JP5789435B2 - Beam fitting hardware and ceiling structure using the same - Google Patents

Description

  The present invention relates to a beam fitting hardware and a ceiling structure using the same, and more particularly to a beam fitting hardware having a high degree of freedom of use and a ceiling structure using the same, which improves workability in a ceiling blow-off portion.

  Various members and construction methods have been proposed for the method of constructing the base of the wall of the blow-up part that rises from the ceiling to the blow-off part in the ceiling blow-off part (see, for example, Patent Document 1).

Patent Document 1 discloses a ceiling structure of a blowout part.
Patent Document 1 discloses a ceiling hanging bracket for connecting an H-shaped steel beam and a field edge.
The ceiling hanger is composed of a hanger body that holds a beam, a field hanger that fixes a field edge, and a connecting bolt that connects the hanger body and the field edge.
And a beam and a field edge are connected by a field metal fitting being fixed to a field edge in the state where a suspension metal fitting body grasped a beam.
That is, in the present technology, the beam and the field edge are connected via the ceiling hanging bracket.

Japanese Patent No. 3522948

Thus, in the prior art of patent document 1, a ceiling frame is fixed to a ceiling hanging metal fitting, and a runner etc. are added to the frame of this ceiling frame, and a protrusion dimension is adjusted, and the foundation | substrate is fixed.
However, in such a technique, there is a problem that construction is difficult when the base is placed at a position away from the ceiling frame, and the base is not stably fixed.
Moreover, in such a technique, it is necessary to connect a runner from the edge part of a ceiling base | substrate, and to connect a field edge and a beam via this runner.

Furthermore, since the interval at which the main body of the hanging bracket grips the flange of the beam is constant, there is a problem in that the thickness of the object to be gripped is limited.
That is, as the steel material used as the beam, not only H-shaped steel but also various steel materials such as groove-shaped steel having a U-shaped cross section are used.

Steel materials used for these beams have different sizes (particularly, thickness), and there has been a demand for hardware that can easily cope with any thickness steel material.
In addition, there are some beams in which the thickness of the hardware gripping portion (flange end portion or the like) is not constant.

For example, in the case of channel steel, there is one that the thickness of its free end portion (side wall end portion) decreases as it approaches the end (that is, it can be inclined in a tapered shape). It is difficult to reliably grip the free end portion (side wall end portion) within a certain gap of the hardware.
In addition, since there are various sizes of members and the dimensions of the members vary depending on the use location, a hardware capable of flexibly responding to such differences in size and dimensions has been demanded.

An object of the present invention is to solve the above-mentioned problems, a beam joint hardware that can flexibly cope with beams of various thicknesses and can adjust the mounting position, and a ceiling using the same. To provide a structure.
Furthermore, another object of the present invention is to provide a beam fitting hardware excellent in workability capable of directly connecting a beam and a base beam without using other members, and a ceiling structure using the same. .

According to the beam joint hardware according to claim 1, the above-mentioned problem is a beam joint hardware for attaching a building ceiling constituent member to a beam, and the beam joint hardware includes a body member to which the building ceiling constituent member is attached. A moving member that is attached to the main body member and clamps and fixes a beam together with the main body member, and the main body member includes a component member fixing portion to which the building ceiling constituent member is attached, Rutotomoni includes a beam mounting fixed portion moving member is mounted, the moving member includes a Ryokyo sandwiching member for sandwiching said beam, an obtuse angle from the side opposite to the beam end of the beams clamping portion is inserted And a slide hole that is drilled in a direction away from the beam from the side where the beam is disposed. The beam holding part is formed, the beam placing part While being arranged so as to face each other with a predetermined distance, the sliding portion is disposed so as to protrude to the side opposite to the tip is disposed above Ryokyo sandwiching member from the slide hole, A fastening member passes through the moving member and the beam mounting fixing portion, and the shape of the gap between the beam clamping portion and the beam mounting fixing portion changes by fastening the fastening member. as well as, the distance between the mobile member and the beam mounting and fixing unit is changed, resolved by the end of the beam between the moving member and the beam mounting and fixing portion is inserted clamped fixed Is done.

By being configured in this way, in the beam fitting according to the present invention, by adjusting the fastening member (that is, rotating in the fastening direction of the fastening member or rotating in the loosening direction), The distance from the beam mounting and fixing portion can be changed.
In other words, the end of the beam is inserted and fixed between the moving member and the beam mounting fixing portion, but even if the thickness of the end of the beam is different, the moving member and the beam mounting fixing portion are fixed. It is possible to sandwich the end of the beam between the two, which improves workability and workability.
Moreover, since it fixes directly from the beam which is a load-bearing structure part, compared with a prior art, a blow-off part wall is fixed more firmly and stably.

Also, specifically, by fastening the pre-Symbol fastening member, the distance between the mobile member and the beam mounting and fixing portion proximate said side is the beam that beam end is inserted in the Ryokyo lifting unit When pressed against the end, the slide portion is preferably moved in a direction away from the beam while the angle with the beam clamping portion is expanded.

Since it is configured in this way, the distance between the moving member and the beam mounting and fixing portion is close by fastening the fastening member, but at this time, the side where the beam end portion of the beam holding portion is inserted is When pressed against the beam end portion, the slide portion moves in a direction in which the slide hole is separated from the beam while the angle with the beam holding portion is expanded.
In other words, when the side where the beam end of the beam clamping part is inserted is pressed against the beam end, this pressure contact point does not move any further, so the slide part pushes the angle with the beam clamping part around this pressure contact point. The slide hole is moved away from the beam while being widened.
In other words, the shape of the gap between the beam sandwiching portion and the beam mounting and fixing portion is deformed, and the beam end portion can be reliably gripped.
For this reason, for example, even when the beam is formed of channel steel and the end of the beam is tapered, the beam holding portion and the beam mounting and fixing portion are aligned along this shape. Since the shape of the gap between them can be deformed, the pressure contact area is increased, and the beam end can be reliably gripped.
In addition, as a reaction force in which the angle between the slide part and the beam clamping part is expanded, a force is applied in the beam clamping direction to the side where the beam end of the beam clamping part is inserted (pressure contact point). In addition, the beam end can be more securely fixed.
Therefore, the end of the beam can be fixed easily and reliably.

At this time, the component member fixing portion extends from the beam mounting fixing portion in a direction opposite to the side where the moving member is disposed, and the mounting position of the component member fixing portion is adjusted. It is preferable that a plurality of fastening holes are formed.
If comprised in this way, it will become possible to adjust the attachment position to the beam joint hardware of a base crosspiece.

At this time, it is preferable that an angle formed by the beam sandwiching portion and the slide portion is 120 ° to 140 °.
For example, when the angle between the beam sandwiching portion and the slide portion is about 90 ° or an acute angle, sliding of the slide portion is hindered.
Therefore, it is preferable that the angle formed by the beam sandwiching portion and the connecting portion is an obtuse angle.

  The beam fitting according to the present invention is more specifically a beam fitting for attaching a building ceiling component to a beam, and the beam fitting is a main body member to which the building ceiling component is attached. And a moving member that is attached to the main body member and clamps and fixes the beam together with the main body member, and the main body member is a constituent member fixing portion to which the building ceiling constituent member is attached, A beam mounting fixing portion extending substantially vertically from the component member fixing portion is provided, and the beam mounting fixing portion is separated from the component member fixing portion from the side on which the component member fixing portion is formed. And a plurality of fastening holes for adjusting the mounting position on the building ceiling component member side are formed in the component member fixing portion. And said The moving member has a beam holding portion that holds the end portion of the beam, and a slide portion that extends at an obtuse angle from the side opposite to the side where the beam end portion of the beam holding portion is inserted. The sliding portion is configured to include a connecting portion that continuously extends from the beam holding portion, and a locking portion that extends from a substantially central portion on the opposite side of the connecting portion that is continuous with the beam holding portion. The beam holding portion is disposed so as to face the beam mounting portion with a predetermined interval, and the locking portion has a tip portion extending from the slide hole to the beam holding portion. Is disposed so as to protrude to the side opposite to the side on which the screw is disposed, and the beam holding portion is formed with a moving member screw through hole in which a nut is disposed, and the fastening member is moved from the slide hole to the moving member. It penetrates toward the screw through-hole and is screwed into the nut to fasten the fastening member. As a result, the beam sandwiching portion is drawn toward the beam placement fixing portion, the distance between the beam sandwiching portion and the beam placement fixing portion is close, and the slide portion of the moving member is formed. When the end opposite to the side is in pressure contact with the end of the beam inserted into the end, the locking portion is interlocked with the angle between the slide portion and the beam clamping portion being expanded. And moving in a direction away from the beam along the slide hole.

Moreover, the ceiling structure which concerns on this invention is comprised by fixing the said building ceiling structural member to the steel beam with the beam fitting hardware of Claim 1 thru | or 4 .
Usually, a plurality of these beam fittings are used.

According to the beam fitting hardware according to the present invention, it is possible to flexibly cope with beams of various thicknesses.
That is, in the beam fitting hardware according to the present invention, the distance between the moving member and the beam mounting and fixing portion can be changed by rotating in the direction in which the fastening member is fastened or rotating in the loosening direction.
In the present invention, the end of the beam is inserted and fixed between the moving member and the beam mounting and fixing portion, and the moving member is configured even if the thickness of the end of the beam is different. Since the distance between the beam and the beam mounting / fixing portion can be adjusted, the end portion of the beam can be clamped, thereby improving workability and workability.

In addition, since the slide part moves in a direction separating the slide hole from the beam while the angle with the beam holding part is expanded, the shape of the gap between the beam holding part and the beam mounting fixing part Is deformed, and the beam end can be securely gripped.
For example, in the beam fitting according to the present invention, even when the beam is formed of channel steel and the end of the beam is tapered, the beam clamping portion and the beam are aligned along this shape. Since the shape of the gap between the mounting and fixing portion is deformable, the pressure contact area is increased, and the beam end portion can be reliably gripped.
In addition, as a reaction force in which the angle between the slide part and the beam clamping part is expanded, a force is applied in the beam clamping direction to the side where the beam end of the beam clamping part is inserted (pressure contact point). In addition, the beam end can be more securely fixed.
Therefore, the end of the beam can be fixed easily and reliably.

Further, since a plurality of bolt holes for adjusting the mounting position are formed in the component member fixing portion, the mounting position on the base rail or the like can be adjusted.
Furthermore, it is possible to directly construct the base beam from the beam without using other members (runners, etc.), and therefore it is possible to provide a beam fitting hardware with excellent workability and a ceiling structure using this. It becomes.
In this way, in the present invention, since it is directly fixed from the beam which is the load bearing structure part, the blow-off part wall is more firmly and stably fixed, and is not affected by the position of the ceiling panel. The degree is improved.

It is a perspective view which shows the beam fitting hardware which concerns on one Embodiment of this invention. It is an exploded view of a beam fitting hardware concerning one embodiment of the present invention. It is a 3rd view which shows the main body member which concerns on one Embodiment of this invention. It is a 4th page figure of the movement member concerning one embodiment of the present invention. It is explanatory drawing which shows the use condition of the beam fitting hardware which concerns on one Embodiment of this invention. It is explanatory drawing which shows the beam fixing mechanism of the beam fitting hardware which concerns on one Embodiment of this invention. It is explanatory drawing which shows the use condition of the beam fitting hardware which concerns on one Embodiment of this invention. It is explanatory drawing which shows the ceiling structure which concerns on one Embodiment of this invention.

Hereinafter, an embodiment of the present invention will be described with reference to the drawings.
Note that the configuration described below does not limit the present invention and can be variously modified within the scope of the gist of the present invention.

  The present embodiment relates to a beam fitting hardware that can flexibly cope with beams of various thicknesses and can also adjust the mounting position, and a ceiling structure using the same.

  1 to 8 show an embodiment according to the present invention. FIG. 1 is a perspective view showing a beam fitting hardware, FIG. 2 is an exploded view of the beam fitting hardware, and FIG. 3 is a three-side view showing a main body member. FIG. 4, FIG. 4 is a four-sided view of the moving member, FIG. 5 is an explanatory diagram showing the use state of the beam fitting hardware, FIG. 6 is an explanatory diagram showing the beam fixing mechanism of the beam fitting hardware, and FIG. FIG. 8 is an explanatory view showing a ceiling structure.

First, the structure of the beam fitting hardware S according to the present embodiment will be described with reference to FIGS.
As shown in FIGS. 1 and 2, the beam fitting hardware S according to this embodiment includes a main body member 1, a moving member 2, and a fastening member 3.

The main body member 1 according to the present embodiment includes a constituent member fixing portion 11 and a beam mounting fixing portion 12.
As shown in FIG. 3, the component member fixing portion 11 is formed in a substantially rectangular flat plate shape, and is formed with six screw through holes 11a.
The screw through hole 11a corresponds to a “fastening hole” described in the claims.
In the present embodiment, the six screw through holes 11a are arranged in parallel at the inner corners of the lower side (the Y direction in FIG. 1: the side opposite to the side on which a beam mounting fixing part 12 described later is formed). 2 above and below the two screw through holes 11a formed at both inner corners (the X direction in FIG. 1: the side on which a beam mounting fixing portion 12 described later is formed) in the vertical direction ( Two pieces are formed so as to be arranged in parallel at equal intervals in the XY direction of FIG.

In addition, the formation number and formation location of this screw through-hole 11a are not restricted to this, It can design suitably in the range which does not deviate from the meaning of this invention.
The screw through hole 11a is for adjusting the mounting position of the beam fitting hardware S.
That is, by forming a plurality of the screw through holes 11a, it is possible to finely adjust the mounting position of the beam fitting S on the component member side, and the workability is improved.

  The beam mounting fixing portion 12 extends from one side of the component member fixing portion 11 substantially perpendicularly to the component member fixing portion 11, and has a longitudinal direction (that is, close to the component member fixing portion 11) at the center thereof. A slide hole 12a having a substantially elliptical shape is formed in a direction away from the side to be moved.

Both long sides are bent substantially vertically downward, and the bent portions serve as body member reinforcing ribs 12b and 12b.
Thus, the main body member 1 is configured as a substantially L-shaped member by the constituent member fixing portion 11 and the beam mounting fixing portion 12.

The moving member 2 according to the present embodiment includes a beam clamping portion 21 and a slide portion 22.
As shown in FIG. 4, the beam clamping portion 21 is formed in a substantially rectangular flat plate shape, and two opposite sides thereof are bent substantially vertically in the same direction to form moving member reinforcing ribs 21b and 21b.
In addition, the direction (X direction of FIG. 1) where this moving member reinforcement ribs 21b and 21b stand is described as upper.
Further, a moving member wing screw through hole 21a is formed at a substantially central portion of the beam clamping portion 21, and a wing screw nut 21c is fixed so as to communicate with the moving member wing screw through hole 21a.
The moving member thumbscrew through-hole 21a corresponds to the moving member screw through-hole in the claims, and the thumbscrew nut 21c corresponds to the nut in the claims.

The slide part 22 includes a connecting part 22A and a locking piece 22B.
The connecting portion 22A has an obtuse angle with respect to the beam clamping portion 21 from one side of the beam clamping portion 21 (one side orthogonal to the side where the reinforcing ribs 21b and 21b stand up) (Y direction in FIG. 1). It is the substantially rectangular part extended to.

And the angle which the beam clamping part 21 and the connection part 22A comprise is an obtuse angle.
In addition, although the angle which the beam clamping part 21 and 22 A of connection parts make is an obtuse angle, about 120 degrees-140 degrees are preferable.
In the present embodiment, the angle formed by the beam sandwiching portion 21 and the connecting portion 22A is formed to be 130 °.
As will be described later, this is a suitable angle for reliably clamping the end of the beam H1 between the beam clamping unit 21 and the beam mounting and fixing unit 12.

Further, the locking piece 22B extends downward from the substantially central portion of the lower side of the connecting portion 22A (the side opposite to the side continuous with the beam clamping portion 21) so as to be continuous with the connecting portion 22A. I'm out.
The width of the locking piece 22B is configured to be smaller than the width of the continuous portion 22A. Therefore, at the boundary portion between the continuous side portion 22A and the locking piece 22B, on both sides of the locking piece 22B. A step is formed.
The steps at the boundary between the continuous portion 22A and the locking piece 22B are referred to as step locking portions K1, K1.

  The locking piece 22B includes a substantially rectangular flat plate-like base end portion 22a and a substantially rectangular flat plate-like tip end portion 22b, and the width of the base end portion 22a is smaller than the width of the tip end portion 22b. It is configured.

Due to the difference in width, retaining stoppers K2 and K2 are formed at the boundary between the base end portion 22a and the distal end portion 22b.
The width of the proximal end portion 22a is configured to be slightly smaller than the width of the slide hole 12a, and the width of the distal end portion 22b is configured to be slightly larger than the width of the slide hole 12a.

  Since it is configured in this manner, the locking piece 22B is inserted from the upper part of the slide hole 12a (the X direction side in FIG. 1; the side opposite to the side where the component fixing part 11 extends) to prevent the locking piece 22B. By adjusting the direction so that the stop portions K2 and K2 are hooked to the long side in the longitudinal direction of the slide hole 12a, the moving member 2 can be disposed so that the tip end portion 22b does not come out of the slide hole 12a.

In addition, since the width of the base end portion 22a is configured to be slightly smaller than the width of the slide hole 12a, the locking piece 22B is prevented from being detached from the slide hole 12a by the retaining locking portions K2 and K2. In the state, it can move in the longitudinal direction along the slide hole 12a.
In this way, the slide portion 22 of the moving member 2 can move along the slide hole 12a with respect to the main body member 1.

The fastening member 3 according to this embodiment includes a thumbscrew 31, a spring washer 32, and a flat washer 33.
As these thumb screws 31, spring washers 32, and flat washers 33, known hardware is used.
A larger fastening force can be obtained by using the spring washer 32.

As shown in FIGS. 1 and 2, the moving member 2 is configured such that the upper surface of the beam placement fixing portion 12 of the main body member 1 (the surface on the X direction side in FIG. On the surface).
At this time, the distal end portion 22b of the locking piece 22B protrudes downward (Y direction in FIG. 1: the side on which the component member fixing portion 11 extends) from the slide hole 12a.

  When the moving member 2 is attached to the main body member 1, the inner holes of the moving member butterfly screw through hole 21a and the butterfly screw nut 21c formed in the substantially central portion of the beam clamping portion 21 communicate with the slide hole 12a. The thumbscrew 31 is inserted into the communication hole from below (the Y direction in FIG. 1: the side on which the component member fixing portion 11 extends) through the spring washer 32 and the flat washer 33.

With reference to FIG. 5, a state where the base beam D1 is fixed to the beam H1 in the beam fitting hardware S will be described.
The end portion of the beam H1 includes an upper surface of the beam mounting fixing portion 12 constituting the main body member 1 (a surface opposite to the side on which the component member fixing portion 11 extends) and a beam holding portion 21 constituting the moving member 2. It is fixed by fastening the thumbscrew 31 in a state of being sandwiched between the lower surface (the side opposite to the side where the moving member reinforcing ribs 21b and 21b stand up).

Moreover, the component member fixing | fixed part 11 which comprises the main body member 1 fixes the foundation | base_piece crosspiece D1 by fastening a wood screw from the screw through-hole 11a.
In this way, the base beam D1 is fixed to the beam H1 via the beam fitting hardware S.

Next, a mechanism for fixing the beam H1 between the main body member 1 and the moving member 2 will be described with reference to FIG.
Although FIG. 6 shows a large interval and deformation for the purpose of explanation, it is only an explanation that such a movement is realized, and the degree (degree of change in angle, degree of deformation, etc.) is shown in this figure. It is not restricted to.

  As shown in FIG. 6 (a), the end of the beam H1 is the upper surface of the beam mounting fixing portion 12 constituting the main body member 1 (the surface opposite to the side on which the component member fixing portion 11 extends), It is inserted between the lower surface of the beam holding portion 21 constituting the moving member 2 (the side opposite to the side where the moving member reinforcing ribs 21b and 21b stand up).

When the thumbscrew 31 is tightened in this state, the moving member 2 is pulled toward the main body member 1, but the step locking portions K1 and K1 formed on the slide portion 22 are locked on the long side of the slide hole 12a. Therefore, the slide part 22 side is hardly pulled toward the main body member 1.
That is, the rear end portion of the moving member 2 (the end side portion facing the side where the slide portion 22 is formed) is first drawn toward the main body member 1 side.

Therefore, as shown in FIG. 6B, when the thumbscrew 31 is initially tightened, the rear end portion of the beam holding portion 21 (the end portion on the side facing the side where the slide portion 22 is formed) is first. As a result, the beam holding portion 21 is inclined with respect to the horizontal.
Further, when the thumbscrew 31 is tightened, the rear end portion of the beam clamping portion 21 (the end portion on the side facing the side where the slide portion 22 is formed) is placed on the beam mounting that constitutes the main body member 1. It is pressed against the upper surface of the end portion of the beam H1 placed on the fixed portion 12, and cannot move any more.

At the same time, as shown in FIG. 6 (c), the slide portion 22 moves forward along the slide hole 12 a of the main body member 1 while the angle formed by the beam sandwiching portion 21 and the slide portion 22 is expanded. It slides (slides) toward the side opposite to the side on which the component member fixing portion 11 is formed.
Then, the angle formed by the beam sandwiching portion 21 and the slide portion 22 is expanded, and as a reaction force, the rear end side of the beam sandwiching portion 21 (the end opposite to the side where the connecting portion 22A extends) is obtained. Part) is applied with a force in the direction of the beam mounting and fixing part 12.
Therefore, the beam H1 is clamped between the beam clamping unit 21 and the beam mounting and fixing unit 12 with a strong holding force.
As described above, the beam H <b> 1 is fixed between the main body member 1 and the moving member 2.

Note that, as described above, the angle formed between the beam sandwiching portion 21 and the connecting portion 22A is preferably an obtuse angle in order to surely perform this sliding (sliding).
That is, for example, when the angle is set to about 90 ° or less, the step locking portions K1 and K1 are fixed in a state of being placed on both sides of the slide hole 12a, and the sliding of the locking piece 22B is hindered. The
Therefore, the angle formed by the beam sandwiching portion 21 and the connecting portion 22A is configured to be an obtuse angle, and in the present embodiment, configured to be 130 °.
This angle is suitable for the state of the gap between the moving member 2 and the main body member 1, ensuring the pressure contact force of the rear end portion of the moving member 2, and the like.

Furthermore, the further usefulness of the beam joint hardware S which concerns on this embodiment is shown in FIG.
The beam fitting hardware S according to the present embodiment is not only a beam end portion having a constant thickness like a flange portion such as H-shaped steel, but also a locking portion having a constant thickness such as a grooved steel, and has a tapered shape. The beam H2 which becomes can also be fixed effectively.

That is, as shown in FIG. 7, the beam joint hardware S according to the present embodiment can freely adjust the width of the gap between the beam clamping unit 21 and the beam mounting and fixing unit 12.
At this time, as described above, the thumbscrew 31 is tightened, and the rear end portion of the beam holding portion 21 (the end portion on the side facing the side where the slide portion 22 is formed) is placed on the main body member 1. After being pressed against the upper surface of the beam H2 placed and cannot move any more, the slide portion 22 moves forward along the slide hole 12a of the main body member 1 while the angle formed by the beam clamping portion 21 and the slide portion 22 is expanded. Slide toward (the side opposite to the side where the component member fixing portion 11 is formed).

At this time, the slide part 22 slides until the beam H2 is securely gripped in the gap between the beam holding part 21 and the beam mounting and fixing part 12.
That is, the slide portion 22 moves forward along the slide hole 12a of the main body member 1 while the angle formed by the beam clamp portion 21 and the slide portion 22 is expanded around the pressure contact portion that is the rear end of the beam clamp portion 21. Since it slides toward (the side opposite to the side where the component member fixing portion 11 is formed), the beam holding portion 21 can be inclined so as to follow the shape of the end portion of the beam H2.
Therefore, the pressing area to the beam H2 of the beam clamping part 21 can be ensured to the maximum extent.
In this way, the beam H2 is securely fixed between the main body member 1 and the moving member 2.

Next, a ceiling structure T using the beam fitting hardware S will be described with reference to FIG.
This ceiling structure T illustrated the structure of the atrium part E.
The first floor ceiling portion is composed of a ceiling panel P1 and a ceiling plate body P2 which is a plaster board.

A blowout wall W1 is erected on the end of the blowout part E via a base bar D1.
And the side surface by the side of the ceiling panel P1 arrangement | positioning of the base crosspiece D1 is being fixed to the structural member fixing | fixed part 11 of the beam metal fitting S. FIG.
In the present embodiment, a plurality of beam fittings S are used, and the base beam D1 is fixed.
And the side wall edge part of the beam H1 is being fixed in the state clamped in the gap | interval of the beam clamping part 21 and the beam mounting fixing | fixed part 12 of the beam fitting hardware S. FIG.

In this way, the base beam D1 is fixed to the beam H1 via the plurality of beam fittings S.
An ALC (autoclaved lightweight aerated concrete) second floor F1 is disposed on the beam H1, and its upper surface is covered with a moisture-proof film F2, a flooring F3, and the like.

The blow-by portion wall W1 is erected with the base bar D1 as a base.
Further, an inner wall W2 is erected at the end of the second floor F1 on the side of the blow-off portion E. The blow-off portion wall W1 faces the inner wall W2 and the blow-off portion E side, and includes a beam H1, a base beam D1, and the like. It is erected so as to cover the structure.

As described above, according to the beam fitting hardware S according to the present embodiment, it is possible to easily and reliably fix the base beam D1 to the beams H1 and H2.
That is, since the beam fitting hardware S according to the present embodiment can adjust the distance between the beam mounting fixing portion 12 constituting the main body member 1 and the beam clamping portion 21 constituting the moving member 2, Workability is high regardless of the size (thickness) of the beams H1 and H2.

  Further, the upper surface of the beam mounting fixing part 12 constituting the main body member 1 (the surface opposite to the side where the constituent member fixing part 11 extends) and the lower surface of the beam holding part 21 constituting the moving member 2 (moving member). The ends of the beams H1 and H2 are inserted between the reinforcing ribs 21b and 21b and the side opposite to the side where the reinforcing ribs 21b stand up, and the thumbscrew 31 is tightened to reduce the gap so that the upper surface of the beam mounting fixing portion 12 and the beam Since the end portions of the beams H1 and H2 are sandwiched between the lower surface of the sandwiching portion 21, they are securely fixed to the end portions of the beams H1 and H2.

  Moreover, since the slide part 22 can move along the slide hole 12a, if the fastening force of the thumbscrew 31 is continuously applied, the angle formed between the beam clamping part 21 and the slide part 22 is expanded and the slide part 22 is moved. 22 slides forward along the slide hole 12a of the main body member 1 (on the side opposite to the side on which the component member fixing portion 11 is formed), and the upper surface of the beam mounting fixing portion 12 and the lower surface of the beam clamping portion 21 Is contracted, and is pressed along the shape of the ends of the beams H1 and H2.

  Therefore, even if it is channel steel like the beam H2, that is, even if the end portion of the beam H2 is formed in a taper shape, the main body member 1 and the moving member 2 are arranged along the taper shape. The beam H2 is securely fixed.

  Furthermore, since a plurality of screw through holes 11a are formed in the component member fixing portion 11, the size (thickness) of the gypsum board constituting the first floor ceiling portion changes, and the position of the base beam D1 also changes. It is possible to respond flexibly and the workability is improved.

DESCRIPTION OF SYMBOLS 1 Main body member 11 Component member fixing | fixed part 11a Screw through hole (fastening hole)
12 Beam mounting fixing part 12a Slide hole 12b Body member reinforcing rib 2 Moving member 21 Beam holding part 21a Moving member butterfly screw through hole 21b Moving member reinforcing rib 21c Butterfly screw nut 22 Slide part 22A Connecting part 22B Locking piece 22a Base end part 22b Tip part 3 Fastening member 31 Thumb screw 32 Spring washer 33 Flat washer D1 Base rail E Blowing part F1 Second floor F2 Moisture-proof film F3 Flooring H1, H2 Beam K1 Step locking part K2 Retaining locking part P1 Ceiling panel P2 Ceiling Plate body S Beam fitting T T Ceiling structure W1 Blow wall W2 Inner wall

Claims (5)

A beam fitting for attaching a building ceiling component to a beam,
The beam fitting hardware is a main body member to which the building ceiling constituent member is attached,
A movable member attached to the main body member and sandwiching and fixing the beam together with the main body member; and
Said body member includes a structure member fixing portion to which the building roof structure member is attached, the movable member includes a beam mounting and fixing portion mounted is Rutotomoni, the moving member includes a Ryokyo sandwiching member for sandwiching said beam, A slide portion extending at an obtuse angle from the opposite side to the side where the beam end portion of the beam sandwiching portion is inserted, and configured.
The beam placement fixing part is formed with a slide hole drilled in a direction away from the beam from the side where the beam is disposed, and the beam holding part has a predetermined distance from the beam placement part. And the slide part is arranged so that the tip part protrudes from the slide hole to the side opposite to the side where the beam clamping part is arranged,
A fastening member passes through the moving member and the beam mounting fixing portion,
By fastening the fastening member, the shape of the gap between the beam sandwiching portion and the beam mounting fixing portion changes , and the distance between the moving member and the beam mounting fixing portion changes,
An end of the beam is inserted and fixed between the moving member and the beam mounting fixing portion, and the beam fitting hardware is characterized. By fastening the front Symbol fastening member, when the distance between the mobile member and the beam mounting and fixing portion is close, the beam end of the Ryokyo lifting unit is the side that is inserted to press the beam end, the 2. The beam fitting hardware according to claim 1, wherein the slide portion moves in a direction separating the slide hole from the beam while being widened at an angle with the beam holding portion. The component member fixing portion extends from the beam mounting fixing portion in a direction opposite to the side where the moving member is disposed,
2. The beam fitting hardware according to claim 1, wherein a plurality of fastening holes for adjusting a mounting position are formed in the component member fixing portion.   The beam fitting hardware according to claim 2, wherein an angle formed between the beam clamping portion and the slide portion is 120 ° to 140 °. The ceiling structure characterized by fixing the said building ceiling structural member to the steel beam with the beam fitting hardware of Claim 1 thru | or 4 .

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