JP7340671B2 - FRP column beam frame - Google Patents

Description

The present invention relates to an FRP column-beam frame in which a column member and a beam member made of fiber-reinforced plastic are connected.

Fiber-reinforced resins are attracting attention as structural materials for buildings or as members for reinforcing and reinforcing building structures. For example, when increasing the cross-sectional area of members constituting pillars, beams, etc. of a building to increase their strength, this results in an increase in the size and weight of the members. Therefore, in order to suppress the increase in size and weight of the member while ensuring strength, a composite structure in which fiber-reinforced resin is combined with other members such as wood has been proposed.
For example, Patent Document 1 discloses a fiber-reinforced laminated timber formed by arranging and bonding carbon fiber bundles between multiple layers of wood materials. The carbon fiber bundle is arranged inside the fiber-reinforced laminated material at a depth of a predetermined value or more from the outer surface.
Further, Patent Document 2 discloses a structural laminated timber in the shape of a square timber having five or more layers that are integrally bonded together. This structural laminated timber includes an outer layer located at the outermost position, a reinforcing layer adjacent to the outer layer, and an inner adjacent layer sandwiching the reinforcing layer between the outer layer, and the reinforcing layer is equipped with a plurality of square members and a reinforcing fiber sheet arranged in parallel, and the reinforcing fiber sheet is arranged between the square members and the outer layer or the inner adjacent layer, and between adjacent square members. The reinforcing layer is bent and sandwiched so as to extend from one end to the other end in the width direction of the reinforcing layer.
Further, Patent Document 3 describes a pair of flat carbon fiber reinforced resin composite layers provided above and below, and a separate flat carbon fiber reinforced resin composite layer connecting between the pair of flat carbon fiber reinforced resin composite layers. The material layers were configured in an H-shape, and the laminated wood was provided on both sides of the separate flat carbon fiber reinforced resin composite layers between the pair of flat carbon fiber reinforced resin composite layers. A carbon fiber reinforced laminated timber is disclosed.

When using the above-mentioned laminated wood as a beam, for example, it must be supported by some kind of column member.
In the case of laminated wood as disclosed in Patent Document 1 and Patent Document 2, when a fire occurs and the external temperature rises, the external temperature is transmitted to the beam via the column member, and carbon fiber bundles and reinforced fiber sheets temperature may rise and cause melting and combustion. For this reason, it cannot be used in buildings that require fire resistance. In addition, in the carbon fiber reinforced laminated wood as disclosed in Patent Document 3, the pair of flat carbon fiber reinforced resin composite material layers are exposed to the outside, so the fire resistance is low, and the fire resistance is low. Similarly, it cannot be used in buildings that require fire resistance.
Against this background, there is a need for a column-beam structure that can further improve fire resistance.

Japanese Patent Application Publication No. 2007-245431 Japanese Patent Application Publication No. 2010-221514 Japanese Patent Application Publication No. 4-279334

The problem to be solved by the present invention is to provide an FRP column-beam frame that includes a finished part and a fiber-reinforced plastic part with high rigidity and can improve the fire resistance performance of the fiber-reinforced plastic part.

The present inventors constructed an FRP column-beam frame in which a column member and an FRP beam member made of fiber-reinforced plastic were connected, by installing the column head of the column member so as to penetrate the finished part and the fireproof covering part from the outside. By directly joining the bottom or side surface of the fiber-reinforced plastic part, which is a structural resistance element that makes up the FRP beam member, it is possible to firmly connect the column member and the fiber-reinforced plastic while improving fire resistance. With this in mind, we have arrived at the present invention.
In order to solve the above problems, the present invention employs the following means. That is, the present invention provides an FRP column-beam frame in which a column member and an FRP beam member made of a combination of fiber-reinforced plastic and a finishing material are connected, and the FRP beam member has a cross-sectional shape of a rectangular shape or an I-shape. , a fiber-reinforced plastic part formed in either a T-shape or an H-shape, a finished part provided around the outer periphery of the fiber-reinforced plastic part, and a finished part provided between the fiber-reinforced plastic part and the finished part, and a fireproof sheathed portion made of a heat-absorbing material sealed, and the pillar member penetrates the finished portion and the fireproof sheathed portion from the outside and is joined to the fiber-reinforced plastic portion. We provide FRP column and beam structures.
According to the above configuration, a finished part is provided around the outer periphery of the fiber-reinforced plastic part, and a fireproof covering part made of a heat-absorbing material sealed is provided between the fiber-reinforced plastic part and the finished part. ing. Even if the outside temperature rises in the event of a fire, the thermal energy that attempts to be transmitted from the outside to the fiber-reinforced plastic part via the finished part etc. is absorbed by the heat absorbing material of the fireproof covering part. In addition, since the column members penetrate from the outside through a fireproof covering made of sealed heat-absorbing material and are joined to the fiber-reinforced plastic section, in the event of a fire, heat may try to transfer to the FRP beam member via the column members. is similarly absorbed by the heat absorbing material of the fireproof coating.
Therefore, it is possible to suppress the temperature rise of the fiber-reinforced plastic part, and thereby the fire resistance performance of the fiber-reinforced plastic part can be improved.

In one aspect of the present invention, the pillar member supports the bottom surface of the fiber-reinforced plastic part and pinches the side surfaces thereof.
According to the above configuration, the fiber-reinforced plastic part that constitutes the FRP beam member can be supported by the pillar member.

Another aspect of the present invention is characterized in that the column member having a fireproof coating layer is provided in a portion penetrating the finished portion.
According to the above configuration, in the part of the column member that penetrates the finished part, the column member having the fireproof coating layer is arranged, so that the penetrating part is blocked by the column member having the fireproof coating layer. Because of this, it is possible to prevent the spread of fire heat from being transmitted from the column member to the FRP beam member in the event of a fire. In other words, since the amount of heat that is transmitted to the inside of the FRP beam member through the column member in the event of a fire is reduced, it is possible to more effectively suppress the temperature rise in the fiber-reinforced plastic portion.

According to the present invention, it is possible to provide an FRP column-beam frame that includes a finished part and a fiber-reinforced plastic part with high rigidity and can improve the fire resistance performance of the fiber-reinforced plastic part.

FIG. 1 is a schematic side view of an FRP column-beam frame in an embodiment of the present invention. FIG. 2 is an enlarged view of a portion viewed from arrow A in FIG. 1. FIG. FIG. 3 is a longitudinal cross-sectional view taken along the line BB in FIG. 2; (a) is a perspective view, (b) is a sectional view, and (c) is a perspective view of the heat absorbing sheet part provided in the fireproof coating member used in the above FRP column-beam frame. be. They are a front view, a top view, and a side view of an experimental environment in a heating experiment for verifying the effectiveness of a fireproof coating. It is a graph showing the experimental results of the above-mentioned heating experiment. FIG. 3 is an explanatory diagram of an analytical model in a heat conduction analysis targeting a column member. 8 is a graph showing the temperature change of the column member main body in the heat conduction analysis of FIG. 7. FIG. 8 is a graph showing temperature changes at the column joints in the heat conduction analysis of FIG. 7. FIG. 8 is a table showing analysis results in the heat conduction analysis of FIG. 7. FIG. 2 is an explanatory diagram of a heating experiment test piece targeting a column member having a fireproof coating layer. 12 is a list of heating experiment specimens of the column member shown in FIG. 11. It is a comparison table of heating experiment results (foam layer thickness and column surface temperature) of column members. FIG. 7 is a longitudinal cross-sectional view of an FRP beam member constituting an FRP column-beam frame according to a modification of the embodiment.

The present invention is an FRP column-beam frame in which a column member and an FRP beam member made of fiber-reinforced plastic are joined. One of the features of the present invention is that the column member provided with the fireproof coating layer penetrates the wooden part (finished part) constituting the FRP beam member and supports the bottom and side surfaces of the fiber-reinforced plastic part. The penetrating portion of the finished part is completely covered with a column member provided with a fireproof coating layer.
Embodiments of the present invention will be described in detail below with reference to the drawings.
FIG. 1 is a schematic side view of a structure using an FRP column-beam frame in this embodiment. This structure is installed outside the building 1. The building 1 has an upper structure 1a and a lower structure 1b. The upper structure 1a is provided above the lower structure 1b. The upper structure 1a has a smaller installation area in a horizontal plane than the lower structure 1b, so that the roof portion 4 is provided on the lower structure 1b at a portion other than the portion where the upper structure 1a is provided.
The structure is installed on the roof part 4 of the building 1. The structure is formed using an FRP column-beam frame 2. The FRP column-beam frame 2 includes column members 5 and beams (FRP beam members) 3. The beam 3 is supported by a plurality of column members 5A to 5F. In this embodiment, the pillar members 5A to 5F are provided on the roof portion 4 and the iron base material 4s laid on the roof portion 4. Among the pillar members 5A to 5F, the pillar member 5A closest to the upper structure 1a extends in the vertical up-down direction. With respect to the column member 5A, two column members 5B and 5C on the side away from the upper structure 1a extend upward and inclined toward the upper structure 1a side. On the roof portion 4, the two pillar members 5D and 5E on the side farthest from the upper structure 1a extend upward and at an angle in a direction away from the upper structure 1a. The column member 5F extends upward from the intermediate portion of the column member 5D in an inclined direction toward the upper structure 1a.
The beam 3 is provided on these column members 5A to 5F. The beam 3 is provided in a curved manner so as to gradually extend upward as it moves away from the upper structure 1a side.
A plurality of sets of such pillar members 5A to 5F and beams 3 are provided at intervals in a direction perpendicular to the paper plane of FIG.
A roof portion 10 is provided on the plurality of beams 3 of the FRP column-beam frame 2 as described above.

FIG. 2 is an enlarged view of a portion viewed from arrow A in FIG. In FIG. 2, regarding the beam 3, only the fiber-reinforced plastic part 11 and the finished part 20, which will be described later, are drawn with solid lines and broken lines, respectively, and other components are omitted. The column member 5 includes a column member main body 6 and a joining member 7 that is joined above the column member main body 6 to join and support the beam 3. In this embodiment, the finished part 20 is wood. The column member main body 6 is formed of a long tubular body 6a. In this embodiment, the tubular body 6a is made of an aluminum alloy. A fireproof coating layer 6b having a predetermined thickness is formed on the surface of the tube body 6a by applying a foaming fireproof paint. Examples of fireproof coating materials include SK Taika Coat (registered trademark) and SK Taika Sheet (registered trademark) from SK Kaken Co., Ltd., and INTERHANE (registered trademark), INTERCHAR (registered trademark), and INTERGARD (registered trademark) from Akzo Nobel Corporation. etc. can be used, but is not limited to this. The pillar member main body 6 is provided so as to extend vertically from the roof portion 4 and the base material 4s shown in FIG. 1 to just below the beam 3.
The joining member 7 includes a pillar joining part 8 that is joined to the pillar member main body 6 and a beam joining part 9 that is joined to the upper end of the pillar joining part 8 and joined to the beam 3. The column joint portion 8 is formed by a plate body 8a. In this embodiment, the plate body 8a is made of steel. A fireproof coating layer 8b having a predetermined thickness or more is formed on the surface of the plate body 8a by applying a fireproof coating material or the like. As the fireproof coating material, the same material as the fireproof coating layer 6b of the column member main body 6 may be used. The fireproof coating layer 8b is not provided near the upper end of the plate 8a, so that the plate 8a is exposed.
In the column member 5D, a splice plate 5a is provided along the surfaces of the column member main body 6 and the column joint portion 8 of the joining member 7, so that the splice plate 5a, the column member main body 6, and the column joint portion are connected to each other. 8 by tightening a high tension bolt 5b. In the column member 5E, the column member main body 6 and the column joint portion 8 are joined via a fork end pin 5c.
The steel column joint part 8 is connected to the upper end side of the column member body 6 where the fiber reinforced plastic part 11 with an allowable temperature of 200°C and the aluminum column member main body 6 with an allowable temperature of 260°C joins from the aluminum column side. It is provided to suppress the heat transfer temperature to 200°C or less and to ensure a predetermined distance between the aluminum column and the fiber-reinforced plastic part. The length of the column joint 8 was set to 200 mm based on the fire resistance performance confirmation experiment of fiber reinforced plastic beam members and the results of heat conduction analysis, which will be described later.

FIG. 3 is a sectional view taken along the line BB in FIG. The beam joint portion 9 includes a bottom plate 9a located on the lower side and a pair of side plates 9b. The bottom plate 9a is formed in a rectangular shape, and is provided perpendicularly to the column joint part 8 and joined at the upper end of the column joint part 8. The bottom plate 9a is provided such that the center portion of the bottom plate 9a in the width direction is located at the upper end of the column joint portion 8. The side plates 9b are connected to both sides of the bottom plate 9a in the width direction and are provided so as to extend upward. In this way, the pair of side plates 9b are provided so as to face each other, and the distance between the opposing side plates 9b is set so that the width of the fiber-reinforced plastic portion 11 of the beam 3, which will be described later, is approximately equal to the width of the beam joint. 9 is formed.

The beam 3 includes a fiber-reinforced plastic part 11 having a rectangular cross-sectional shape and a finished part 20, and is constructed by combining fiber-reinforced plastic and wood (finishing material).
The fiber-reinforced plastic portion 11 is made of fiber-reinforced plastic that is formed into the above shape by impregnating reinforcing fibers such as carbon fibers, aramid fibers, and vinylon fibers with resin.
The fiber-reinforced plastic portion 11 has a rectangular cross-sectional shape intersecting the central axis. That is, the fiber-reinforced plastic part 11 includes an upper plate part 11a and a lower plate part 11b that are spaced apart from each other in the vertical direction, and a pair of side plate parts 11c that connect these parts. When the fiber-reinforced plastic part 11 is viewed in cross section as shown in FIG. 3, the side plate part 11c is joined to each side end of the upper plate part 11a and the lower plate part 11b, and connects them between the upper and lower parts. It is set up like this. A body part 11d of the fiber-reinforced plastic part 11 is formed by the upper plate part 11a, the lower plate part 11b, and the pair of side plate parts 11c. , and a hollow portion S surrounded by a pair of side plate portions 11c is formed.
As described later, the fiber-reinforced plastic part 11 is joined to the column member 5. Through-holes 11r for joining with the column member 5 are provided at predetermined intervals in the length direction in the portions of the lower plate part 11b and the side plate part 11c to be joined to the column member 5.
The body portion 11d of the fiber-reinforced plastic portion 11 is embedded (buried) in the center of the beam 3 in a cross section intersecting the central axis extending in the longitudinal direction of the beam 3. That is, the body portion 11d of the fiber-reinforced plastic portion 11 is not exposed to the outside of the beam 3.

The fiber-reinforced plastic part 11 is joined to and supported by the beam joint part 9 of the column member 5. The fiber-reinforced plastic part 11 is positioned so as to be sandwiched between the side plates 9b of the beam joint part 9, and placed on the bottom plate 9a.
In this way, the column member 5 is provided to support the bottom surface 11q of the fiber-reinforced plastic part 11 and to sandwich the side surface 11u.
A through hole 9s is provided at a position corresponding to the column joint through hole 11r in the bottom plate 9a and side plate 9b of the beam joint part 9, which face and contact each of the lower plate part 11b and the side plate part 11c of the fiber reinforced plastic part 11. It has been established. A bolt 9c is inserted from the outside of the beam joint part 9 toward the fiber-reinforced plastic part 11 and tightened so as to pass through the correspondingly provided through hole 9s and column joint through hole 11r.

A protruding body 11p that protrudes outward from the body portion 11d is provided around the outer periphery of the fiber-reinforced plastic portion 11. In particular, in this embodiment, the protruding body 11p is provided so as to protrude upward from the upper surface of the upper plate portion 11a. The protruding body 11p is formed into a flat plate shape and is provided so as to extend in the longitudinal direction of the beam 3.
The protruding body 11p is provided with first and second through holes 11s and 11t. These through holes 11s and 11t are spaced apart from each other such that the first through hole 11s is located below the second through hole 11t. A plurality of first and second through holes 11s and 11t are each provided at predetermined intervals in the longitudinal direction of the beam 3.

An inner connector 12 is joined to each of the two side surfaces of the protrusion 11p. The inner joint tool 12 includes two plate parts 12a and 12b, which are joined perpendicularly to each other at their sides, thereby forming an L-shaped cross section. The inner connector 12 is arranged such that one plate part 12a is along the protrusion 11p, and the other plate part 12b is located above the plate part 12a and is approximately parallel to the upper plate part 11a of the fiber-reinforced plastic part 11. It is provided. The inner connector 12 is protruded by a bolt 12c inserted through a through hole 12d provided in each of two plate parts 12a provided along both side surfaces of the protrusion 11p and a first through hole 11s of the protrusion 11p. It is joined to the body 11p.
An outer connector 13 is joined to each of the inner connectors 12 . Like the inner connector 12, the outer connector 13 is also formed with two plate portions 13a and 13b so that the cross section thereof is L-shaped. The outer connector 13 has one plate portion 13b that contacts and follows the plate portion 12b of the inner connector 12, and the other plate portion 13a that is located outside of the plate portion 13b and extends along the fiber-reinforced plastic portion 11. It is provided so as to be substantially parallel to the side plate portion 11c, and is joined to the inner joining tool 12.

A flat vertical connecting member 14 is joined to the outer surface of the plate portion 13a of the outer joint tool 13 so as to extend downwardly along the outer surface of the plate portion 13a.
A lower connector 15 is connected to the lower end of each of the vertical connecting members 14 . Similarly to the inner connector 12, the lower connector 15 is also formed with two plate portions 15a and 15b so as to have an L-shaped cross section. In the lower joint 15, one plate part 15a is joined along the inner surface of the vertical connection member 14, and the other plate part 15b is located inside the plate part 15a and is connected below the fiber reinforced plastic part 11. It is provided so as to be substantially parallel to the plate portion 11b, and is joined to the vertical connection member 14.
In this way, the inner connector 12, the outer connector 13, the vertical connection member 14, and the lower connector 15 connect the body portion of the fiber-reinforced plastic part 11 in a cross section intersecting the central axis extending in the longitudinal direction of the beam 3. A rectangular outer shell 16 is formed that surrounds 11d from the outside.
Among the inner connector 12, the outer connector 13, the vertical connection member 14, and the lower connector 15, at least the inner connector 12 and the outer connector 13 are formed short in the longitudinal direction of the beam 3. 3 at intervals in the longitudinal direction.

The finished part 20 is provided around the outer periphery of the fiber-reinforced plastic part 11. The finished part 20 includes two side plate parts 20a and two lower plate parts 20b.
The side plate portions 20a are each provided on the outside of the vertical connection member 14 along the vertical connection member 14, and are tightened by tightening the screws 21 from the inside of the outer shell portion 16 toward the side plate portions 20a located on the outside. , are fixed to the vertical connecting member 14.
The two lower plate parts 20b are respectively provided below the plate part 15b of the lower connector 15 along the plate part 15b, and are fixed to the plate part 15b with bolts and nuts 22. The lower plate portion 20b is thus provided so as to face inward. The inner end surfaces 20d of these two lower plate portions 20b are provided so as to face the surface of the column joint portion 8, particularly the fireproof coating layer 8b, in close proximity to or in contact with the surface. In this way, the column joint part 8 of the column member 5 is provided so as to pass through the gap G provided between the lower plate parts 20b of the finished part 20, and the column joint part 8 is provided in the part passing through this gap G. 8 fireproof coating layers 8b are coated.
By providing the side plate portion 20a and the lower plate portion 20b in this manner, the side and lower portions of the body portion 11d of the fiber-reinforced plastic portion 11 are covered with the finished portion 20.
In addition, the finished part 20 includes an inner connector 12, an outer connector 13, a vertical connecting member 14, a lower connector 15, and a bolt 12c inserted through the first through hole 11s of the protrusion 11p. It is fixed to the fiber reinforced plastic part 11.

A fireproof covering part 30 is provided between the body part 11d of the fiber-reinforced plastic part 11, the outer shell part 16, and the finished part 20. In this embodiment, the fireproof coating portion 30 is provided with a fireproof coating member 30A such as Aqua Cover (registered trademark). FIG. 4(a) is a perspective view of the fireproof coating member, FIG. 4(b) is a sectional view of the fireproof coating member, and FIG. 4(c) is a perspective view of a heat absorbing sheet portion provided within the fireproof coating member. The fireproof covering member 30A includes a mat portion 31, a heat absorbing sheet portion 32, and an outer covering material 35 for packaging and covering these from the outside.
The mat portion 31 is made of refractory ceramic fiber, for example.
The heat absorbing sheet portion 32 includes a heat absorbing material 33 and a covering material 34. The covering material 34 is formed into a film shape by laminating, for example, polyethylene, aluminum foil, and nylon. The heat absorbing sheet portion 32 is formed by placing two sheets of the covering material 34 facing each other and sealing the heat absorbing material 33 therebetween. The heat absorbing material 33 is, for example, water, a high-molecular absorption polymer that retains water, or the like.
When a fire occurs and the outside temperature rises, the fireproof covering member 30A absorbs heat by evaporating the water in the heat absorbing material 33, and this heat absorption suppresses the temperature rise of surrounding members.
A plurality of fireproof coating members 30A are stacked one on top of the other and bent to fit in the space S1 between the body portion 11d of the fiber-reinforced plastic portion 11 and the finished portion 20. In particular, the fireproof covering part 30 is provided below the fiber-reinforced plastic part 11 so as to be penetrated by the pillar joint part 8 of the pillar member 5 joined thereto. The fireproof covering part 30 is provided so that the heat-absorbing sheet part 32 is in close contact with each member forming the space S1. As already explained, since the fireproof coating layer 8b is not provided near the upper end of the column joint 8 and the plate 8a is exposed, the fireproof coating 30 is provided in direct contact with the plate 8a. It is being

As shown in FIG. 3, the roof portion 10 is supported by the FRP column-beam frame 2 formed as described above. The roof section 10 includes an aggregate 81, a roof connecting member 82, a roof material 84, and a cover member 86.
The aggregate 81 is provided above the beam 3 and supports the roof portion 10. The aggregate 81 includes an upper plate portion 81a located on the upper side and a pair of side plate portions 81c. The side plate portion 81c is connected to the side end portion of the upper plate portion 81a and is provided so as to extend downward. In this way, the upper plate part 81a and the pair of side plate parts 81c are formed so that the cross-sectional shape intersecting the central axis is C-shaped, and the fiber-reinforced plastic part 11 is placed in the space S2 formed thereby. The aggregate 81 is positioned such that the protruding body 11p is accommodated and each lower end of the side plate portion 81c is located on the plate portion 13b of the outer joint tool 13.
Roof connecting members 82 are bonded to the inside of the aggregate 81 at predetermined intervals in the longitudinal direction of the beam 3. The roof connecting member 82 is formed along the protrusion 11p while partially contacting it. The aggregate 81 is joined to the protruding body 11p by bolts and nuts 83 inserted through each of the through holes 82d provided in the roof connecting member 82 and the second through hole 11t of the protruding body 11p.
A roofing material 84 formed in a panel shape is positioned above the aggregate 81, and these are fixed to each other via bolts and nuts 85 and the like.

A fireproof covering section 40 having the same configuration as the fireproof covering section 30 is provided also in the space S2 formed by each plate section 81a, 81c of the aggregate 81 and the protruding body 11p. The fireproof covering part 40 is made by stacking a plurality of fireproof covering members 30A as described above, and is bent so as to fit into the space S2, and in particular, so that the heat absorbing sheet part 32 is in close contact with each member forming the space S2. It is provided.
As described above, since the inner connector 12 and the outer connector 13 are formed short in the longitudinal direction of the beam 3, the lower space S1 and the upper space S2 of the inner connector 12 are At the longitudinal cross-sectional position of the beam 3 where the outer connector 12 and the outer connector 13 are not provided, there are spaces S1 and S2 that communicate with each other. For example, in such a portion, the fireproof covering portions 30 and 40 are integrally constructed.
A cover member 86 is provided so as to span each of the outer surfaces of the two side plate portions 81c of the aggregate 81 and the upper end of the side plate portion 20a of the finished portion 20. Thereby, a space S3 is formed that is surrounded by the outer surface of the side plate portion 81c, the upper surface of the plate portion 13b of the outer connector 13, and the cover member 86. A heat insulating material 41 is provided within this space S3.

If a fire occurs in the FRP column-beam frame 2 as described above and the external temperature rises, even if heat tries to be transferred to the inside of the beam 3 due to combustion of the finished part 20, the fireproof covering part provided in the space S1 Since the water in the body 30 evaporates and absorbs this heat, a temperature rise above a certain level in the body portion 11d is suppressed.
In addition, external heat is also transmitted through the plate part 13b of the outer joint tool 13 and the plate part 12b of the inner joint tool 12, which join the finishing part 20 and the fiber reinforced plastic part 11. can be transmitted to. In this case, first, the outer connector 13 is heated by the heat insulating material 41 provided on the plate portion 13b of the outer connector 13 and the fireproof coating 30 provided in the space S1 so as to be in close contact with the outer connector 13. Heat transfer via the plate portion 13b of 13 is suppressed. Furthermore, even if heat is transferred from the plate part 13b of the outer connector 13 to the plate part 12b of the inner connector 12, a fireproof structure provided in each of the spaces S1 and S2 so as to be in close contact with the inner connector 12 is provided. The covering portions 30 and 40 suppress further transfer of heat to the protruding body 11p.

Particularly below the beam 3, heat is transferred from the column member main body 6 made of aluminum alloy to the fiber-reinforced plastic portion 11 of the beam 3 via the steel joining member 7. In this part, aluminum alloy and fiber-reinforced plastic are joined via steel, and since aluminum alloy and fiber-reinforced plastic have different allowable temperatures in the event of a fire, heat is transferred from the member with a higher allowable temperature, that is, the aluminum alloy. As a result, the temperature of the member having a low allowable temperature, that is, the fiber-reinforced plastic increases, and the fiber-reinforced plastic may be destroyed. More specifically, if the allowable temperature for aluminum alloy is 260°C and the allowable temperature for fiber-reinforced plastic is 200°C, there is a possibility that the temperature of fiber-reinforced plastic will exceed 200°C due to heat transfer from the aluminum alloy. .
On the other hand, in this embodiment, the tube body 6a of the column member body 6 and the plate body 8a of the column joint part 8 are coated with fireproof coating layers 6b and 8b, respectively. Therefore, in the event of a fire, the rise in temperature of the column member main body 6 is suppressed, and the transfer of heat from the column member main body 6 via the plate 8a is suppressed.
Furthermore, a fireproof covering part 30 is provided in the space S1 in the beam 3 in which the column joint part 8 is provided. In particular, near the upper end of the column joint 8, the plate 8a is not covered with the fireproof coating layer 8b, and the fireproof coating 30 provided in contact with the plate 8a directly absorbs heat from the plate 8a. Therefore, heat transfer via the column joints 8 is suppressed.
By combining the above factors, as will be explained in detail later in the experimental results, even if the column member main body 6 made of aluminum alloy rises to 260℃, the temperature of the steel material of the column joint 8 will be kept below 200℃. The temperature of the fiber-reinforced plastic portion 11 can be kept at 200° C. or lower.

(Experiment to confirm fire resistance performance of fiber-reinforced plastic beams and heat conduction analysis)
Elemental experiments were conducted to confirm the fire resistance performance of the fireproof coatings that make up the beam members made of fiber-reinforced plastic.
First, a heating experiment and its results regarding the effectiveness of the fireproof coatings 30 and 40 used in this embodiment will be described. FIG. 5 is a front view, a top view, and a side view of the experimental environment in the heating experiment.
In this experiment, a fiber-reinforced plastic part 100 with a width of 60 mm and a length of 900 mm was used. This fiber-reinforced plastic part 100 was arranged facing the furnace 103, and a fireproof coating member 101 was provided between the fiber-reinforced plastic part 100 and the furnace 103. The fireproof coating member 101 had a structure of 26 mm by stacking two 13 mm thick aqua covers. Under this situation, the fiber reinforced plastic part 100 was heated 102 for 30 minutes from the opposite side of the fireproof covering member 101 according to the standard heating temperature curve described in ISO834. After extinguishing the fire, temperature measurements were continued until the maximum temperature of the fiber-reinforced plastic part 100 was confirmed. The temperature was measured at three locations on the fiber-reinforced plastic part 100: south position P11, center position P12, and north position P13.
FIG. 6 is a graph showing the experimental results of the above heating experiment. Even when the temperature inside the furnace 103 is heated to exceed 800°C, as shown by the line 105, the maximum temperature of the fiber-reinforced plastic part 100 is about 105°C, as shown by the line 104. there were. The fiber-reinforced plastic part can exhibit strength when used as a structure if it can be maintained at about 200°C or less, but the maximum temperature was significantly lower than this allowable temperature.
Therefore, it is possible to satisfy the necessary fire resistance performance with respect to the configuration of a fiber-reinforced plastic beam member that is installed with a fiber-reinforced plastic part provided in the center of the beam cross section, a fire-resistant coating part provided on the outer peripheral surface, and a finished part. was confirmed.

Next, a heat conduction analysis was performed on the fiber-reinforced plastic beam members, and the fire-resistant performance and fire-resistant structural performance of the fiber-reinforced plastic beam members were confirmed. The column member portion of the FRP column-beam frame 110 as shown in FIG. 7(a) was modeled as shown in FIG. 7(b).
In this analysis model 110A, the tube body 111a of the column member main body 111 is made of aluminum alloy with a density of 2700 kg/m ³ , a specific heat of 903 J/(kg・K), and a thermal conductivity of 190 W/(m・K). did. The length and width of the tubular body 111a were 8000 mm and 150 mm, respectively. The tube body 111a was coated with Interchar 212, a fire-resistant paint manufactured by Akzo Nobel, to a thickness of 12.9 mm. FIG. 8 shows a temperature change when such a tube body 111a is heated for 30 minutes according to the standard heating temperature curve of ISO834. The maximum temperature is below 260°C, which is the allowable temperature for aluminum alloys.
The plate 112a of the column joint 112 was made of steel having a density of 7850 kg/m ³ , a specific heat of 481 J/(kg·K), and a thermal conductivity of 52 W/(m·K). The width of the plate 112a was 150 mm, the same as the tube 111a, and the length L was variable. A fireproof coating layer 112b was set on the column joint 112 using a ceramic blanket to have a thickness of 15 mm. FIG. 9 shows the temperature change when such a plate 112a is heated for 30 minutes according to the standard heating temperature curve of ISO834.
For the above analytical model 110A, the temperature change as described above was applied to each member, the length L of the plate 112a was changed as a parameter, and the temperature change in each part was analyzed by FEM heat conduction analysis.
Figure 10 shows the analysis results. It was found that if the length L of the plate 112a is 200 mm or more, the temperature of the upper end 112c of the plate 112a will be 200°C or less, and the temperature of the fiber-reinforced plastic part 113 will be 200°C or less, which is the allowable value. .

Next, a heating experiment was conducted on the column members having the fire-resistant coating layer constituting the FRP column-beam frame, and the fire-resistant performance and fire-resistant structural performance of the column members were confirmed.
FIG. 11 is an explanatory diagram of a test specimen in a heating experiment. Moreover, FIG. 12 is a list of test specimens. The test specimens 120 of the column member main bodies 6 each had a height of 1.2 m and a heating range length of 1 m. As for the cross-sectional shapes of the test specimens 120, a round cross-section test specimen 120A having a round cross section and an H-shaped cross-sectional test specimen 120B having an H-shaped cross section were used. In addition to this cross-sectional shape, a total of 12 test specimens 120, two for each type, were prepared using the fireproof coating material and coating thickness as parameters. For all types of test bodies 120, one test body 120 was used for each of the standard heating temperature curve specified in ISO834 and the heating temperature curve corresponding to the case where the fire temperature increase coefficient α was set to 295.
In either case, measurements were continued until the maximum temperature of the aluminum alloy was confirmed. In the heating temperature curve corresponding to the case where the fire temperature increase coefficient α was 295, the fire duration time was 22 minutes, but heating was performed for a longer time of 30 minutes.
FIG. 13 is a table showing the results of the heating test. In this table, the thickness of the foam layer was measured at three locations shown as a, b, and c in FIG. 11(c). In the standard heating temperature curve test, the temperature of the aluminum alloy exceeded the allowable value (260 degrees) in A1, which had a round cross-sectional shape, but fell below the allowable value for the other test specimens. In the test of the heating temperature curve corresponding to the case where the fire temperature increase coefficient α was 295, all test specimens 120 were below the allowable value.
Therefore, by applying a predetermined thickness of foamable fire-resistant paint to the aluminum alloy column members constituting the FRP column-beam frame of the present invention to form a fire-resistant coating layer, the necessary fire resistance required for the FRP column-beam frame can be achieved. It was confirmed that performance could be ensured.

Next, the effects of the above-mentioned FRP column-beam frame will be explained.

The FRP column-beam frame 2 of the above embodiment is an FRP column-beam frame 2 in which column members 5 and FRP beam members (beams) 3 made of a combination of fiber-reinforced plastic and finishing materials are connected. 3 is a fiber-reinforced plastic part 11 having a rectangular cross-sectional shape, a finished part 20 provided around the outer periphery of the fiber-reinforced plastic part 11, and a part provided between the fiber-reinforced plastic part 11 and the finished part 20. The column member 5 penetrates the finished part 20 and the fireproof coating part 30 from the outside and is joined to the fiber-reinforced plastic part 11. It is characterized by
According to the above configuration, the finished part 20 is provided around the outer periphery of the fiber-reinforced plastic part 11, and the heat-absorbing material 33 is sealed between the fiber-reinforced plastic part 11 and the finished part 20. A covering portion 30 is provided. Even if the external temperature rises in the event of a fire, the thermal energy that attempts to be transmitted from the outside to the fiber-reinforced plastic part 11 via the finished part 20 and the like is absorbed by the heat absorbing material 33 of the fireproof covering part 30. In addition, since the column member 5 penetrates from the outside the fireproof covering part 30 formed by the heat absorbing material 33 and is joined to the fiber reinforced plastic part 11, heat is transferred to the FRP beam through the column member 5 in the event of a fire. Even if the heat is to be transmitted to the inside of the member 3, it is similarly absorbed by the heat absorbing material 33 of the fireproof coating 30.
Therefore, it is possible to suppress the temperature rise of the fiber-reinforced plastic part 11, and thereby, the fire resistance performance of the fiber-reinforced plastic part 11 can be improved.

Moreover, the column member 5 is characterized in that it supports the bottom surface 11q of the fiber-reinforced plastic part 11 and clamps the side surface 11u.
According to the above configuration, the fiber-reinforced plastic part 11 can be firmly fixed to the column member 5.

Further, the column member 5 having a fireproof coating layer 8b is provided in a portion penetrating the finished portion 20.
According to the above configuration, in the part of the column member 5 that penetrates the finished part 20, the column member 5 having the fireproof coating layer 8b is arranged, so that the penetrating part passes through the fireproof coating layer 8b. Since it is blocked by the column member 5 having the structure, it is possible to prevent the spread of fire heat from being transmitted from the column member 5 to the FRP beam member 3 in the event of a fire. That is, since the total amount of heat transmitted to the inside of the FRP beam member 3 via the column member 5 in the event of a fire is reduced, it is possible to suppress the temperature rise in the fiber-reinforced plastic portion 11 more effectively.

Further, a through hole 11r is provided in a portion of the fiber-reinforced plastic portion 11 supported by the column member 5, and the fiber-reinforced plastic portion 11 is joined to the column member 5 using a bolt 9c.
Generally, it is not easy to drive a nail or the like into a fiber-reinforced plastic part, but according to the above structure, the through-hole 11r is formed in the fiber-reinforced plastic part 11, and the column member 5 is connected to the through-hole 11r. Since the beam joint portions 9 of the members 7 are joined by the bolts 9c, these can be easily and reliably joined.

Note that the FRP column-beam frame of the present invention is not limited to the above-described embodiment described with reference to the drawings, and various other modifications are possible within the technical scope thereof.
For example, the cross-sectional shape of the fiber-reinforced plastic portion 11 is not limited to a rectangular shape. Various modifications of the cross-sectional shape of the fiber-reinforced plastic part 11 are shown in FIG.
The fiber-reinforced plastic portion 11A in FIG. 14(a) includes a pair of narrow flange portions 11e and 11f that are spaced apart in the vertical direction, and a web portion 11g that connects these flange portions 11e and 11f. , and is formed to have an I-shaped cross section. The beam joint portion 9A of the FRP column-beam frame 2A that supports such a fiber-reinforced plastic portion 11A has a shape corresponding to this. That is, the beam joint 9A includes a pair of flange clamping parts 9e and a pair of web clamping parts 9f. Each of the pair of flange holding parts 9e has a shape such that it bulges outward from the upper end of the column joint part 8A on both end sides of the flange part 11f, then extends upward, and then goes inward. The flange portion 11f is formed to be housed and fixed between a pair of opposing flange holding portions 9e. Each of the pair of web clamping parts 9f is provided so as to extend upward from the inner end of each flange clamping part 9e, and the web part 11g is accommodated between the pair of web clamping parts 9f. It is formed. The web portion 11g and the pair of web holding portions 9f each have a through hole (not shown) at a corresponding position, and a bolt (not shown) is inserted through the through hole and is tightened and fixed.

The fiber-reinforced plastic part 11B in FIG. 14(b) includes one flange part 11h and a web part 11i provided to extend above the flange part 11h, and has a cross-sectional shape of T. It is formed to have a shape.
The fiber-reinforced plastic portion 11C in FIG. 14(c) also has a pair of flange portions 11j and 11k that are spaced apart in the vertical direction and have a longer width than the flange portions 11e and 11f of the fiber-reinforced plastic portion 11A. , and a web portion 11l that connects these flange portions 11j and 11k, and is formed to have an H-shaped cross section.
The beam joint portion 9B of the FRP column-beam frame 2B that supports such fiber-reinforced plastic portions 11B and 11C has a common shape corresponding thereto. Like the beam joint 9A, the beam joint 9B includes a pair of flange clamping parts 9g and a pair of web clamping parts 9f. The flange clamping part 9g of the beam joint part 9B is provided so as to extend outward longer than the flange clamping part 9e of the beam joint part 9A, in accordance with the shape of the flange parts 11h and 11k that it clamps.

In addition to the above, the shape is not limited to the above as long as the fiber reinforced plastic portion 11 has sufficient strength. For example, the cross-sectional shape may be circular or oval. In this case, the inside of the fiber-reinforced plastic part 11 may be hollow as in the above embodiment, or may be formed solid, that is, without any space.
In this case, it goes without saying that the beam joint portion 9 is formed in a corresponding shape.
Similarly, the fiber-reinforced plastic part 11 may have a rectangular cross section as in the above embodiment, but may be formed solid.
Furthermore, in the above embodiment, the FRP beam member is formed by combining fiber-reinforced plastic and the finishing material (wood), but the finishing material is not limited to wood, and may include gypsum board, Keikal board, metal plate, or A plastic plate may also be used.
In addition to this, it is possible to select the configurations mentioned in the above embodiments or to change them to other configurations as appropriate, without departing from the gist of the present invention.

2 FRP column and beam frame 11, 11A to 11C Fiber reinforced plastic part 3 Beam (FRP beam member) 11p Projection body 5, 5A to 5F Column member 11q Bottom surface 6 Column member body 11u Side surfaces 6b, 8b Fireproof coating layer 20 Wooden part (finished part )
7 Joint member 30, 40 Fireproof covering part 8 Column joint part 33 Heat absorbing material 9 Beam joint part

Claims (2)

An FRP column-beam frame in which a column member and an FRP beam member made of a combination of fiber-reinforced plastic and finishing material are connected,
The FRP beam member includes a fiber-reinforced plastic portion having a cross-sectional shape of a rectangular shape, an I-shape, a T-shape, or an H-shape;
a finished part provided around the outer periphery of the fiber-reinforced plastic part;
a fireproof covering part in which a heat-absorbing material is sealed and provided between the fiber-reinforced plastic part and the finished part;
The FRP pillar-beam frame is characterized in that the pillar member is joined to the fiber-reinforced plastic part. The FRP column-beam frame according to claim 1, wherein the column member having a fireproof coating layer is provided in a portion penetrating the finished part.

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