JP2007262660A - Method of mounting bearing wall panel, bearing wall panel, and building structure - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a method of mounting a bearing wall panel capable of preventing a bearing wall panel from being ruptured by load concentration even when the bearing wall panel formed of a sheet lightweight shape steel is installed on a frame composed of wooden columns and beams with different mechanical properties. <P>SOLUTION: In this method of mounting the bearing wall panel, the bearing wall panel 7 formed by mounting a surface material 15 on the frame materials 11a, 11b, 13a, 13b formed of the sheet lightweight shape steel is mounted on the frame having the wooden columns 3 and beams 5. The bearing wall panel 7 is mounted on the frame with a mounting member 13a for absorbing a vertical force interposed therebetween. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a mounting method of a load-bearing wall panel in which a load-bearing wall panel made of a thin lightweight steel frame material is installed on a frame made of wooden columns and beams, a load-bearing wall panel, and a building structure to which the load-bearing wall panel is attached. About.

  FIG. 3 is an explanatory diagram of the structure of a general steel house whose roof is composed of a truss 43 including a truss upper chord member 43a, a truss bundle member 43b, a reinforcing bundle member 43c, a reinforcing oblique member 43d, and a truss lower chord member 43e. Non-patent document 1). As shown in FIG. 3, the steel house has a load-bearing wall panel 42 in which a face member or a brace is attached to a frame member 41 made of a thin, lightweight steel as a main frame element.

Further, the load-bearing wall of the steel house is characterized in that the panel frame is made of steel and the face material or brace is joined to the screw fastening, so that it is easy to manufacture and has high dimensional accuracy and high strength. In addition, there are many excellent points that the shape does not be warped or distorted by drying like a wooden bearing wall, even if it is made and kept in stock. When this load bearing wall with excellent characteristics is applied to a wooden structure, it is expected to greatly improve the earthquake and wind resistance performance of the wooden structure.
However, there are various problems in using a combination of steel and wood having different mechanical properties as they are.
KC type steel house construction standard specification, issued by Steel House Association, P105, revised in October 2004

Wood members have dimensional changes due to drying shrinkage, which are not found in steel members, and dimensional changes due to creep phenomenon due to continuous load. Further, the thermal expansion coefficient differs between the wooden member and the steel member.
When wood members and steel members having completely different mechanical properties are used together as the same vertical member, the load is concentrated on the steel member due to the difference in the above characteristics between the wood member and the steel member, causing various obstacles. This may cause the steel member to break.

For example, when installing a load-bearing wall panel made of a thin, lightweight steel frame on a frame made of wooden pillars and beams, when installed by the general steel house mounting method described above, Such a problem arises.
The height of the frame is lowered due to drying shrinkage and creep phenomenon of wooden columns and beams. For this reason, the load concentrates on the load-bearing wall panel, causing various obstacles, and the load-bearing wall panel may be destroyed.

The present invention has been made to solve such a problem, and even when a load-bearing wall panel made of thin lightweight steel is installed on a frame comprising wooden columns and beams having different mechanical properties, the load-bearing wall is provided. An object of the present invention is to provide a mounting method for a load-bearing wall panel in which loads are not concentrated on the panel and destroyed.
It is another object of the present invention to provide a load-bearing wall panel capable of such an attachment method and a building structure to which the load-bearing wall panel is attached.

(1) The load-bearing wall panel mounting method according to the present invention includes a load-bearing wall panel in which a face member or a brace is attached to a frame material made of a thin, lightweight steel, and is installed on a frame having wooden columns and beams. A wall panel mounting method is characterized in that the load-bearing wall panel is mounted via a mounting member that absorbs a vertical force.

(2) The mounting member according to (1) is a groove-shaped member extending in the width direction of the load-bearing wall panel, and has a bent portion in which both sides of the flange bend inward or outward. It is characterized by being.

(3) Moreover, the attachment member as described in said (1) or (2) is an upper side frame material which comprises the frame material of a load-bearing wall panel, It is characterized by the above-mentioned.

(4) Moreover, the load-bearing wall panel according to the present invention is a load-bearing wall panel in which a face material or a brace is attached to a thin lightweight steel frame material, and the upper side frame material constituting the frame exerts a vertical force. It is characterized by having a vertical force absorbing function capable of absorbing.

(5) Moreover, the upper side frame member described in the above (4) is a groove-shaped member having a bent portion in which both side walls bend inward or outward.

(6) Moreover, the building structure which concerns on this invention installs the load-bearing wall panel as described in said (4) or (5), It is characterized by the above-mentioned.

  In the present invention, the load-bearing wall panel in which the face material or the brace is attached to the frame member made of the thin lightweight steel is attached to the frame including the wooden column and the beam via the attachment member that absorbs the vertical force. Therefore, even if the frame height is lowered due to drying shrinkage or creep phenomenon, the mounting member absorbs the vertical force, so that the load bearing wall panel is not destroyed.

FIG. 1 shows a frame (a part of the first floor part and a part of the second floor part) of a building structure according to an embodiment of the present invention.
The building structure of the present embodiment is configured by installing a load-bearing wall panel 7 formed by attaching a face material 15 to a frame material made of a thin, lightweight steel on a frame composed of a wooden base 1, a column 3, and a beam 5. Is done. Note that the thin lightweight steel refers to a member made of a steel plate having a thickness of less than 2.3 mm.
Hereinafter, each component will be described in more detail.

<Frame>
The frame of a building structure (for example, a house) in the present embodiment is made up of a wooden frame such as a wooden base 1, a wooden column 3, and a wooden beam 5. The wooden base 1 is installed on a concrete foundation 9 as shown in FIG.

<Load bearing wall panel>
The load-bearing wall panel 7 is configured by attaching a plywood face member 15 to a frame member composed of vertical frame members 11a and 11b and horizontal frame members 13a and 13b. In addition, the load-bearing wall panel 7 of this example has a spacer 17 at the center of the frame, and a cross member 19 at a position slightly above the middle in the height direction.
The left and right vertical frame members 11a and 11b and the lower horizontal frame member 13b are made of lip groove steel made of thin lightweight steel. Further, the upper lateral frame member 13a is also composed of a groove-shaped member made of thin lightweight steel, but has a function of absorbing a vertical force. This vertical force absorbing function will be described in detail below.

FIG. 2 is a sectional view of the upper end portion of the load bearing wall panel 7 orthogonal to the panel surface of the load bearing wall panel 7. In FIG. 2, the vertical frame members 11a and 11b are indicated by broken lines.
As shown in FIGS. 1 and 2, the upper horizontal frame member 13 a has a shape having a bent portion 21 that is bent at a part of the flanges on both sides and bent inward. And the part other than the bending part in the flange of both sides is straight. This straight flange portion is screwed to the vertical frame members 11a and 11b.

  A face material 15 made of plywood is attached to one surface of the frame material, and the upper end side of the face material 15 is positioned lower than the upper end surface of the upper horizontal frame material 13a as shown in FIG. Is set to By setting in this way, the face material 15 and the beam 5 do not interfere with each other when the upper horizontal frame member 13a contracts. With such a configuration, the horizontal frame member can freely expand and contract within a certain range, and the vertical force acting on the load bearing wall panel 7 can be absorbed.

  In the load-bearing wall panel 7 configured as described above, the upper lateral frame member 13a is joined to the beam 5 by nails or screws. When there is a load bearing wall at the top, the bolt 23 is joined to the upper load bearing wall. Similarly, the lower lateral frame member 13b is joined to the base 1 with nails or screws. This counteracts horizontal and out-of-plane forces. Furthermore, in order to cope with the pulling force to the load-bearing wall panel, a hole-down hardware is disposed on the vertical frame and joined to the base 1.

  Thus, in the building structure in which the load-bearing wall panel 7 is installed on the frame, even if the wooden column 3 and the beam 5 are changed in the height of the frame due to drying shrinkage or creep phenomenon, the upper horizontal frame The bending portion of the material 13a is bent and deformed to absorb the change in the vertical height of the frame. Therefore, an extra vertical load due to a change in the vertical height of the frame does not act on the bearing wall panel 7. Therefore, the load-bearing wall panel 7 is not destroyed by the change in the vertical height of the frame.

  The upper horizontal frame member 13a and the beam 5 are joined with nails or screws, and a horizontal force is transmitted between the beam 5 and the load-bearing wall panel 7, and a hole down is provided at the end of the panel. Since the hardware is installed, the load-bearing wall panel 7 functions as a structural member. That is, in this embodiment, it can be said that the compression force and the tensile force are separated, the compression force is borne by the wooden member, and the tensile force is borne by the steel member.

As described above, in the building structure of the present embodiment, the load-bearing wall panel 7 in which the face material 15 is attached to the frame material made of the thin and light steel plate has the function of absorbing the vertical force. By attaching to the frame made of wooden columns and beams via 13a, even if the wooden columns and beams expand and contract, an excessive load will not be applied to the load bearing wall panel 7, thereby Destruction is prevented.
Further, in the load bearing wall panel 7 of the present embodiment, the upper side frame member 13a has a vertical force absorbing function, so that a separate member for absorbing the vertical force is not required, and the configuration is simple. Installation is also easy.

  In the above example, the upper side frame member 13a is formed of grooved steel whose side walls bend inward, but the shape of the upper side frame member 13a is not limited to this, for example, You may comprise the grooved steel which a side wall bends outward. However, in this case, in order to avoid interference with the face material 15, it is preferable that the position of the upper side of the face material 15 be lower than the bent portion 21.

In the above description, the method of attaching the load bearing wall panel 7 installed on the first floor portion of the building structure has been described. Needless to say, the same applies to the second floor or higher floors.
Moreover, although the example which installed the load-bearing wall panel 7 in the frame which consists of a wooden frame was shown in said example, the load-bearing wall panel 7 which concerns on this Embodiment can also be used as an internal load-bearing wall in a steel house. . In this case, since the vertical force does not act on the internal bearing wall, an effect of simplifying the design can be obtained.

  Further, in the above embodiment, the expansion function is added to the upper horizontal frame member 13a, but the upper horizontal frame member 13a is formed from the same grooved steel as the lower horizontal frame member 13b, You may make it join the upper side frame material 13a and the beam 5 via the attachment member which has an expansion-contraction function. The mounting member used in this case has various shapes such as a groove-shaped side wall bent outward, a groove-shaped member, for example, a cross-section perpendicular to the axial direction formed into a Z-shape, etc. Can be applied.

  Moreover, although the above-mentioned load-bearing wall panel 7 is an example in which the face material 15 is attached to the frame material, the bracing may be installed instead of the face material 15.

1 shows a frame (a part of the first floor part and a part of the second floor part) of a building structure according to an embodiment of the present invention. It is explanatory drawing of the upper side frame material 13a which concerns on one embodiment of this invention. It is explanatory drawing of the conventional common steel house.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 1 Base, 3 pillars, 5 beams, 7 Load-bearing wall panel, 11a, 11b Vertical frame material, 13a, 13b Horizontal frame material, 15 Face material, 21 Bending part.

Claims (6)

A method of attaching a load-bearing wall panel in which a load-bearing wall panel formed by attaching a face material or a brace to a frame material made of thin lightweight steel is installed on a frame provided with wooden columns and beams,
The mounting method of the load-bearing wall panel, wherein the load-bearing wall panel is mounted via a mounting member that absorbs a vertical force. The mounting member is a groove-shaped member that extends in the width direction of the load-bearing wall panel, and has a bent portion that bends inward or outward on both sides of the flange. Mounting method for load-bearing wall panels. The mounting method of the load-bearing wall panel according to claim 1 or 2, wherein the mounting member is an upper horizontal frame member that constitutes a frame member of the load-bearing wall panel. It is a load-bearing wall panel in which a face material or brace is attached to a thin lightweight steel frame material, and the upper horizontal frame material constituting the frame has a vertical force absorbing function capable of absorbing vertical force. Load-bearing wall panels. The load-bearing wall panel according to claim 4, wherein the upper lateral frame member is a groove-shaped member having bent portions whose both side walls bend inwardly or outwardly. A building structure comprising the load-bearing wall panel according to claim 4.

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