small cross-sectional area and the PC steel material 22 erected in at least one direction through the ceiling material direct-attached metal fitting 27. Therefore, it is possible to provide a seismic ceiling structure having high seismic safety.

Further, the seismic ceiling structure 20 can realize high rigidity and high strength as described above. Therefore, it is not necessary to install a brace material in the space behind the ceiling in order to bear the horizontal load. Further, the structure of the seismic ceiling structure 20 is simple and the number of parts is small. From the above, it is possible to reduce the amount of steel material and reduce the construction cost.

Further, since it is not necessary to install the brace material in the seismic ceiling structure 20 as described above, the interference with the equipment and the equipment piping installed in the space behind the ceiling is reduced, and the design and construction are facilitated.

The seismic ceiling structure of the present invention is not limited to the above-described embodiments and modifications described with reference to the drawings, and various other modifications can be considered within the technical scope thereof.

For example, the above-mentioned seismic ceiling structures 1 and 20 are of course applicable as a structure when constructing a new building, but for example, for the purpose of reinforcing the existing ceiling structure described with reference to FIG. 12 and the like. , While keeping the existing ceiling material, the ceiling material direct-attached metal fitting is attached to the upper surface of the ceiling material, and the ceiling material direct-attached metal fitting is attached to the beam skeleton according to the first embodiment or the modified examples 1, 2 or 2. It may be supported by a vertical steel material rigidly joined to the ceiling or a PC steel material fixed to the wall frame.
In addition, if there are places where there are few beams protruding downward from the floor frame on the upper floor and the ceiling material cannot be sufficiently supported by the seismic ceiling structure 1, the seismic ceiling structure 20 is partially introduced and protruded. In a place where there are few beams, the seismic ceiling structure 1 and the seismic ceiling structure 20 may be used in combination, such as supporting the ceiling material with a PC steel material.

In addition to this, as long as the gist of the present invention is not deviated, the configurations given in each of the above-described embodiments and modifications can be selected or appropriately changed to other configurations.

S Attic space 5 Vertical steel material 1 Seismic ceiling structure 6 Connecting steel material 2 Floor skeleton on the upper floor 6e Fixing hole (hole for height adjustment)
3 Beam frame 7, 17, 27, 37 Ceiling material directly attached hardware 3a Side surface 7a Horizontal part 4 Ceiling material 7e First wall part 4a Top surface 7f Second wall part

Claims (2)

It is a seismic ceiling structure of a building that is rigidly joined to the beam frame in the attic space.
The beam skeleton is made of reinforced concrete or steel-framed reinforced concrete, is formed in a rectangular shape when viewed in a vertical cross section, and has a lower surface and side surfaces that rise upward from both ends of the lower surface.
The ceiling material provided at the top of the living space of the building and
A vertical steel material that is rigidly joined to the side surface of the beam skeleton, extends downward from the side surface, and is provided so as to project from the lower surface.
It is provided with a metal fitting directly attached to the ceiling material for joining the vertical steel material and the ceiling material.
The metal fitting directly attached to the ceiling material is composed of a wall portion extending upward to be joined to the vertical steel material and a horizontal portion for fixing the ceiling material .
The vertical steel material is a steel material having a web and a flange.
The ceiling material direct-attached metal fitting has a seismic ceiling structure in which the wall portion of the ceiling material direct-attached metal fitting and the vertical steel material are joined via a connecting steel material having a height adjusting hole. The seismic ceiling structure according to claim 1, wherein the vertical steel materials are provided as a pair on the left and right sides of the beam skeleton on both sides.

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