RU2793696C1 - Connecting structure between partitions and floor plate and method for its manufacture - Google Patents

Abstract

FIELD: connecting structures.

SUBSTANCE: connecting structure between partitions and a floor slab and a method for manufacturing a connecting structure are proposed, in which the material of the walls facing the vertical compartment is precisely attached to the racks without any deformation of the guides and damage to the connecting structure, even if pressing forces are applied from the racks to the guides. A connecting structure 100 is provided, which is configured to connect the first partition 30 and the second partition 40 to the floor slab 20. The first partition 30 and the second partition 40 are connected to the floor slab 20 and separate the vertical compartment 10 from the room 13 on the top floor and the room 15 on the lower floor, which are located next to the vertical compartment 10 and above and below the floor slab 20. The bottom guide 31, configured to accommodate the lower end of the first rack 32, is placed on the floor slab 20. An upper guide 33, configured to receive the upper end of the second rack 34, which forms the second partition 40, is placed below the floor slab 20. The first wall material 50 is attached to the first rack 32 via the first flashing 80A, and attached to the second rack 32 via the second flashing 80B. The first wall material 50 extends from the first rack 32 to the second rack 24 in the vertical compartment.

EFFECT: material of the walls facing the vertical compartment is precisely attached to the racks without any deformation of the guides and damage to the connecting structure, even if pressing forces are applied from the racks to the guides.

10 cl, 5 dwg

Description

The field of technology to which the invention belongs

[0001] The present description relates to a connecting structure between partitions and a floor slab and to a method for its manufacture.

State of the art

[0002] The fire prevention and fire resistance characteristics of building walls are determined by the building standards law, and wall structures and materials must comply with the interior decoration restrictions and fire prevention and fire resistance characteristics specified by the building standards law. For example, based on the use and size of buildings and zone designations, the Building Standards Act defines buildings as fire-resistant buildings or quasi-fire-resistant buildings. In addition, in terms of the application and size of buildings, prevention of fire spread, evacuation, smoke, fire fighting, etc., the building work standards law determines the fire prevention and fire resistance characteristics related to interior decoration materials, interior wall structures, structures of building components, spaces for pipe placement, etc. According to the current building standards law, the incombustibility of the interior finishing materials of buildings is divided into predetermined incombustibility classes (non-combustible materials, quasi-incombustible materials and fire retardant materials). In addition, the fire resistance of building walls is classified into predefined types of structures (fire-resistant structure, quasi-fire-resistant structure, fire-prevention structure, and quasi-fire-prevention structure).

[0003] Additionally, from the point of view of reducing the weight of the building, a fireproof partition formed by a dry method is used as a partition between the vertical compartment and its adjacent spaces. In a fire-resistant partition, fire-resistant panels such as gypsum boards or calcium silicate panels are attached to both surfaces of light thin-walled steel posts. The vertical compartment includes elevator shafts, stairs, and the like, and adjacent spaces include elevator lobbies, walkways, and living rooms.

[0004] When the connecting structure is made, the vertical compartment is segmented by a partition, and the upper floor room and the lower floor room located next to the vertical compartment are located above and below the floor slab made of reinforced concrete. When manufacturing a connecting structure, the floor slab is made directly on site and, therefore, often has a design error. Therefore, it is difficult to place the rails on the same plane as the end surface of the vertical compartment floor slab (from the side of the vertical compartment), install the racks (so that the racks are also on the same plane as the end surface of the vertical compartment floor slab (with side of the vertical compartment)) and fasten the wall material facing the vertical compartment to the uprights. For this reason, there is known a method in which the floor slab is manufactured in a state in which the top and bottom rails extend beyond the end surface of the vertical compartment floor slab (from the side of the vertical compartment), the top and bottom posts being installed in the top and bottom rails, and the wall material facing the vertical bay is attached to the top and bottom posts.

[0005] In the following, the above method will be described in detail with reference to FIG. 1. FIG. 1 is a vertical cross-sectional view illustrating an example of a conventional bridging structure between partitions and a floor slab, in which the vertical compartment is separated from the rooms on the upper and lower floors, which are adjacent to the vertical compartment and above and below the floor slab.

[0006] FIG. 1, a floor slab 20 made of reinforced concrete is located on the left side of the vertical compartment 10 and is supported by a floor beam 25 formed from a structural steel material such as H-shaped steel. The floor slab 20 is produced on site. The connecting structure 90 between the baffles and the floor slab is formed by connecting the upper first baffle 30 and the lower second baffle 40 with the floor slab 20 and the floor beam 25. The upper first partition 30 and the lower second partition 40 separate the room 13 on the upper floor and the room 15 on the lower floor, which are located above and below the floor slab 20, from the vertical compartment 10.

[0007] The end surface 21 of the vertical compartment floor slab 20 (vertical compartment side) made of reinforced concrete has protrusions and notches due to a design error. The protrusions and recesses are formed in the vertical direction as shown in FIG. 1 and also in the depth direction of the paper surface of FIG. 1. Therefore, the bottom guide 31 constituting the upper first baffle 30 and formed from the steel base building material is located on the top surface of the floor slab 20 in a state in which the bottom guide 31 extends beyond the end surface 21 by a width t1. Then, the bottom rail 31 is attached to the floor slab 20 by means of a fastener 70 such as a screw or a nail.

[0008] Additionally, the rail receivers 37A and 37B are attached to the portions of the upper and lower flanges 25a of the floor beam 25, on the side of the vertical bay with respect to the web 25b of these flanges, by welding or the like. Further, the upper and lower floor beam guides 35 formed from the steel base building material are attached to the rail receivers 37A and 37B by fasteners 70 such as screws and self-tapping screws, with the holes of the upper and lower floor beam rails 35 facing each other. Rack 36 floor beams is located in the upper and lower rails 35 floor beams. The upper and lower floor beam guides 35 are attached to the rail receivers 37A and 37B in a state in which the upper and lower floor beam guides 35 extend beyond the end surface 21 of the vertical compartment floor slab 20 (vertical compartment side) by a width t1.

[0009] Additionally, the rail receiver 37C is attached to the bottom surface of the bottom flange 25a of the floor beam 25 by welding or the like. The upper rail 33 constituting the lower second baffle 40 and formed from the steel base building material is disposed on the rail receiver 37C in a state in which the upper rail 33 extends beyond the end surface 21 on the vertical compartment side by a width t1. The top rail 33 is then attached to the rail receiver 37C by a fastener 70 such as a screw or self-tapping screw.

[0010] In the first baffle 30, a plurality of first posts 32 are installed between an upper rail (not illustrated) and a lower rail 31 at intervals in the width direction of the first baffle 30 (in the depth direction of FIG. 1), and the second wall material 60A is attached to the surfaces the first 32 racks on the side of the room. In the second baffle 40, a plurality of second studs 34 are installed between a lower rail (not illustrated) and an upper rail 33 at intervals in the width direction of the second baffle 40 (in the depth direction of FIG. 1), and the third wall material 60B is attached to the surfaces of the second studs 34 on the side of the room.

[0011] The first wall material 50 is attached to surfaces on the side of the vertical compartment of the first stud 32, the second stud 34, and the stud 36 of the floor beam. The first wall material 50 extends from the first stud 32 to the second stud 34 and faces the vertical compartment 10.

[0012] The first wall material 50, the second wall material 60A, and the third wall material 60B have stacked structures in which base layer materials 51, 61, and 64 and top layer materials 52, 62, and 65 are stacked on top of each other in the wall thickness direction. The first wall material 50, the second wall material 63, and the third wall material 60B are attached to the first post 32, the second post 34, and the floor beam post 36 by means of fasteners 70 such as screws and self-tapping screws. The base layer materials 51, 61, and 64 and the top layer materials 52, 62, and 65 may each be formed from a gypsum board. Alternatively, one of the base layer materials 51, 61 and 64 and the top layer materials 52, 62 and 65 may be formed from a gypsum board, and the other of the base layer material and the top layer material may be formed from a calcium silicate board or the like.

[0013] The first baffle 30 includes a second wall material 60A forming a room on an upper floor, a first pillar 32, a bottom rail 31, a top rail (not illustrated), and a first wall material 50. The second baffle 40 includes a third wall material 60B forming a room on bottom floor, the second post 34, the top rail 33, the bottom rail (not illustrated), and the first wall material 50. Additionally, the fire-resistant cover material 28 is formed in the vicinity of the floor beam 25 by spraying or the like. Accordingly, a connecting structure 90 is formed between the partition walls and the floor slab with fire resistance characteristics.

[0014] As illustrated in FIG. 2, a case is checked in which a large horizontal force H is applied to the first baffle 30 and the second baffle 40, such as during a strong earthquake. As described above, the bottom rail 31, the top rail 33, and the floor beam guides 35 extend beyond the end surface 21 of the vertical bay floor slab 20 (vertical bay side) by a width t1. Therefore, when a horizontal force H is applied to the first baffle 30 or the like, the first baffle 30 or the like is subjected to out-of-plane moments due to the horizontal force H. Then pressing forces P due to out-of-plane moments can be applied from the first post 32, the second post 34 and the floor beam post 36 to the inside corners on the vertical compartment side of the bottom rail 31, the top rail 33 and the beam guides 35 ceilings that are formed from the steel base building material. Thereafter, the pressing forces P cause at least portions of the first stud 32, the second stud 34 and the floor beam stud 36 to move toward the side of the vertical compartment beyond the width t1. In addition, at least portions in the vertical section of the lower rail 31, the upper rail 33, and the floor beam rails 35 can bend and deform downward and upward (deformation δ). As a result, at least portions of the first stud 32, the second stud 34, and the floor beam stud 36 may be torn off from the bottom rail 31, the top rail 33, and the floor beam guides 35, thereby causing damage to the connecting structure 90. Additionally, with regard to conservation performance, the upper ends of the second rack 34 sit in the upper guide 33 with gaps between them. The same applies to the top ends of the first stud 32 seated in the top rail (not illustrated) and to the top end of the floor joist post 36 seated in the top joist track 35. Therefore, the upper ends of the first post 32, the second post 34 and the floor beam post 36 tend to be easily detached from the top rail (not illustrated), the top rail 33 and the top rail 35 of the floor beam. If the large horizontal force H described above is applied, the first stud 32, the second stud 34, and the floor beam stud 36 may break away from the top rail (not illustrated), the top rail 33, and the top rail 35 of the floor beam, which can also cause damage to the connecting structure 90.

[0015] As described above, if the connecting structure 90 is formed by connecting the upper first baffle 30 and the lower second baffle 40 to the floor slab 20, if there are errors in the structure of the floor slab 20 by passing portions of the lower rail 31, the upper rail 33, etc. P. beyond the end surface 21 of the vertical compartment floor slab 20 (from the vertical compartment side), there may be a possibility that the connecting structure 90 may be damaged during a strong earthquake or the like.

[0016] A fire-resistant partition wall is provided that includes a fire-resistant seam. The fire-resistant joint is configured to prevent local reduction in fire resistance characteristics that may occur in the intersecting section of the transverse seam of the plinth and the vertical seam of the internal decorative panel, and with the ability to improve the fire resistance characteristics of the partition. In particular, the fire joint is inserted into the vertical joint of the interior decorative panel of the fire barrier which extends between the upper and lower horizontal fire compartments. The partition includes a vertical channel element that passes between the horizontal fire-resistant compartments, a plinth oriented in the horizontal direction, and an internal decorative panel formed on the plinth. The fire-resistant seam element includes a plug-in section configured to be inserted between the edge of the inner decorative panel and the plinth, and a bottom joint section configured to hide the bottom of the vertical seam. At least at the intersecting portion of the transverse seam and the vertical seam, a fire-resistant seam member is located in the vertical seam so as to hide the bottom of the vertical seam (see, for example, Patent Document 1).

Prior Art Documents

Patent Documents

[0017] Patent Document 1. Patent Laid-Open Publication (Japan) No. 2002-309691

The essence of the invention

Problems to be solved by the invention

[0018] According to the fireproof partition described in Patent Document 1, if a fire occurs in a room on one side, the temperature of the entire rear surface of the partition increases relatively uniformly, and there is no local high temperature area. Accordingly, the fireproof partition wall can have excellent fire resistance performance. However, even if the fireproof partition described in Patent Document 1 is applied, it is impossible to solve the problem described above with reference to FIG. 2, i.e. it is not possible to accurately connect the wall material facing the vertical compartment to the top and bottom studs by preventing damage to the connecting structure due to deformation of the top and bottom rails installed in the floor slab, while resolving design errors in the floor slab.

[0019] The present disclosure provides a connection structure between partitions and a floor slab, and a method for manufacturing a connection structure in which the material of the walls facing the vertical compartment is accurately attached to the studs without any deformation of the rails and damage to the junction structure, even if pressing forces are applied from the studs to guides during a strong earthquake, etc.

Tools for solving problems

[0020] According to an embodiment of the present invention, a connecting structure between partitions and a floor slab is provided. The connecting structure is configured to connect the upper first baffle and the lower second baffle to the floor slab. An upper first baffle and a lower second baffle separate the vertical compartment from the upstairs room and the downstairs room, which are adjacent to the vertical compartment and above and below the floor slab. The bottom rail, configured to accommodate the lower end of the first post, which forms the first partition, is placed on the floor slab. The top rail, configured to accommodate the upper end of the second post, which forms the second partition, is placed below the floor slab. The first wall material is attached to the first post through the first flashing and is attached to the second post through the second flashing. The first wall material extends from the first stud to the second stud in the vertical compartment. The first baffle is formed by the second wall material, the first post, the bottom rail, and the first wall material; the second wall material forms the room on the top floor. The second baffle is formed by the third wall material, the second post, the top rail and the first wall material. The third wall material forms the room on the lower floor.

[0021] According to an embodiment of the present disclosure, a method is provided for manufacturing a connecting structure between partitions and a floor slab. The connecting structure is configured to connect the upper first baffle and the lower second baffle to the floor slab. An upper first baffle and a lower second baffle separate the vertical compartment from the upstairs room and the downstairs room, which are adjacent to the vertical compartment and above and below the floor slab. The method includes a rail placement process, a rack installation process, and a baffle formation process. The process of placing rails includes placing the bottom rail on the floor slab and placing the top rail below the floor slab. The bottom rail is configured to receive the lower end of the first post, which forms the first baffle, and the upper rail is configured to receive the upper end of the second post, which forms the second baffle. The rack installation process includes, after placing and installing the lower end of the first rack in the bottom rail, attaching the first flashing plate to a surface on the vertical bay side of the first rack, and after locating and installing the upper end of the second rack in the second rail, attaching the second flashing plate to the surface on the first rack. side of the vertical bay of the second rack. The process of forming the partitions includes attaching the first wall material to the first stud through the first flashing and to the second stud through the second flashing. The first wall material extends from the first stud to the second stud in the vertical compartment. The partition forming process includes attaching the second wall material to the first stud such that the first partition is formed by the second wall material, the first stud, the bottom rail, and the first wall material. The second wall material forms the room on the top floor. The partition forming process includes attaching the third wall material to the second stud such that the second partition is formed by the third wall material, the second stud, the top rail, and the first wall material. The third wall material forms the room on the lower floor.

Benefits of the Invention

[0022] According to the present disclosure, it is possible to provide a connecting structure between partitions and a floor slab in which the material of the walls facing the vertical compartment is accurately attached to the posts without any deformation of the rails and damage to the connecting structure, even if pressing forces are applied from the posts to the rails. during a strong earthquake, etc.

Brief description of the drawings

[0023] FIG. 1 is a vertical cross-sectional view illustrating an example of a conventional bridging structure between partitions and a floor slab, in which the vertical compartment is separated from the rooms on the upper and lower floors, which are adjacent to the vertical compartment and above and below the floor slab;

Fig. 2 is a top cross-sectional view illustrating an example of a conventional connection structure between baffles and a floor slab that is damaged due to a horizontal force applied to the baffles during an earthquake;

Fig. 3 is a top cross-sectional view illustrating an example of a connecting structure between partitions and a floor slab according to an embodiment;

Fig. 4 is a drawing illustrating an example of a method for manufacturing a connecting structure between partitions and a floor slab according to an embodiment; And

Fig. 5 is a drawing illustrating an example of a method for manufacturing a connecting structure between partitions and a floor slab according to an embodiment.

The best embodiment of the invention

[0024] The connecting structure between the partitions and the floor slab and the manufacturing method thereof are described below with reference to the accompanying drawings. In the detailed description and drawings, elements having substantially identical functions or configurations may be referred to by identical reference numbers, and their duplicate description may be omitted.

Connecting structure between partitions and floor slab according to an embodiment

[0025] First, with reference to FIG. 3, the following describes an example of a connecting structure between partitions and a floor slab according to the embodiment. Fig. 3 is a top cross-sectional view illustrating an example of a connecting structure between partitions and a floor slab according to an embodiment.

[0026] The connecting structure 100 between the partitions and the floor slab illustrated in FIG. 3 is formed by connecting the upper first baffle 30 and the lower second baffle 40 to the floor slab 20 and the floor beam 25. An upper first baffle 30 and a lower second baffle 40 separate the vertical compartment 10 from the upstairs room 13 and the downstairs room 15, which are adjacent to the vertical compartment 10 and above and below the floor slab 20.

[0027] The vertical compartment 10 to which the connection structure 100 is applied includes elevator shafts, stairs, ventilation shafts, pipeline shafts, and the like. Room 13 on the top floor and room 15 on the bottom floor, which are spaces adjacent to the vertical compartment, include elevator lobbies, walkways, living rooms, meeting rooms, administration rooms, and the like. The connecting structure 100 can be applied not only to steel buildings, but also to reinforced concrete (RC) buildings, wooden buildings, and the like. Additionally, the buildings to which the connection structure 100 is applied include factories, warehouses, buildings, apartments, and single family houses.

[0028] The floor slab 20 made of reinforced concrete is fabricated on site, and the end surface 21 of the vertical compartment floor slab 20 (vertical compartment side) has protrusions and notches due to a design error. The protrusions and recesses are formed in the vertical direction as shown in FIG. 3 and also in the paper surface depth direction of FIG. 3.

[0029] The bottom rail 31, formed from the steel base building material and constituting the upper first baffle 30, is located on the top surface of the floor slab 20. In particular, the bottom rail 31 is positioned such that it is moved (shifted back) by a width t3 towards the room on the top floor relative to the end surface 21 of the vertical compartment floor slab 20 (from the side of the vertical compartment) and is attached to the floor slab 20 by means of the fastener 70 such as a screw or nail.

[0030] Additionally, the rail receivers 37A and 37B are attached to the portions on the side of the vertical compartment with respect to the web 25b, the upper and lower flanges 25a of the floor beam 25 by welding, and the like. The upper and lower floor beam guides 35, formed from the steel base building material, are attached to the guide receivers 37A and 37B by means of fasteners 70 such as screws and self-tapping screws, with the holes of the guides 35 facing each other. Additionally, rack 36 of the floor beam is located in the upper and lower rails 35 of the floor beam. When the top and bottom rails 35 of the floor beams are attached to the rail receivers 37A and 37B by means of fasteners 70 such as screws and self-tapping screws, the flanges 35a on the side of the vertical compartment of the rail receivers 37A and 37B are pushed back (shifted back) a width t3 to the lower floor room relative to the end surface 21 of the slab 20 of the vertical compartment floor. It should be noted that the flanges 35a on the vertical compartment side of the upper and lower rails 35 of the floor beam are located on the underside of the room between the upper rail receiver 37A and the lower rail receiver 37B.

[0031] Additionally, the rail receiver 37C is attached to the bottom surface of the bottom flange 25a of the floor beam 25 by welding or the like. The upper rail 33, formed from the steel base building material and constituting the lower second baffle 40, is positioned so that it is retracted (shifted back) by a width t3 towards the lower floor room relative to the end surface 21 of the vertical compartment floor slab 20. The top rail 33 is attached to the rail receiver 37C by a fastener 70 such as a screw or self-tapping screw.

[0032] In the first baffle 30, a plurality of first posts 32 formed from edged steel base building material are installed between an upper rail (not illustrated) and a lower rail 31. The first posts 32 are placed at intervals (e.g., at 606 mm or smaller, for example at intervals of 606 mm or 455 mm) in the width direction of the first baffle 30 (in the depth direction of FIG. 3). Additionally, the second wall material 63 is attached to the room side surfaces of the first posts 32.

[0033] In the second baffle 40, a plurality of second studs 34 formed from edged steel base building material are installed between a lower rail (not illustrated) and an upper rail 33. Second studs 34 are placed at intervals (for examples, at 606 mm intervals). or less, for example at intervals of 606 mm or 455 mm) in the width direction of the second baffle 40 (in the depth direction of FIG. 3). Additionally, the third wall material 66 is bonded to the room side surfaces of the second studs 34.

[0034] It should be noted that the first stud 32, the second stud 34, and the floor beam stud 36 may be formed from rectangular steel, instead of the edged steel base building material. As the steel main building material used for the first stud 32, the second stud 34, and the floor beam stud 36, light thin-walled steel for the overall structure (JIS G 3350), hot-dipped galvanized steel sheet (JIS G 3302), and the like can be used. . Additionally, a steel base building material having a size of 45 mm - 500 mm × 45 mm - 75 mm × 8 mm - 32 mm and a thickness of 0.4 mm or more may be used. Additionally, a rectangular steel having a size of 45 mm - 500 mm × 40 mm - 350 mm and a thickness of 0.4 mm or more can be used.

[0035] Additionally, as the steel main building material used for the bottom rail 31, the top rail 33, and the floor beam rails 35, light thin-walled steel for the overall structure (JIS G 3350), hot-dip galvanized steel sheet (JIS G 3302 ) and so on. Additionally, light thin-walled steel for the overall structure, hot-dip galvanized steel sheet and the like having a size of 45mm-500mm x 35mm-75mm and a thickness of 0.4mm or more may be used.

[0036] The first wall material 50 is attached to surfaces on the vertical bay side of the first stud 32, the second stud 34, and the floor beam stud 36. The first wall material 50 extends from the first stud 32 to the second stud 34.

[0037] The first wall material 50, the second wall material 63, and the third wall material 66 have stacked structures in which base layer materials 51, 61, and 64 and top layer materials 52, 62, and 65 are stacked on top of each other in the wall thickness direction. The first wall material 50, the second wall material 63, and the third wall material 66 are attached to the first post 32, the second post 34, and the floor beam post 36 by fasteners 70 such as screws and self-tapping screws. The base layer materials 51, 61, and 64 and the top layer materials 52, 62, and 65 may each be formed from a gypsum board or a gypsum board. Alternatively, one of the base layer materials 51, 61, and 64 and the top layer materials 52, 62, and 65 may be formed from a gypsum board or gypsum board, and the other of the base layer material and the top layer material may be formed from a calcium silicate board, etc. P. Examples of the gypsum board include the gypsum board specified in JIS 6901 having a thickness of 9.5 mm to 25 mm. In particular, "Tiger Board (Registered Trademark) - Z Type" manufactured by Yoshino Gypsum Co., Ltd. may be used. Additionally, the base layer materials 51, 61 and 64, respectively, are bonded to the top layer materials 52, 62 and 65 with adhesive materials. Examples of adhesives include vinyl acetate resin adhesives, acrylic resin adhesives, urethane adhesives, epoxy resin adhesives, and silicone adhesives.

[0038] Additionally, although not illustrated, one or both of the base layer material 51 and the top layer material 52 of the first wall material 50 may comprise a slot having a width of 10 mm or less at the position below the floor beam 25. Additionally, the slot may be filled with a sealing material such as a polyurethane material, an acrylic material, or a silicone material. In addition, although not illustrated, the floor finish may be built on the floor slab 20 . Additionally, an interior finish material such as a coating or fabric may be applied to the surfaces of the topsheet materials 62 and 65, and the interior finish surfaces of the topsheet materials 62 and 65 are accessible to the interior of the rooms. Although not illustrated, the skirting board is attached such that it extends from the floor finish material constructed on the top surface of the floor slab 20 into the interior finish surface.

[0039] As illustrated in FIG. 3, the first wall material 50 is attached to the first stud 32 by a fastener 70, such as a screw, self-tapping screw, or staple, through a first flashing 80A having a thickness t2. Additionally, the first wall material 50 is attached to the second post 34 by means of a fastener 70 through a second flashing 80B having the same thickness t2. Additionally, the first wall material 50 is attached to the floor beam upright 36 by means of a fastener 70 via a third flashing 80C having the same thickness t2.

[0040] Each of the first flashing 80A, the second flashing 80B, and the third flashing 80C may be formed from gypsum board, gypsum board, reinforced gypsum board, non-combustible sandwich gypsum board, fiber reinforced cement board, glass wool, stone wool, glass fiber felt, rock wool felt, etc. and may have a thickness of about 25 mm or less and a width of about 40 mm or more. It should be noted that each of the first flashing 80A, the second flashing 80B and the third flashing 80C can have a total thickness of more than 25 mm by stacking two or more flashings on top of each other.

[0041] With the setting line L1, along which the first wall material 50 is installed in the vertical compartment 10, as the starting line, the first post 32, the second post 34, and the floor beam post 36 are moved (rearward) by a thickness t2 of the first flashing 80A, the second flashing 80B and the third flashing 80C, respectively, from the starting line to the room on the top floor and the room on the bottom floor. Additionally, the bottom track 31, the top track 33 and (flanges 35a on the side of the bay) the floor beam guides 35 are moved (shifted back) by a width t3 towards the top floor room and the bottom floor room with respect to the end surface 21 of the vertical bay floor slab 20. Accordingly, as illustrated in FIG. 2, even if the horizontal force H is applied to the first baffle 30 and the second baffle 40 at the time of an earthquake, and pressing forces P are applied from the first post 32, the second post 34, and the like. to the bottom run 31, the top run 33, etc., the bottom guide 31, the top guide 33, etc. are not deformed. Accordingly, damage to the connecting structure 100 due to deformation of the lower guide 31, the upper guide 33, and the like. can be prevented.

[0042] Additionally, a first flashing 80A is placed between the first post 32 and the first wall material 50, a second flashing 80B is placed between the second post 34 and the first wall material 50, and a third flashing 80C is placed between the floor beam post 36 and the first wall material 50. of this configuration, even if the end surface 21 of the vertical compartment floor slab 20 made of reinforced concrete has protrusions and notches due to error, when the floor slab 20 is fabricated on site, the first wall material 50 can be accurately attached to the first stud 32, the second stud 34, and rack 36 floor beams.

[0043] In the connecting structure 100, a gap formed between the end surface 21 of the vertical compartment floor slab 20 and the first wall material 50 is filled with a refractory 85 formed from stone wool or the like. Additionally, the fire resistant cover material 28 is formed in the vicinity of the floor beam 25 by spraying or the like. The flame retardant cover material 28 is formed, for example, from a laminate of felt heat resistant stone wool and a flame retardant non-woven fabric.

[0044] As described above, the first baffle 30 and the second baffle 40 are provided with fire resistance, a fire resistant cover material 28 is provided in the vicinity of the floor beam 25, and the gap between the end surface 21 of the vertical compartment floor slab 20 and the first wall material 50 is filled with a refractory 85. Accordingly, the connecting structure 100 with excellent fire resistance can be formed.

Method for manufacturing a connecting structure between partitions and a floor slab according to an embodiment

[0045] Next, with reference to FIG. 4 and FIG. 5, and again with reference to FIG. 3, an example of a method for manufacturing a connecting structure between partitions and a floor slab according to an embodiment is described. Fig. 4 and FIG. 5 are top cross-sectional views illustrating an example of a method for manufacturing a connecting structure between partitions and a floor slab according to the embodiment, and the method will be described with reference to FIG. 4, fig. 5 and FIG. 3 in that order.

[0046] The method for manufacturing a connecting structure according to the embodiment includes a floor slab construction process, a rail placement process, a stud installation process, and a partition formation process.

[0047] First, as illustrated in FIG. 4, a floor slab 20 made of reinforced concrete is fabricated on site such that the floor slab 20 is supported by a floor beam 25 formed from H-shaped steel (floor slab construction process).

[0048] Then, the bottom rail 31, configured to accommodate the lower end of the first post 32, which forms the first partition 30, is attached to the top of the floor slab 20 by means of the fastener 70. Additionally, the Top rail 33, configured to accommodate the upper end of the second post 34, which forms the second partition 40, is secured under the bottom flange 25a of the floor beam 25 by means of a fastener 70. The floor beam 25 supports the floor slab 20.

[0049] The rail receivers 37A and 37B are attached to the portions on the side of the vertical compartment with respect to the web 25b, the upper and lower flanges 25a of the floor beam 25 by welding, and the like. The upper and lower floor beam guides 35 are attached to the rail receivers 37A and 37B by fasteners 70 with the openings of the upper and lower floor beam rails 35 facing each other. Rack 36 floor beams is located in the upper and lower rails 35 floor beams.

[0050] With the setting line L1, on which the first wall material 50 is installed in the vertical compartment 10, as the starting line, the bottom guide 31, the top guide 33, and the floor beam guides 35 are positioned so that they are pushed back (shifted back) by a thickness t2 of the first flashing 80A, the second flashing 80B, and the third flashing 80C from the starting points Q on the setting line L1 to the upstairs room and downstairs room (guide placement process). It should be noted that after the guide placement process, the fire-resistant coating material 28 is formed in the vicinity of the floor beam 25 by spraying or the like, and the refractory 85 is provided on the end surface 21 of the vertical compartment floor slab 20 .

[0051] Further, as illustrated in FIG. 5, the lower end of the first column 32 is placed and installed in the lower rail 31. It should be noted that the upper end of the first column 32 is seated in the upper rail (not illustrated). Then, the first flashing 80A is attached to the surface on the side of the vertical bay of the first post 32.

[0052] Additionally, the upper end of the second column 34 is placed and installed in the upper rail 33. It should be noted that the lower end of the second column 34 sits in the lower rail (not illustrated). Then, the second flashing 80B is attached to the surface on the side of the vertical compartment of the second column 34.

[0053] Additionally, the third flashing 80C is attached to the surface on the side of the vertical compartment of the pillar 36 of the floor beam. The first flashing 80A, the second flashing 80B, and the third flashing 80C are temporarily fixed to the first post 32, the second post 34, and the floor beam post 36 with adhesive tapes (including double-sided adhesive tapes), adhesives, self-tapping screws, or the like. For example, acrylic resin adhesives, polyamide adhesives, natural rubber adhesives, synthetic rubber adhesives, and the like can be used. Additionally, adhesive tapes having a thickness of 3 mm or less and a width of 100 mm or less can be used.

[0054] It should be noted that the third flashing 80C can be temporarily attached to the floor beam post 36 in advance, and when the floor beam post 36 is placed in the rail placement process, installation of the third flashing 80C can be completed at the same time (stud installation process).

[0055] Then, as illustrated in FIG. 3, the first wall material 50 is attached to the first stud 32 by the fastener 70 through the first flashing 80A, attached to the second stud 34 by the fastener 70 through the second flashing 80B, and attached to the floor joist post 36 by the fastener 70 through the third flashing 80C. The first wall material 50 extends from the first post 32 to the second post 34 in the vertical compartment 10. The first flashing 80A or the like, which is temporarily attached to the first post 32 or the like, is permanently attached to the first post 32 or the like. . tightly by means of fasteners 70.

[0056] Further, the second wall material 63 forming the upper floor room 13 is attached to the first post 32 by the fastener 70. Accordingly, the first partition 30 is formed by the second wall material 63, the first post 32, the bottom rail 31, the top rail ( not illustrated) and the first wall material 50.

[0057] Additionally, the third wall material 66 forming the lower floor room 15 is attached to the second stud 34 by the fastener 70. Accordingly, the second partition 40 is formed by the third wall material 66, the second stud 34, the top rail 33, the bottom rail ( not illustrated) and the first material of the walls 50, and the connecting structure 100 is manufactured (the partition forming process).

[0058] In the method for manufacturing the connecting structure according to the embodiment, the bottom guide 31, the top guide 33, and the like. are positioned in such a way that they are pushed back (shifted back) by a predetermined amount to the room on the top floor and the room on the lower floor relative to the end surface 21 of the vertical compartment floor slab 20 having protrusions and recesses. Accordingly, damage to the lower guide 31 or the like. due to an earthquake can be prevented. In addition, the first wall material 50 can be accurately attached to the first stud 32 or the like. through the first flashing 80A and the like, thereby enabling the connecting structure 100 to be efficiently constructed.

[0059] Other embodiments may be modified in which other elements are combined with elements of the above embodiment, and the present description of the entity is not limited to the configurations shown herein. In this respect, changes may be made without departing from the intent of the present disclosure and may be appropriately determined according to their form of application.

[0060] This application is based on and claims priority to Japanese Patent Application No. 2020-049538, filed March 19, 2020, the contents of which are incorporated herein by reference in their entirety.

Description of links with numbers

[0061] 10 - vertical compartment

13 - room on the top floor

15 - room on the lower floor

20 - floor slab

25 - floor beam

28 - fire-resistant cover material

21 - end surface on the side of the vertical compartment

30 - first partition

31 - bottom guide

32 - first rack

33 - top guide

34 - second rack

35 - floor beam guide

36 - rack floor beams

37A - first rail receiver (rail receiver)

37B - second rail receiver (rail receiver)

37C - third rail receiver (rail receiver)

40 - second partition

50 - the first wall material

51 - base layer material

52 - top layer material

60A, 63 - second wall material

60B, 66 - third wall material

61, 64 - base layer material

62, 65 - top layer material

70 - fastener

80A - first flashing

80B - second flashing

80C - third flashing

85 - refractory

100 - connecting structure between partitions and floor slab (connecting structure).

Claims (31)

1. A connecting structure between partitions and a floor slab, wherein the connecting structure is configured to connect the upper first partition and the lower second partition to the floor slab, the upper first partition and the lower second partition separating the vertical compartment from the room on the upper floor and the room on the lower floor, which are located next to the vertical compartment and above and below the floor slab, - at the same time, the lower guide, configured to accommodate the lower end of the first post, which forms the first partition, is placed on the floor slab, - an upper guide, configured to accommodate the upper end of the second post, which forms the second partition, is placed below the floor slab, - the first wall material is attached to the first post through the first flashing and attached to the second post through the second flashing, the first wall material extending from the first post to the second post in the vertical compartment, - the first partition is formed by the second wall material, the first post, the bottom rail and the first wall material, the second wall material forming the room on the top floor, and - the second partition is formed by the third wall material, the second post, the top rail and the first wall material, the third wall material forming the room on the lower floor. 2. The structure according to claim 1, wherein the lower rail and the upper rail are offset by the thickness of the first flashing and the second flashing, respectively, to the room on the upper floor and the room on the lower floor relative to the end surface of the floor slab on the side of the vertical compartment. 3. Design according to any one of paragraphs. 1, 2, in which the lower guide is attached to the floor slab by means of a fastener, - while the upper guide is attached to the guide receiver by means of a fastener, and the guide receiver is directly or indirectly attached to the floor slab. 4. The structure according to claim 3, in which the floor slab is supported by a floor beam, - the rail receiver is attached to the floor beam, and the upper rail is attached to the rail receiver. 5. Design according to any one of paragraphs. 1-4, in which a refractory is located between the end surface of the floor slab on the side of the vertical compartment and the first wall material. 6. Design according to any one of paragraphs. 1-5, wherein the first wall material, the second wall material, and the third wall material each have a stacked structure in which the base layer material and the top layer material are stacked on top of each other in the thickness direction of the baffles. 7. Building containing: - a connecting structure between partitions and a floor slab according to any one of paragraphs. 1-6. 8. A method for manufacturing a connecting structure between partitions and a floor slab, wherein the connecting structure is configured to connect the upper first partition and the lower second partition to the floor slab, the upper first partition and the lower second partition separating the vertical compartment from the room on the upper floor and the room on the lower floor, which are located next to the vertical compartment and above and below the floor slab, while the method contains: - the process of placing guides; rack installation process; and the process of forming partitions, - at the same time, the process of placing guides includes the stages at which: - placing the lower guide on the floor slab, wherein the lower guide is configured to receive the lower end of the first post, which forms the first partition, and - placing the upper guide below the floor slab, wherein the upper guide is configured to receive the upper end of the second post, which forms the second partition, - at the same time, the process of installing racks includes the stages at which: - after placing and installing the lower end of the first post in the lower rail, attach the first flashing to the surface of the first post on the side of the vertical compartment, and - after placing and installing the upper end of the second post in the second rail, attach the second flashing to the surface of the second post on the side of the vertical compartment, and - at the same time, the process of forming partitions includes the stages at which: - attaching the first wall material to the first post through the first flashing and to the second post through the second flashing, the first wall material extending from the first post to the second post in the vertical compartment, attaching the second wall material to the first stud such that the first partition is formed by the second wall material, the first stud, the bottom rail and the first wall material, the second wall material forming the room on the top floor, and attaching the third wall material to the second stud in such a way that the second partition is formed by the third wall material, the second stud, the top rail and the first wall material, the third wall material forming a room on the lower floor. 9. The method according to claim 8, wherein during the placement of the guides, the bottom guide and the top guide are placed on the floor slab and below the floor slab in such a way that they are offset by a predetermined amount towards the room on the top floor and the room on the bottom floor, respectively, relative to the end surface of the floor slab on the side of the vertical compartment, and wherein the predetermined value is the length, starting from the position in which the first wall material is fixed during the formation of the partitions, and corresponding to the thickness of the first flashing and the second flashing. 10. The method according to any one of paragraphs. 8, 9 further comprising a floor slab manufacturing process for manufacturing a floor slab such that it is supported by a floor beam, - while in the process of placing the guides, the guide receiver is attached to the floor beam, and the upper guide is attached to the guide receiver.

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