JP7465825B2 - Beam-floor joint structure - Google Patents

Description

The present invention relates to a beam-floor joint structure, and in particular to a beam-floor joint structure for integrally joining a wooden beam and a concrete floor slab formed by pouring in-situ concrete onto the top surface of the wooden beam.

For example, in the case of low- to mid-rise buildings, wooden buildings are generally constructed entirely of wood, while reinforced concrete buildings are generally constructed entirely of concrete. In recent years, it has become possible to form large-section structural members, preferably using laminated timber made of wood, making it possible to build larger buildings using wood. However, even when using laminated timber, there is a limit to how large a building can be made using wood alone.

For this reason, various buildings have been developed that have composite structures of wood and concrete, combining the strength of concrete with the warm exterior and interior of wood by combining structural parts made of wood and structural parts made of concrete. As a composite structure for such buildings, for example, a beam-floor joint structure has been proposed in which a concrete floor slab is provided on the top surface of a beam, preferably made of exposed wood. Furthermore, a technology has been developed that makes it easy to integrate the wooden beam and the floor slab by forming the floor slab on the top surface of the wooden beam using cast-in-place concrete (see, for example, Patent Documents 1 to 3). For example, by using exposed wooden beams, it is possible to provide a space with a wood-like texture, and a concrete floor slab is effective in ensuring livability in terms of noise and floor vibration between upper and lower floors, and the development of wooden beams with fire resistance has made it possible to use wooden beams even in properties that are subject to fire resistance restrictions.

In addition, in the beam-floor joint structure between wooden beams and floor slabs made of cast-in-place concrete described in Patent Documents 1 to 3, in order to efficiently transmit the shear force along the joint between the wooden beams and the concrete floor slab between these members, grooves that intersect in a plan view are provided on the top surface of the wooden beam, and these grooves are filled with cast-in-place concrete and allowed to harden (see Patent Document 1), cast-in-place concrete is poured while wrapping around a cement hardening body with an uneven surface that is fixed to the top surface of the wooden beam with lag screws (see Patent Document 2), or steel plates or steel rods are protruded from the top surface of the wooden beam, and cast-in-place concrete is poured while wrapping around these steel materials (see Patent Document 3), thereby ensuring shear resistance.

Patent No. 5930609 Japanese Patent No. 6010430 Patent No. 6592958

However, the beam-floor joint structures described in Patent Documents 1 to 3, which are between wooden beams and floor slabs made of cast-in-place concrete, require a lot of work, such as machining grooves that intersect in a plan view on the top surface of the wooden beams, forming a cement hardened body with unevenness, and machining and attaching steel plates and steel bars. Therefore, there is a need for the development of a new beam-floor joint structure that can ensure shear strength in a more stable state over a long period of time.

The objective of the present invention is to provide a beam-floor joint structure between a wooden beam and a floor slab made of cast-in-place concrete that can be easily formed without requiring much effort and that can ensure shear strength in a more stable state over a long period of time.

The present invention provides a beam-floor joint structure for integrally joining a wooden beam and a concrete floor slab formed by pouring in-situ concrete on the upper surface of the wooden beam, and has a shear force transmission means provided at the joint between the wooden beam and the concrete floor slab to transmit the shear force along the joint between these members. The shear force transmission means is an architectural grid-like surface material formed by overlapping a lower stage strip layer of multiple elongated strip-shaped plate materials arranged in parallel at intervals and fixed integrally to the upper surface of the wooden beam, and an upper stage strip layer of multiple elongated strip-shaped plate materials similarly arranged in parallel at intervals, diagonally crossing the axial direction of the wooden beam, in a grid pattern, and concrete that has solidified and entered continuously into the gaps between the multiple strip-shaped plate materials that make up the lower stage strip layer and the gaps between the multiple strip-shaped plate materials that make up the upper stage strip layer when pouring in-situ concrete, thereby achieving the above-mentioned objective.

The beam-floor joint structure of the present invention is preferably such that, in the areas where the gaps between the multiple strip-shaped plate materials constituting the lower strip layer and the gaps between the multiple strip-shaped plate materials constituting the upper strip layer overlap, metal rod-shaped metal fittings are driven from above toward the wooden beams and are embedded in the concrete floor slab with their upper parts erected above the top surface of the wooden beams and above the architectural lattice surface material.

In addition, in the beam-floor joint structure of the present invention, it is preferable that the wooden beam is a fireproof beam having a load-bearing layer that is the load-bearing portion and a covering layer made of a covering material that surrounds both sides and the underside of the load-bearing layer.

Furthermore, in the beam-floor joint structure of the present invention, the wooden beam is preferably a fire-resistant beam having a load-bearing layer that is the load-bearing portion, a covering layer made of a covering material made of fire-retardant-injected wood that surrounds both sides and the underside of the load-bearing layer, and a decorative material that surrounds the sides and underside of the covering layer.

Furthermore, in the beam-floor joint structure of the present invention, the wooden beam is preferably a fireproof beam having a load-bearing layer that is the load-bearing portion, a side covering layer made of a covering material made of wood that covers both side surfaces of the load-bearing layer, a bottom covering layer made of a covering material made of reinforced gypsum board that covers the bottom surface of the load-bearing layer, and a decorative material made of wood that surrounds both side surfaces and the bottom surface of the bottom covering layer.

In addition, in the beam-floor joint structure of the present invention, reinforcing steel members attached at intervals in the axial direction of the wooden beam are embedded in the concrete floor slab so as to straddle the covering layers on both sides of the load-bearing layer or the top surface of the side covering layers on both sides, and it is preferable that the architectural lattice surface material is fixed integrally to the top surface of the wooden beam in a divided state at the portion where the reinforcing steel members are attached.

Furthermore, the beam-floor joint structure of the present invention is a fireproof wooden structural material in which the wooden beam has a wooden load-bearing layer, a non-combustible first covering member covering both sides of the load-bearing layer in one direction of the cross section, a wooden burnt layer fixed via a spacer to the outside of each of the first covering members in the one direction so as to have a gap between the first covering member and the first covering member, and a second covering member covering one or both sides of the load-bearing layer in a direction perpendicular to the one direction, and a non-combustible corner reinforcing member is arranged on the outer surface side of each of the first covering members on the one or both sides having the second covering member in the orthogonal direction, and the corner reinforcing member is arranged in a state where it overlaps the outer surface of the first covering member in part or in whole and extends from one end of the load-bearing layer in the orthogonal direction, and it is preferable that the corner reinforcing member partially narrows the length of the gap in the one direction or partially eliminates the gap.

The beam-floor joint structure of the present invention, which is made of a wooden beam and a floor slab made of cast-in-place concrete, can be easily formed without requiring much effort, and can ensure shear strength in a more stable state over the long term.

1A is a cross-sectional view of a beam-floor joint structure according to a first preferred embodiment of the present invention, FIG. 1B is a perspective view of a wooden beam portion, and FIG. 1C is a top view of the wooden beam portion. 1A is a cross-sectional view of a beam-floor joint structure according to a second preferred embodiment of the present invention, FIG. 1B is a perspective view of a wooden beam portion, and FIG. 1C is a top view of the wooden beam portion. 3A is a cross-sectional view of a beam-floor joint structure according to a third preferred embodiment of the present invention, FIG. 3B is a perspective view of a wooden beam portion, and FIG. 3C is a top view of the wooden beam portion. 4A is a cross-sectional view of a beam-floor joint structure according to a fourth preferred embodiment of the present invention, FIG. 4B is a perspective view of a wooden beam portion, and FIG. 4C is a top view of the wooden beam portion. FIG. 11 is a cross-sectional view illustrating another preferred embodiment of the present invention.

The beam-floor joint structure 10 according to the first preferred embodiment of the present invention is used as a joint structure for joining together a wooden beam 11 and a concrete floor slab 12 made of cast-in-place concrete as a composite structure of wood and concrete, for example as shown in FIG. 1(a). The beam-floor joint structure 10 of the first embodiment makes it possible to form a building with a composite structure of wood and concrete that combines the increased strength of concrete with the warm exterior and interior of wood, and can be easily installed without much effort. It also has the function of firmly joining a wooden beam and a concrete floor slab, which are materials with different physical properties, to ensure shear strength in the direction along the joint in a more stable state over the long term.

As shown in Figures 1(a) to (c), the beam-floor joint structure 10 of the first embodiment is a joint structure for integrally joining a wooden beam 11 and a concrete floor slab 12 formed by pouring in-situ concrete on the upper surface of the wooden beam 11, and has a shear force transmission means 13 provided at the joint between the wooden beam 11 and the concrete floor slab 12 to transmit the shear force along the joint between these members. The shear force transmission means 13 is formed integrally with the upper surface of the wooden beam 11 by overlapping a lower strip layer 14 made of multiple elongated strip-shaped plate materials 14a arranged in parallel at intervals, and an upper strip layer 15 made of multiple elongated strip-shaped plate materials 15a similarly arranged in parallel at intervals, diagonally crossing the axial direction X of the wooden beam 11 in a grid pattern, forming a building grid-like surface material 16, and concrete that has solidified and penetrated in a continuous state into the gaps 14b of the multiple strip-shaped plate materials 14a that make up the lower strip layer 14 and the gaps 15b of the multiple strip-shaped plate materials 15a that make up the upper strip layer 15 when pouring the cast-in-place concrete.

In the first embodiment, in the area where the gaps 14b of the multiple strip-shaped plate materials 14a constituting the lower strip layer 14 and the gaps 15b of the multiple strip-shaped plate materials 15a constituting the upper strip layer 15 overlap, metal rod-shaped metal fittings 17 are driven from above toward the wooden beams 11 and are embedded in the concrete floor slab 12 with their upper parts standing upright above the architectural grid-like surface material 16 from the top surface of the wooden beams 11.

In the first embodiment, the wooden beam 11 can be formed using wooden beam materials of various materials known as structural timber that constitutes a framework structure. The wooden beam 11 can be preferably formed using laminated timber obtained by layering multiple boards sawn from small diameter logs with adhesive, as described in JP 2007-268731 A. The wooden beam 11 is formed by using structural timber with a width of, for example, about 45 mm to 200 mm, which is generally distributed as structural timber, either alone or layered in the width direction, so that the structural timber has a rectangular (including square) cross-sectional shape with a width in the horizontal direction (horizontal width) of about 45 mm to 1500 mm and a width in the vertical direction perpendicular to the horizontal direction (vertical width) of about 90 mm to 1500 mm, and a length of, for example, about 3000 to 15000 mm. The wooden beam 11 is supported at both ends by other wooden beam members or pillar members that extend perpendicular to it, and is attached in a spanning state between these members.

The cast-in-place concrete poured onto the top surface of the wooden beams 11 can be any of a variety of known unhardened, fluid concretes used in construction work. Cast-in-place concrete is poured to a specified thickness after appropriate reinforcing bars are placed on, for example, a temporary formwork support (not shown) assembled in the area between adjacent wooden beams 11, or on a deck plate (not shown) erected between adjacent wooden beams 11, and then hardened to form a concrete floor slab 12 of a specified thickness.

The shear force transmission means 13, which is provided at the joint between the wooden beam 11 and the concrete floor slab 12 and transmits the shear force along the joint between these members, is formed as described above by the architectural grid surface material 16, which is formed by diagonally crossing the lower strip plate layer 14 and the upper strip plate layer 15 made of multiple elongated strip plate materials 14a, 15a to form a grid shape, and by the concrete portion that has entered and solidified in a continuous state into the gaps 14b between the multiple strip plate materials 14a of the lower strip plate layer 14 and the gaps 15b between the multiple strip plate materials 15a of the upper strip plate layer 15.

The architectural grid surface material 16 can preferably be a panel having a similar structure to the wall finishing base panel used in the wall finishing base structure described in, for example, Japanese Patent No. 3162676, known as "Kizure Panel" (registered trademark). In other words, the architectural grid surface material 16 is a panel member that can also be used as a wall finishing base material for buildings, and is composed of a lower band plate layer 14 and an upper band plate layer 15 that are joined together as shown in Figures 1 (b) and (c). The lower band plate layer 14 and the upper band plate layer 15 are each composed of a large number of band-shaped plate materials 14a, 15a arranged in parallel in an inclined direction with predetermined intervals 14b, 15b between them. In addition, the strip-shaped plate material 14a constituting the lower strip layer 14 and the strip-shaped plate material 15a constituting the upper strip layer 15 are arranged so as to be inclined in opposite directions so as to intersect with each other, and at each intersection, the strip-shaped plate material 14a of the lower strip layer 14 and the strip-shaped plate material 15a of the upper strip layer 15 are bonded together with an adhesive or the like to form an integrated structure, thereby obtaining a grid-like architectural surface material 16.

Such architectural grid surface material 16 is precisely formed in advance in a factory or the like, and after being delivered to the construction site of the building, it is cut to a predetermined shape corresponding to the shape of the upper surface of the wooden beam 11, and can be fixed to the upper surface of the wooden beam 11 by bonding it to the upper surface of the wooden beam 11 with adhesive or the like. In addition, the architectural grid surface material 16 can be fixed to the upper surface of the wooden beam 11 by work at the construction site without using a preformed one in a factory or the like, by attaching a plurality of strip-shaped plate materials 14a of the lower strip layer 14 to the upper surface of the wooden beam 11 at a predetermined interval 14b with adhesive or the like, and then attaching a plurality of strip-shaped plate materials 15a of the upper strip layer 15 to the upper surface of the wooden beam 11 with adhesive or the like at a predetermined interval 15b at the construction site of the building.

Here, in the first embodiment, the multiple strip-shaped plate materials 14a, 15a constituting the lower strip layer 14 and the upper strip layer 15 of the architectural grid surface material 16 can be strip-shaped plate members having a cross section with a width of about 30 to 120 mm and a thickness of about 8 to 40 mm, for example, similar in material and shape to the narrow boards used in conventional wooden lath bases. In addition, the multiple strip-shaped plate materials 14a, 15a constituting the lower strip layer 14 and the upper strip layer 15 are arranged with intervals 14b, 15b of, for example, 35 to 100 mm, and are inclined at an angle of 45 degrees with respect to the axial direction X of the wooden beam 11, and the strip-shaped plate materials 14a constituting the lower strip layer 14 and the strip-shaped plate materials 15a constituting the upper strip layer 15 are arranged to cross each other and incline in opposite directions symmetrical with respect to the axial direction X of the wooden beam 11. That is, each strip-shaped plate material 14a, 15a intersects at right angles and is arranged in a grid pattern tilted at 45 degrees.

In addition, according to the first embodiment, the gaps 14b between the strip-shaped plate materials 14a constituting the lower strip layer 14 and the gaps 15b between the strip-shaped plate materials 15a constituting the upper strip layer 15 are also arranged to be inclined at an angle of 45 degrees with respect to the axial direction X of the wooden beam 11, and are arranged in a lattice pattern inclined at 45 degrees in opposite directions symmetrical to the axial direction X of the wooden beam 11 so as to intersect with each other at right angles, and each gap 14b, 15b communicates with each other at these intersections.

In the first embodiment, when the cast-in-place concrete in a fluid state is poured above the wooden beam 11, the concrete content in the concrete, for example, the mortar content in the concrete and the concrete content containing only coarse aggregate with a particle size equal to or smaller than the thickness of the strip plate material 14a of the lower strip plate layer 14, will fill not only the gaps in the intervals 15b between the strip plate materials 15a of the upper strip plate layer 15, but also the gaps in the intervals 14b between the strip plate materials 14a constituting the lower strip plate layer 14 that are continuous with this, and then solidify. As a result, the strip plate material 14a of the lower strip plate layer 14, the strip plate material 15a of the upper strip plate layer 15, and the cast-in-place concrete that has been filled and solidified in the continuous intervals 14b, 15b are interlocked in a mixed and integrated state at the joint between the wooden beam 11 and the concrete floor slab 12, forming a strong shear force transmission means 13. In this embodiment, the shear force transmission means 13 formed by interlocking the wooden architectural grid panel 16 and the concrete in this state makes it possible to firmly support the shear force along the joint without losing balance between the long-term shear strength of the wood and the long-term shear strength of the concrete, and also makes it possible to efficiently transmit the shear force along the joint between the wooden beam 11 and the concrete floor slab 12.

Therefore, according to the beam-floor joint structure of the first embodiment, a lower strip layer 14 made of multiple strip-shaped plate materials 14a arranged in parallel at intervals and an upper strip layer 15 made of multiple strip-shaped plate materials 15a are diagonally crossed and overlapped in a grid pattern to form an architectural grid-like surface material 16, which is fixed as a single unit on the upper surface of the wooden beam 11, and then, with a simple configuration in which cast-in-place concrete is poured above the wooden beam 11, it is possible to easily form a shear force transmission means 13 that can effectively transmit the shear force along the joint between the wooden beam 11 and the concrete floor slab 12 without much effort, and it is possible to avoid a loss of balance between the long-term shear strength of the wood and the long-term shear strength of the concrete, and to ensure the shear strength of the joint of these members in a more stable state over a long period of time.

In the first embodiment, in the overlapping portion between the gaps 14b of the plurality of strip-shaped plate materials 14a constituting the lower strip layer 14 and the gaps 15b of the plurality of strip-shaped plate materials 15a constituting the upper strip layer 15, as shown in FIG. 1(a), a metal rod-shaped metal fitting 17, preferably a lag screw, can be embedded in the concrete floor slab 12 with its upper portion erected above the upper surface of the wooden beam 11 and above the architectural grid-like surface material 16. A plurality of metal rod-shaped metal fittings 17 can be attached at predetermined intervals in the axial direction X of the wooden beam 11 (see FIGS. 1(b) and (c)). This effectively reinforces the shear force transmission means 13 that transmits the shear force along the joint between the members of the wooden beam 11 and the concrete floor slab 12, making it possible to ensure the shear resistance of the joint made of these members in a more stable state over a long period of time.

Figures 2(a) to (c) show a beam-floor joint structure 20 according to a preferred second embodiment of the present invention. The beam-floor joint structure 20 according to the second embodiment shown in Figures 2(a) to (c) has a configuration that is substantially similar to the beam-floor joint structure 10 of the first embodiment, except that the shape of the wooden beam 21 is different from that of the wooden beam 11 of the first embodiment. Note that with respect to the beam-floor joint structure 20 of the second embodiment shown in Figures 2(a) to (c), the components that differ from the beam-floor joint structure 10 of the first embodiment will be mainly described, and the same components will be given the same reference numerals and will not be described. For components that are not specifically mentioned, the description of the beam-floor joint structure 10 of the first embodiment will be applied as appropriate.

In the second embodiment of the beam-floor joint structure 20 shown in Figures 2(a) to (c), the wooden beam 21 is a fire-resistant beam that has a load-bearing layer 21a that is the load-bearing portion, and a covering layer 21b that is a burnable layer made of a covering material that surrounds both sides and the underside of the load-bearing layer 21a.

In the second embodiment, the architectural grid surface material 16 formed by overlapping the lower strip layer 14 made of strip plate material 14a and the upper strip layer 15 made of strip plate material 15a in a grid pattern, which constitutes the shear force transmission means 23, is fixed integrally to the upper surface of the load support layer 21a of the wooden beam 21, and the cast-in-place concrete is poured and solidified on the upper surface of the load support layer 21a and the burnt layers (covering layers) 21b on both sides so as to cover the entire fixed architectural grid surface material 16, forming a concrete floor slab 12 integrated with the wooden beam 21. In addition, in the area where the gap portion 14b of the lower strip layer 14 and the gap portion 15b of the upper strip layer 15 overlap, metal rod-shaped metal fittings 17 are driven from above toward the wooden beam 21 at a predetermined interval in the axial direction X of the wooden beam 21 and are embedded in the concrete floor slab 12 in a standing state from the upper surface of the wooden beam 21.

The beam-floor joint structure 20 of the second embodiment also has a shear force transmission means 23 that can firmly support the shear force along the joint, since the strip plate material 14a of the lower strip plate layer 14 of the architectural grid surface material 16, the strip plate material 15a of the upper strip plate layer 15, and the cast-in-place concrete that has been filled in and solidified in the successive gaps 14b, 15b are interlocked together at the joint between the wooden beam 21 and the concrete floor slab 12, and thus produces the same effect as the beam-floor joint structure 10 of the first embodiment described above.

Figures 3(a) to (c) show a beam-floor joint structure 30 according to a preferred third embodiment of the present invention. The beam-floor joint structure 30 according to the third embodiment shown in Figures 3(a) to (c) has a configuration that is substantially similar to the beam-floor joint structure 10 of the first embodiment, except that the shape of the wooden beam 31 is different from that of the wooden beam 11 of the first embodiment. Note that with respect to the beam-floor joint structure 30 of the third embodiment shown in Figures 3(a) to (c), the components that differ from the beam-floor joint structure 10 of the first embodiment will be mainly described, and similar components will be given the same reference numerals and will not be described. For components that are not specifically mentioned, the description of the beam-floor joint structure 10 of the first embodiment will be applied as appropriate.

In the third embodiment of the beam-floor joint structure 30 shown in Figures 3(a) to (c), the wooden beam 31 is a fire-resistant beam that includes a load-bearing layer 31a that is the load-bearing portion, a coating layer 31b that is the burnable layer made of a coating material made of fire-retardant-injected wood that surrounds both sides and the underside of the load-bearing layer, and a decorative material 31c that surrounds the sides and underside of the coating layer 31b.

In the third embodiment, the architectural lattice surface material 16 formed by overlapping a lower strip layer 14 made of strip plate material 14a and an upper strip layer 15 made of strip plate material 15a in a lattice pattern, which constitutes the shear force transmission means 33, is fixed integrally to the upper surface of the load support layer 31a of the wooden beam 31, and cast-in-place concrete is poured and solidified on the upper surfaces of the load support layer 31a, the burnt layer (covering layer) 31b made of fire-retardant-injected wood on both sides, and the decorative materials 31c on both sides, so as to cover the entire fixed architectural lattice surface material 16, thereby forming a concrete floor slab 12 integrated with the wooden beam 31. In addition, where the gap 14b of the lower strip layer 14 and the gap 15b of the upper strip layer 15 overlap, metal rod-shaped metal fittings 17 are driven from above toward the wooden beam 31 at a predetermined interval in the axial direction X of the wooden beam 31 and are embedded in the concrete floor slab 12 in an upright position from the top surface of the wooden beam 31.

The beam-floor joint structure 30 of the third embodiment also has a joint between the wooden beam 31 and the concrete floor slab 12, in which the strip plate material 14a of the lower strip plate layer 14 of the architectural grid surface material 16, the strip plate material 15a of the upper strip plate layer 15, and the cast-in-place concrete that has been filled and solidified in the successive gaps 14b, 15b are interlocked together in a mixed and integrated state, forming a shear force transmission means 33 that can firmly support the shear force along the joint, thereby achieving the same effect as the beam-floor joint structure 10 of the first embodiment described above.

Figures 4(a) to (c) show a beam-floor joint structure 40 according to a preferred fourth embodiment of the present invention. The beam-floor joint structure 40 according to the fourth embodiment shown in Figures 4(a) to (c) has a configuration that is substantially similar to the beam-floor joint structure 10 of the first embodiment, except that the shape of the wooden beam 41 is different from that of the wooden beam 11 of the first embodiment. Note that with respect to the beam-floor joint structure 40 of the fourth embodiment shown in Figures 4(a) to (c), the components that differ from the beam-floor joint structure 10 of the first embodiment will be mainly described, and the same components will be given the same reference numerals and will not be described. For components that are not specifically mentioned, the description of the beam-floor joint structure 10 of the first embodiment will be applied as appropriate.

In the fourth embodiment of the beam-floor joint structure 40 shown in Figures 4(a) to (c), the wooden beam 41 is a fireproof beam that includes a load-bearing layer 41a, a side covering layer 41b made of a covering material made of wood that covers both sides of the load-bearing layer 41a and serves as a burnable layer, a bottom covering layer 41c made of a covering material made of reinforced gypsum board that covers the bottom surface of the load-bearing layer and serves as a fireproof layer, and a decorative material 41d made of wood that surrounds both sides and the bottom surface of the bottom covering layer 41c.

In the fourth embodiment of the beam-floor joint structure 40 shown in Figures 4(a) to (c), reinforcing steel members 44 are embedded in the concrete floor slab 12, straddling the upper surfaces of the side covering layers 41b on both sides of the load-bearing layer 41a, and are attached at intervals in the axial direction X of the wooden beam 41, which is the extension direction of the beam. The architectural lattice surface material 16 is fixed integrally to the upper surface of the wooden beam 41 in a divided state at the portion where the reinforcing steel members 44 are attached.

In the fourth embodiment, the architectural lattice surface material 16 formed by overlapping the lower strip layer 14 made of strip plate material 14a and the upper strip layer 15 made of strip plate material 15a in a lattice pattern, which constitutes the shear force transmission means 43, is fixed integrally to the upper surface of the load support layer 41a of the wooden beam 41, and cast-in-place concrete is poured onto the upper surfaces of the load support layer 41a and the side covering layers 41b, which are burnt layers on both sides, so as to cover the entire fixed architectural lattice surface material 16 and reinforcing steel material 44, and then solidified to form a concrete floor slab 12 integrated with the wooden beam 41. In addition, where the gap 14b of the lower strip layer 14 and the gap 15b of the upper strip layer 15 overlap, metal rod-shaped metal fittings 17 are driven from above toward the wooden beam 41 at a predetermined interval in the axial direction X of the wooden beam 41 and are embedded in the concrete floor slab 12 in a standing state from the top surface of the wooden beam 41.

The beam-floor joint structure 40 of the fourth embodiment also has a joint between the wooden beam 41 and the concrete floor slab 12, in which the strip plate material 14a of the lower strip plate layer 14 of the architectural grid surface material 16, the strip plate material 15a of the upper strip plate layer 15, and the cast-in-place concrete that has been filled and solidified in the successive gaps 14b, 15b are interlocked together in a mixed and integrated state, forming a shear force transmission means 43 that can firmly support the shear force along the joint, thereby achieving the same effect as the beam-floor joint structure 10 of the first embodiment described above.

In addition, according to the beam-floor joint structure 40 of the fourth embodiment, the reinforcing steel members 44 are attached at intervals in the axial direction X of the wooden beam 41 so as to straddle the upper surface of the side covering layers 41b on both sides, so that the load support layer 41a and the side covering layers 41b covering both sides of it do not come apart, making it easier to manufacture and install on site. In addition, when pouring the unhardened, fluid concrete onto the formwork, it is not necessary to place the formwork, such as a deck plate or half precast plate, on the load support layer 41a. The reinforcing steel members 44 may be attached to the upper surface of the wooden beam 41, or may be attached by providing a groove on the upper surface of the wooden beam.

The present invention is not limited to the above-mentioned embodiments, and various modifications are possible. For example, in the area where the gaps of the lower and upper strip layers of the architectural grid surface material overlap, it is not necessary that the metal bar-shaped metal fittings are driven toward the wooden beam and embedded in the concrete floor slab. As shown in FIG. 5, the wooden beam 51 to which the architectural grid surface material 16 is attached at the joint with the concrete floor slab 12 has a wooden load-bearing layer 51a, a first covering member 51b covering both sides of the load-bearing layer 51a in one direction Y, a burnt layer 51d fixed via a spacer 51c to the outside of each of the first covering members 51b in one direction Y so as to have a gap 51e between the first covering member 51b, and a second covering member 51f covering one or both sides of the load-bearing layer 51a in the perpendicular direction Z. In the fire-resistant wooden structural material, a corner reinforcing member 51g is arranged on the outer surface side of each of the first covering members 51b on one or both sides having the second covering member 51f in the perpendicular direction Z, and the corner reinforcing member 51g is arranged in a state where it overlaps partially or completely with the outer surface of the first covering member 51b and extends partially from one end of the load support layer 51a in the perpendicular direction Z, and the corner reinforcing member 51g may partially narrow the length of one direction of the gap 51e or partially eliminate the gap 51e.

10, 20, 30, 40, 50 Beam-floor joint structure 11 Wooden beam 12 Concrete floor slab 13, 23, 33, 43, 53 Shear force transmission means 14 Lower strip layer 14a Strip-shaped plate material 14b Gap portion 15 Upper strip layer 15a Strip-shaped plate material 15b Gap portion 16 Architectural grid surface material 17 Metal rod-shaped metal fitting (lag screw)
21 Wooden beam 21a Load support layer 21b Covering layer 31 Wooden beam 31a Load support layer 31b Covering layer 31c Decorative material 41 Wooden beam 41a Load support layer 41b Side covering layer 41c Underside covering layer 41d Decorative material 44 Reinforcing steel material 51 Wooden beam 51a Load support layer 51b First covering member 51c Spacer 51d Burning margin layer 51e Gap 51f Second covering member 51g Corner reinforcing member X Axial direction of wooden beam Y One direction Z Orthogonal direction

Claims (7)

A beam-floor joint structure for integrally joining a wooden beam and a concrete floor slab formed by pouring cast-in-place concrete on the upper surface of the wooden beam,
a shear force transmission means provided at a joint between the wooden beam and the concrete floor slab for transmitting a shear force along the joint between these members;
The shear force transmission means is a beam-floor joint structure in which an architectural lattice surface material is formed by overlapping a lower strip layer made of a plurality of elongated strip-shaped plate materials arranged in parallel at intervals and fixed integrally to the upper surface of the wooden beam, and an upper strip layer made of a plurality of elongated strip-shaped plate materials similarly arranged in parallel at intervals, diagonally crossing the axial direction of the wooden beam in a lattice pattern, and concrete that has solidified and filled in continuously into the gaps between the plurality of strip-shaped plate materials that make up the lower strip layer and the gaps between the plurality of strip-shaped plate materials that make up the upper strip layer when pouring in-situ concrete. The beam-floor joint structure of claim 1, in which metal rods are driven from above into the wooden beams at the overlapping portions of the gaps between the multiple strip-shaped plate materials that make up the lower strip layer and the multiple strip-shaped plate materials that make up the upper strip layer, with their upper portions erected above the top surface of the wooden beams and embedded in the concrete floor slab. The beam-floor joint structure according to claim 1 or 2, wherein the wooden beam is a fireproof beam having a load-bearing layer that is the load-bearing portion and a covering layer made of a covering material that surrounds both sides and the underside of the load-bearing layer. The wooden beam is a fireproof beam comprising a load-bearing layer that is the load-bearing portion, a covering layer made of a covering material made of fire-retardant-injected wood that surrounds both sides and the underside of the load-bearing layer, and a decorative material that surrounds the sides and the underside of the covering layer. The beam-floor joint structure according to claim 1 or 2. The wooden beam is a fireproof beam comprising a load-bearing layer that is the load-bearing portion, a side covering layer made of a covering material made of wood that covers both sides of the load-bearing layer, a bottom covering layer made of a covering material made of reinforced gypsum board that covers the bottom surface of the load-bearing layer, and a wooden decorative material that surrounds both sides and the bottom surface of the bottom covering layer. The beam-floor joint structure according to claim 1 or 2. The beam-floor joint structure according to claim 5, in which reinforcing steel members attached at intervals in the axial direction of the wooden beam are embedded in the concrete floor slab so as to straddle the covering layers on both sides of the load-bearing layer or the top surface of the side covering layers on both sides, and the architectural lattice surface material is fixed integrally to the top surface of the wooden beam in a divided state at the portion where the reinforcing steel members are attached. The wooden beam is a fireproof wooden structural material having a wooden load-bearing layer, a non-combustible first covering member covering both sides of the load-bearing layer in one direction of the cross section, a wooden burnt layer fixed via a spacer to the outside of each of the first covering members in the one direction so as to have a gap between the first covering member and the first covering member, and a second covering member covering one or both sides of the load-bearing layer in a direction perpendicular to the one direction, and a non-combustible corner reinforcing member is arranged on the outer surface side of each of the first covering members on the one or both sides having the second covering member in the orthogonal direction, and the corner reinforcing member is arranged in a state where it overlaps the outer surface of the first covering member in part or in whole and extends from one end of the load-bearing layer in the orthogonal direction, and the corner reinforcing member partially narrows the length of the gap in the one direction or partially eliminates the gap. The beam-floor joint structure according to claim 1 or 2.

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