JP3527298B2 - Substructure for buildings - Google Patents

Description

Detailed Description of the Invention

[0002]

[Industrial applications]

The present invention relates to a base structure for a building, and more particularly to a base structure for a floor, a wall or a ceiling in a structure.

[Prior art]

[0004] For example, as a floor base structure for a building,
Japanese Industrial Standard JIS A6519 There are some that use steel floor base materials for gymnasiums. In addition, OA such as computer rooms
A flooring material with a special structure developed for floors is also known. Further, as a floor substructure of a building (particularly for general houses), a wooden Daibiki is arranged on an underfloor slab, a wooden joist is arranged on the Daibiki, and a floor material is arranged on the wooden joist. In this case, as a measure against termites, it is often the case that wooden daiiki and joists are soaked with a chemical for termite control.

By the way, in recent years, attempts have been made to increase the number of effective floors by lowering the height of each floor in a building (in particular, a high-rise building). Is required.

However, in the case of the above-mentioned floor substructure using the steel floor substructure for a gymnasium, since it is limited to a gymnasium, it is difficult to make the floor low because of its structure, and it lacks versatility. There is a problem that it is generally difficult to spread because of its high cost.

[0007] In addition, in the OA floor, many supporting members having a complicated structure are interposed between the underfloor slab and the floor material, and the joint portion between each supporting member and the floor material is provided. Is a structure in which the lower surface of the floor material is specially processed and the upper end of the support member is fitted, so the structure is inevitably complicated and the number of parts and processing man-hours increase, which inevitably leads to cost increase. There is a problem. In addition, workability is deteriorated because it takes a lot of time and effort to adjust the height of each support member. Moreover, since it is exclusively for the OA floor, it lacks general versatility, and there is a problem that it is difficult to popularize it in general.

Further, in the case of constructing a floor substructure by combining a wooden haul and joists, there is a limit to the reduction of the floor substructure, and the construction itself becomes complicated, and the assembling work must be complicated. There is a problem of not getting. Moreover, there is also a problem that simply impregnating the used wood with chemicals is not a complete countermeasure against termites.

[0009] One of the main reasons why metal floor substrata are not used in general houses is that carpenters do not like to use them due to their complicated structure and construction method.

As a base structure for puffed walls in a building, (1) a pair of runners arranged vertically along a wall slab is fitted with W bars or the like used for a ceiling or the like at predetermined intervals, and each double bar (2) that the middle part of is fixed by using a metal fitting or the like
Without using a runner, a plurality of fixing devices for fixing the W bar to the wall slab are arranged at predetermined points, and the W bars are fitted and fixed to the fixing devices arranged in a straight line.
(3) A conventional steel square column is fitted into the upper and lower runners, a rail with a special structure is fixed orthogonally to the wall slab corresponding to the middle part, and a special clip fitted into the rail and a conventional steel square. There are ones in which mold columns are coupled with screws, and (4) ones in which glue is attached to a wall slab and an upper-attached board is directly attached to this (generally called the GL method).

However, in the case of the conventional puffer wall base structure described above, all of the conventional techniques (1) to (3) require a lot of time and labor for the construction work, and various components must be combined. However, there is a problem that it is difficult to avoid the cost increase. Moreover, in the base structure for puffed walls, the puffed width from the wall slab (that is,
Although it is desirable to make the distance between the wall slab and the overlaid board as small as possible, there is a problem that these conventional techniques have structural limitations. Further, in the prior art of the above (4), although the puffed width can be made small, since the glue is used, unless the drying time is long, there is a problem that the surface of the top-stick board is moldy and the wall surface There is also the problem that skill is required to level out.

As a base structure for a ceiling in a building, (1) a hanging bolt is screwed into an insert already installed in a ceiling slab, a hanger is fixed to the lower end of the hanging bolt, and a hoop receiver (ie, a hanger) is attached to the hanger. , Channel) and fix the single or double field edge in a grid to the field edge receiver with clips, (2) Conventionally for a pair of runners arranged at both ends of the ceiling slab There is a type in which square steel columns are fitted at predetermined intervals.

However, in the case of the conventional ceiling base structure described above, in the conventional technique of (1), the assembling process is extremely complicated, the number of types of parts is inevitably increased, and a lot of labor is required for the construction. At the same time, there is a problem that construction requires considerable skill. Further, in recent condominium constructions and the like, a shallow ceiling is required in order to increase the room area as much as possible, but the conventional technique (1) has a problem in that it cannot be shallow because of structural limitations. Further, in the prior art of (2), since there is no fixing means in the middle part, it can be applied to a narrow ceiling width (for example, a ceiling width of about 1.5 m or less), but if the ceiling width increases,
There is a problem that the middle part may drip downward, which makes it difficult to apply.

[Problems to be Solved by the Invention]

From the above-mentioned circumstances, a metal base material fixed to the slab by fixing pins is interposed between the interior material and the slab in parallel with each other at a predetermined interval. Expectations are rising for the underlying structure for buildings.

This foundation structure for a structure has a very simple structure and can be constructed at a low cost without requiring any special technique, but it is technically difficult to make the surface of the slab flat, A member for filling the gap between the base material and the slab and for horizontally adjusting or vertically adjusting the base material is required.

It is conceivable that a plurality of plate materials having different thicknesses are prepared as the above-mentioned horizontal or vertical adjusting members and the horizontal adjustment or the vertical adjustment is performed by combining them, but many plate materials having different thicknesses are prepared in advance. There is a problem that the number of parts must be increased and the combination of the plate materials must be decided on site, resulting in poor workability.

The present invention has been made in view of the above points, and in a building structure for a floor, a wall, or a ceiling, horizontal adjustment or vertical adjustment of a base material is performed.
It is an object of the present invention to make it possible to carry out extremely easily and with good workability with a small number of parts.

[Means for Solving the Problems]

In the first basic structure of the present invention, as a means for solving the above problems, a fixing pin 8 is provided between the interior material 1 and the slab 2 (slab for floor, wall or ceiling).
Ri Na and interposed in a parallel state a metal base member 3 fixed to the slab 2 at a predetermined distance by the scan
Co-sew between the love 2 and the base material 3 with the fixing pin 8
And is perpendicular to the longitudinal direction of the base material 3.
The upper surfaces 11a and 12a contact each other and
The tapered surfaces are parallel surfaces 11b and 12b parallel to each other.
A pair of wedge-shaped adjustment pieces 11 and 12 can be slid
In building a foundation structure ability ing and interposed, said both tone
Tapered surfaces 11a and 12a of the alignment pieces 11 and 12
, Extend in the sliding direction and are slidably fitted together
Forming the ridges 15 and the grooves 16 that are in contact with each other
Of the two adjusting pieces 11 and 12, the base material 3
Of the adjusting piece 11 located on the side in the sliding direction
Partly cut away so that it is orthogonal to the sliding direction
Mark reference end 17 that is formed and protrudes from the mark reference end 17
And positioning for connecting the two adjusting pieces 11, 12 together
The positioning projection 18 that serves as a fastening portion of the fastening fastener 19 is formed.

In the second basic configuration of the present invention, the above problems
The interior material 1 and the slab 2 (floor
Fixing pin 8 between the slab for walls, walls, or ceiling)
Metal base material fixed to the slab 2 by
3 are provided in parallel with each other at a predetermined interval.
Co-sew between the love 2 and the base material 3 with the fixing pin 8
And is perpendicular to the longitudinal direction of the base material 3.
The upper surfaces 11a and 12a contact each other and
The tapered surfaces are parallel surfaces 11b and 12b parallel to each other.
A pair of wedge-shaped adjustment pieces 11 and 12 can be slid
In building a foundation structure ability ing and interposed, said both tone
Tapered surfaces 11a and 12a of the alignment pieces 11 and 12
, Extend in the sliding direction and are slidably fitted together
Forming the ridges 15 and the grooves 16 that are in contact with each other
On the back side of both the adjusting pieces 11 and 12,
Recesses 34 and 30 formed by hollowing out the center of the
Is made.

In the first basic configuration of the present invention, there are the following preferred embodiments.

[0021] That is, on the back side of the front Symbol both adjusting pieces 11 and 12, formed by hollowed their central recesses 34, 30
If the formation respectively, good preferable in that cracks can be prevented in adjusting pieces 11, 12 that may occur at the time of driving of the fixing pin 8.

The first and second basic structures of the present invention
In the formation, there are the following preferred embodiments.

That is, the base material 3 is formed as a hollow metal square tube, and a plurality of cutout holes 7 used as working holes are formed in the end face 3a of the interior material 1 side of the fixing pin 8.
It is preferable to form the structure corresponding to the fixed position in order to obtain a low-cost base structure that is lightweight, robust, and excellent in workability.

Further, the base material 3 has a U-shaped cross section in which the slab 2 side is opened and the width of the slab 2 side from the interior material 1 side is narrowed, and the base material 3 is elongated at both ends on the slab 2 side. The metal member having the flange portions 25, 25 for mounting the fixed pin continuous in the direction makes it possible to secure the slide adjustment amount without increasing the length of the adjustment pieces 11, 12 in the sliding direction, and is lightweight and robust. Is preferable in that a low-cost base structure having excellent workability can be obtained.

Further, the base material 3 is a metal square tube having an opening 26 continuous in the longitudinal direction on the end face 3b on the slab 2 side, and a fixing pin straddling the longitudinal edge of the opening 26. Mounting plates 27 for mounting are arranged at predetermined intervals, and a plurality of cutout holes 7 used as working holes are formed in the end face 3a of the base material 3 on the side of the interior material 1 corresponding to the mounting plate 27. It is preferable that it is lightweight, robust, and excellent in workability because a low-cost base structure can be obtained.

[Action]

In the first basic configuration of the present invention, the following actions are obtained by the above means.

That is, with the base material 3 placed on the slab 2, the adjustment piece 1 is placed in the gap between the base material 3 and the slab 2.
By disposing 1, 12 and sliding both adjusting pieces 11, 12 along the tapered surfaces 11a, 12a, the contact state between the two (that is, the degree of polymerization of the tapered surfaces 11a, 12a)
Accordingly, fine adjustment of the gap (that is, horizontal adjustment or vertical adjustment of the base material 3) can be easily performed. At this time, the adjusting pieces 11 and 12 are prevented from being displaced in a direction other than the sliding direction due to the fitting sliding action of the convex strip 15 and the concave groove 16, and smooth slide adjustment can be performed. In addition, the adjustment pieces 11 and 12
After the horizontal adjustment or vertical adjustment, the fixing pin 8
Slab based on the mark reference end 17 before co-sewing
Positioning reference mark such as the adjustment piece 12 located on the 2 side
And then the positioning reference mark and the mark reference end 17
With the positioning projections 18
Joining the two adjusting pieces 11, 12 with the armature 19
This makes it easy to position both adjustment pieces 11 and 12.
Get

In the second basic constitution of the present invention, the above-mentioned means are provided.
The following actions can be obtained.

That is, a state in which the base material 3 is arranged on the slab 2.
In the state, the adjustment piece 1 is placed in the gap between the base material 3 and the slab 2.
1 and 12 are arranged, and both adjusting pieces 11 and 12 are tapered surfaces.
Sliding along 11a and 12a will bring them into contact
State (that is, degree of polymerization of mutual tapered surfaces 11a and 12a)
Fine adjustment of the gap according to the
Or vertical adjustment) is easy. At this time, both adjustment pieces
11 and 12 are sliding action for fitting the ridge 15 and the groove 16 together.
Prevents displacement in directions other than the sliding direction, and ensures smooth sliding.
You can adjust the ride. In addition, both adjustment pieces 11 and 12
On the back surface side, a concave portion 34 formed by hollowing out the central portion thereof,
By forming 30 respectively, the fixing pin 8 is driven.
Adjustment piece 1 that may be generated by impact force when it is inserted
The cracks of 1 and 12 can be prevented.

In the preferred embodiment of the present invention, the following actions are obtained.

In the first basic structure of the present invention, when the recesses 34 and 30 are formed on the back side of the adjusting pieces 11 and 12 by hollowing out the central portions thereof, when the fixing pin 8 is driven in. It is possible to prevent the adjustment pieces 11 and 12 from cracking which may be caused by the impact force.

In the first and second basic configurations of the present invention
The base material 3 is a hollow metal rectangular tube, and a plurality of cutout holes 7 used as working holes are provided on the end surface 3a of the interior material 1 side corresponding to the fixing positions of the fixing pins 8. In this case, the notch hole 7 is used as a working hole, and the base material 3 and the slab 2 are joined together via the fixing pin 8 at a position corresponding to the notch hole 7, thereby making the structure robust. It is possible to obtain a simple underlying structure.

Further, the base material 3 has a U-shaped cross-sectional shape in which the slab 2 side is opened and the width of the slab 2 side from the interior material 1 side is narrowed, and the base material 3 is long at both ends on the slab 2 side. When a metal member having flanges 25, 25 for mounting fixed pins that are continuous in the direction is formed, the width of the base material 3 on the slab 2 side is narrow, so the length of the adjustment pieces 11, 12 in the sliding direction is reduced. The adjustment slide amount (in other words, the height adjustment amount) can be secured without increasing the length, and the flange portion 2
The base material 3 can be easily fixed by driving the fixing pins 8 into 5, 5, and a solid base structure can be obtained by an extremely simple structure and work.

The base material 3 is a metal square tube having an opening 26 continuous in the longitudinal direction on the end face 3b on the slab 2 side, and a fixing pin straddling the longitudinal edge of the opening 26. Mounting plates 27 for mounting are arranged at predetermined intervals, and a plurality of cutout holes 7 used as working holes are formed in the end face 3a of the base material 3 on the side of the interior material 1 corresponding to the mounting plate 27. In this case, by using the cutout hole 7 as a work hole, the base material 3 and the slab 2 are joined by the fixing pin 8 via the mounting plate 27 at a position corresponding to the cutout hole 7 by an extremely simple structure and work. A solid foundation structure can be obtained.

【The invention's effect】

According to the first basic construction of the present invention, a fixing pin 8 is used to fix the interior material 1 and the slab 2 (floor, wall or ceiling slab) to the slab 2. a base member 3 made of metal Ri name and interposed in a parallel state at a predetermined interval, between the slab 2 and the base member 3, the solid
Co-sewn with a fixed pin 8 and in the longitudinal direction of the base material 3.
Abut on each other at tapered surfaces 11a and 12a that are orthogonal to
Parallel surface 1 in which the respective anti-taper surface sides are parallel to each other
A pair of wedge-shaped adjusting pieces 1b and 12b
In slidably interposed to name Ru building for the underlying structure 1, 12, tape in the both adjusting piece 11
The slide surfaces 11a and 12a extend in the sliding direction and
The ridge 15 and the groove 16 which are slidably fitted together are provided.
The adjustment pieces 11 and 12 are formed respectively.
Of the adjusting piece 11 located on the side of the base material 3
Make sure that the tip of the slide direction is perpendicular to the slide direction.
The reference end 17 of the mark formed by partially cutting the
Both adjusting pieces 11, 12 protruding from the reference end 17
Of the positioning fastener 19 for connecting the
Since the projecting portion 18 is formed, the ridge 15 and the groove 1
Both adjustment pieces 1 while utilizing the fitting slide action with 6.
By sliding 1 and 12 along the tapered surfaces 11a and 12a, the clearance is finely adjusted (that is, the base material 3 is Horizontal adjustment or vertical adjustment) can be easily performed, and there is an excellent effect that smooth slide adjustment can be performed while preventing deviation of the both adjustment pieces 11 and 12 in directions other than the slide direction.

Further, since the adjustment can be performed only with the pair of adjusting pieces 11 and 12, the number of parts can be reduced as compared with the prior art, and the working time and cost required for the construction can be greatly reduced.

Further, when used for a floor, a puffed wall or a ceiling, a plurality of types of maximum heights of the pair of adjusting pieces 11 and 12 are different according to the underfloor height, puff width or depth of the pavement. If one is manufactured, there is also an effect that the construction can be easily performed according to the situation of the construction site.

Furthermore, by the adjusting pieces 11 and 12.
After horizontal adjustment or vertical adjustment, using the fixing pin 8
Before co-sewing, slab 2 based on mark reference end 17
The positioning reference mark such as the adjustment piece 12 located on the side is recorded.
And then the positioning reference mark and the mark reference end 17
From the positioning protrusion 18 to the positioning fastening in the combined state
By connecting the two adjusting pieces 11, 12 with the child 19.
Therefore, both adjustment pieces 11, 12 can be easily positioned.
There is also the effect of

According to the second basic configuration of the present invention, the interior
Material 1 and slab 2 (for floor, wall or ceiling slab)
Is fixed to the slab 2 by a fixing pin 8 between
Intervening metal base material 3 in parallel with each other at a predetermined interval.
Is installed between the slab 2 and the base material 3 and
Co-sewn with a fixed pin 8 and in the longitudinal direction of the base material 3.
Abut on each other at tapered surfaces 11a and 12a that are orthogonal to
Parallel surface 1 in which the respective anti-taper surface sides are parallel to each other
A pair of wedge-shaped adjusting pieces 1b and 12b
In slidably interposed to name Ru building for the underlying structure 1, 12, tape in the both adjusting piece 11
The slide surfaces 11a and 12a extend in the sliding direction and
The ridge 15 and the groove 16 which are slidably fitted together are provided.
The adjustment pieces 11 and 12 are formed respectively.
On the back surface side of the concave part 3 formed by hollowing out the central part thereof
Since the grooves 4 and 30 are formed, the ridge 15 and the groove
Both adjustment pieces 1 while utilizing the fitting slide action with 16
Tapered surface 11a of 1,12, slide is along 12a
The contact between them (that is, the taper of each other).
Fine adjustment of the gap (immediately depending on the degree of polymerization of the surfaces 11a and 12a)
Then, the horizontal adjustment or vertical adjustment of the base material 3 can be easily performed.
How to slide both adjustment pieces 11 and 12
Smooth slide adjustment is performed while preventing misalignment.
It has the excellent effect of

Also, with only a pair of adjusting pieces 11 and 12,
The number of parts is smaller than that of the conventional technology.
Dramatically reduces the work time and cost required for construction
There is also an effect that it can be reduced.

Furthermore, for floors, puffed walls or ceilings
When used as, height under floor, puff width or foot
Corresponding to the depth of the filter, the maximum of the pair of adjustment pieces 11 and 12
If you make multiple types with different heights,
The effect that construction can be easily performed according to the situation of the place
There is also.

Furthermore, the back of both adjusting pieces 11 and 12
On the surface side, concave portions 34, 3 formed by hollowing out the central portion thereof
By forming 0 respectively, the fixing pin 8 is driven.
Adjustment piece 1 that may be caused by the impact force
There is also an effect that cracks 1 and 12 can be prevented.

【Example】

Some preferred embodiments of the present invention will be described below with reference to the accompanying drawings.

Example 1 FIGS. 1 to 8 show a building base structure according to Example 1 of the present invention.

The base structure for a building of the present embodiment is a base structure for a floor, and as shown in FIGS. 1 and 2, an interior material (hereinafter referred to as a floor material) 1 and concrete. It is configured by interposing a base material 3 made of a hollow metal square tube between the floor slab 2 and the floor slab 2 at a predetermined interval in a horizontal state in a parallel state.

The base material 3 is formed by bending a metal plate cut into a predetermined width into a square tube shape so that both ends thereof come into contact with each other at one corner, and one end of the metal plate is provided. Is provided with an inverted J-shaped bent portion 5 formed by bending the inside of the base material 3 and further bending the tip end of the inside toward the outside. The other end of the metal plate has an inside An inverted U-shaped bent portion 6 formed by being bent in an inverted U shape is provided, and both are continuously fitted and pressure-bonded to each other to form a corner-type connecting portion 4 which is continuous in the vertical direction. And this base material 3
Is arranged so that the corner-type connecting portion 4 is located above,
The floor material 1-side end surface (hereinafter, referred to as an upper surface in this embodiment) 3a is a surface to which the floor material 1 is attached, and the slab 2-side end surface (hereinafter, referred to as a lower surface in this embodiment) 3b is an adjustment piece 11, 1 described later.
It is supposed to be a connecting surface with the slab 2 via 2. According to this structure, since the base material 3 can be composed of a thin metal plate, a lightweight, robust, and low-cost floor base structure can be obtained, and the impact when the base material 3 and the slab 2 are joined is a corner type. The connection portion 4 is less affected.

A plurality of cutout holes 7 are formed in the upper surface 3a of the base material 3 at predetermined intervals in the longitudinal direction. The notch hole 7 is used as a working hole for inserting a nailing gun for driving a fixing pin (concrete pin 8 in this embodiment) when the base material 3 and the slab 2 are joined. It is sufficient that the opening area is such that a nail gun can be inserted, and the shape thereof can be appropriately selected from the rectangular shape shown in the figure. At both ends of the base material 3, the end face openings 9 in the corresponding portions are used as working holes.

A plurality of lower surfaces 3b of the base material 3 and the slabs 2 are provided at the rim of the end face opening 9 and below each of the notched holes 7 (in the present embodiment, orthogonal to the longitudinal direction of the base material 3). The concrete pins 8 are connected through two concrete pins 8 arranged in the direction
Between the head portion 8a and the lower surface 3b of the base material 3, a metal pressing plate 13 and a buffer plate 14 made of hard synthetic rubber, which are common to the concrete pins 8 and 8, are provided. The metal pressing plate 13 has a width substantially the same as the width of the lower surface 3b of the base material. When the concrete pin 8 is driven, the metal pressing plate 13 receives the head 8a of the concrete pin 8 and the lower surface 3b of the base material. It acts to hold down and contributes to strengthening the degree of bonding between the base material 3 and the slab 2. Further, the buffer plate 14 has a function of preventing the generation of floor squeezing which may occur due to contact between metals.

Further, in this embodiment, the base material 3 is used.
A plurality of beads 10 extending in the vertical direction are formed on both side surfaces 3c, 3d of the same at predetermined intervals in the longitudinal direction. The beads 10, 10, ... Are the side surfaces 3c, 3 of the base material.
It is composed of a vertically elongated groove formed by indenting a part of d. With such a configuration, the load resistance of the base material 3 is improved, and the one that can withstand the same load can be made thin, and the one having the same thickness can increase the force to withstand the vertical load, resulting in cost reduction. It leads to reduction. The bead 10 need not be formed when the rigidity of the base material 3 is sufficiently obtained.

Between the lower surface 3b of the base material 3 and the slab 2, a pair of upper and lower adjusting pieces 11 and 12 which are sewn together by the concrete pin 8 and are in contact with each other by tapered surfaces 11a and 12a are slidable. Is installed in. The adjustment pieces 11 and 12 have tapered surfaces 11a and 12
The lower adjustment piece 12 positioned on the slab 2 side has a wedge shape in which the anti-tapered surfaces are abutted against each other at a and parallel side surfaces 11b and 12b are parallel to each other.
It is preferable to paste the slab 2 in advance. The material of the adjusting pieces 11 and 12 is the tapered surface 1 of both.
It is desirable to use a hard low-foam synthetic resin plate because the sliding contact resistance at 1a and 12a can be reduced. This adjustment piece 1
Reference numerals 1 and 12 serve to horizontally adjust the base material 3 by filling a gap between the slab 2 and the base material 3 by a slide polymerization degree in a state where the tapered surfaces 11a and 12a are in contact with each other.

At both ends of the adjusting pieces 11 and 12 in the sliding direction, the ridges 15 and 15 and the groove 1 extending in the sliding direction and slidably fitted to each other are formed.
6 and 16 are formed (see FIG. 3). Further, in the case of the present embodiment, the lengths of both adjusting pieces 11, 12 in the sliding direction are the same, and the upper adjusting piece 1
At the tip of the slide direction 1, mark reference ends 17, 17 are formed by partially cutting both side ends of the slide direction so as to be orthogonal to the slide direction, and a positioning projection protruding from the mark reference ends 17, 17. And 18 are formed. The slide-direction rear end of each of the ridges 15 is formed as a horizontal portion 15a that is cut off horizontally, so that the ridges 15 and the slab 2 come into contact with each other at the initial sliding stage of the upper adjustment piece 11. It is supposed to be avoided.

The mark reference ends 17 and 17 are reference marks for providing positioning reference marks on the lower adjusting piece 12 when the alignment of the upper and lower adjusting pieces 11 and 12 is completed during horizontal adjustment by the upper and lower adjusting pieces 11 and 12. It will be. On the other hand, the positioning projection 18 is for connecting both adjustment pieces 11 and 12 by screwing a screw 19 which is a positioning stopper from the positioning projection 18 after positioning the both adjustment pieces 11 and 12. Is.

On the back surface of the upper adjusting piece 11, as shown in FIG.
As shown in FIG. 5, a recess 34 is formed by hollowing out the central portion into a rectangular shape while leaving the outer peripheral portion (in other words, the outer peripheral portion as the parallel surface 12b). In the case of the present embodiment, the positioning projection 18 in the recess 34 is
The side is open.

On the other hand, on the rear surface of the lower adjusting piece 12, as shown in FIG. 5, the outer peripheral portion is left (in other words,
A concave portion 30 is formed by hollowing out the central portion into a rectangular shape (with the outer peripheral portion serving as the parallel surface 12b). Due to the presence of the recess 30, even if the surface of the slab 2 is not flat, the contact state by the parallel surface 12b can be well ensured. Further, since the recesses 34 and 30 formed on the back surfaces of both the adjusting pieces 11 and 12 can obtain an average wall thickness, it is possible to prevent cracking when the concrete pin 8 is driven.

Further, at the central portions of both ends of the lower adjusting piece 12 in the sliding direction, center positioning 31, 32 for setting the center of the lower adjusting piece 12 is provided. Reference numeral 33 is an air vent groove for venting air from the recess 30.

With the above construction, when the vertical adjustment pieces 11 and 12 are slid with respect to each other, the projections 15 and 15 and the recessed grooves 16 and 16 are fitted and slid to each other so as to move in a direction orthogonal to the sliding direction. The positional deviation can be prevented, the horizontal adjustment of the base material 3 can be smoothly and quickly performed by the vertical adjustment pieces 11, 12, and the positioning and the positioning projections 18 by the mark reference ends 17, 17 can be performed.
The horizontal adjustment of the base material 3 becomes extremely easy by the positioning connection of the vertical adjustment pieces 11 and 12 by.

Next, the procedure for assembling the base structure according to this embodiment will be described.

First, a plurality of base materials 3 are arranged in parallel on the slab 2 at a predetermined interval, and the base material 3 is made from the end face opening 9 and the notch hole 7 with a concrete pin 8 using a nailing gun.
Is fixed on the slab 2, but at this time, the base material 3
Is adjusted in advance by the following procedure using the vertical adjustment pieces 11 and 12.

The horizontal adjustment is performed in the procedure shown in FIG.

First, as shown in FIG. 6A, the base material 3
Are fixed to the slab 2 in the vicinity of the end face openings 9 and 9 and between the cutout hole 7 and the slab 2 in advance by gluing or adhering, and are positioned at both ends of the base material 3. The upper adjusting piece 11 is slid to fit the ridges 15 and 15 of the upper adjusting piece 11 into the concave grooves 16 and 16 of the lower adjusting piece 12, and the base material 3
And the slab 2 are filled in and the horizontal adjustment of the base material 3 is performed. Then, when the horizontal adjustment of the base material 3 is completed, a positioning reference mark is marked on the tapered surface 12a of the lower adjustment piece 12 with the mark reference ends 17, 17 of each upper adjustment piece 11 as references. At this time, the metal pressing plate 13 and the cushioning plate 14 are fixed to the places defined as a set by lapping or bonding.

Next, as shown in FIG. 6B, the vertical adjustment pieces 11 and 12 located at both ends of the base material 3 are positioned while aligning the mark reference ends 17 and 17 with the positioning reference mark. They are joined by screws 19 screwed from the projecting portion 18, and the concrete pin 8 is driven from the rear end face opening 9 using a nailing gun from above the metal pressing plate 13 to slab the base material 3 together with the adjusting pieces 11 and 12. Co-sew on top of 2. At this time, since the upper and lower adjusting pieces 11 and 12 are coupled by the screw 19, even if an impact from a nailing gun is applied, the adjusting pieces 11 and 1 are adjusted.
2 does not shift in the sliding direction, and horizontal adjustment does not occur.

When the base material 3 can be horizontally adjusted as described above, as shown in FIG. 6C, the lower part of the cutout hole 7 in the base material 3 and the lower adjusting pieces 12, 12 ,. Each lower adjustment piece 1 so as to fill each gap created between
The upper adjustment piece 11 is slid while fitting the ridges 15 and 15 into the concave grooves 16 and 16 of the second reference mark 1
Fill in the positioning reference marks by 7 and 17.

Next, as shown in FIG. 6D, the vertical adjustment pieces 11 and 12 located below the cutout hole 7 are positioned and coupled in the same manner as described above, and then a nailing gun is used from the cutout hole 7. The concrete pin 8 from above the metal pressing plate 10 and the base material 3 is adjusted vertically.
Together with 1 and 12, they are sewn together on the slab 2.

In the above-mentioned procedure, the metal pressing plate 13 presses the lower surface 3b of the base material 3 by the impact force applied to the head 8a of the concrete pin 8 and the compressing force acts on the buffer plate 14, but the buffer plate 14 is buffered after the connection. The reaction force from the plate 14 acts on the concrete pin head 8a, so that the coupling force by the concrete pin 8 is increased. Moreover, in the case of this embodiment, the vertical adjustment piece 1
The ridges 15 and 15 and the ridges 16 and 16 are formed at both end portions in the sliding direction of the ridges 1 and 12, and the recesses 34 and 30
Since the averaging of the wall thickness is achieved by forming the, the upper adjusting piece 11 will not be cracked by the impact force when the concrete pin 8 is driven.

As shown in FIG. 7A, the height adjustment range of the upper and lower adjustment pieces 11 and 12 is as shown in FIG.
The height Tmax in a state where 1, 12 are superposed over the entire length in the sliding direction (that is, a state in which the tip of the positioning projection 18 coincides with the end of the lower adjustment piece 12 in the sliding direction),
As shown in FIG. 7B, the height Tmin is a range in which the mark reference end 17 of the upper adjustment piece 11 is aligned with the side surface 3d of the base material 3.

As shown in FIG. 8, when a base material 3 having a low height H is used, it is difficult to insert a nailing gun from the end face opening 9, so that the floor of the base material 3 is difficult to insert. A notched hole 7 having an open end is formed as a working hole at the end in the longitudinal direction of the end face on the material side (that is, the upper surface 3a).
The concrete pin 8 may be driven in by inserting a nailing gun from above.

As described above, in the base structure of the present embodiment, the horizontal adjustment of the base material 3 can be extremely easily obtained by the degree of polymerization of the pair of adjusting pieces 11 and 12, and the ridges 15 can be obtained.
Since the displacement of the sliding operation can be prevented by the fitting sliding action of the groove 16 and the groove 16, the horizontal adjustment can be easily and quickly achieved with an extremely small number of parts.

Further, the base structure obtained as described above can be completed by an extremely simple structure and work, and is robust and low in cost. In addition, even a worker (for example, a carpenter) who does not have a special technique can easily perform the construction, and the floor can be easily reduced. Moreover, it has versatility that it can be used not only for special floor structures but also for general housing.

Since the metal base material 3 is used, it is extremely useful as a measure against termites.

Moreover, since a large amount of space is maintained between the base materials 3, 3, ... Under the floor, ancillary work (for example, laying heat insulating material, plumbing for water supply work, wiring for electrical work, floor work, etc.) Installation of heating, etc.) is extremely easy.

Since the base material 3 is obtained by bending a metal plate into a rectangular tube shape, various sectional dimensions can be easily obtained, and if these are selected according to the height of the floor base structure. Also, it is possible to easily deal with different heights under the floor.

Example 2 FIGS. 9 and 10 show a building base structure according to Example 2 of the present invention.

In the case of this embodiment, in the ground structure of the first embodiment (that is, the floor ground structure shown in FIGS. 1 and 2), the floor material 1 and the ground material 3 are orthogonal to each other between the floor material 1 and the ground material 3. A plurality of joists 20 are provided at predetermined intervals. The joist 20 is
The base materials 3, 3 ... Have a function to reinforce each other, and are formed as hollow metal rectangular cylinders having the same configuration as the base material 3 in Example 1, but the size of the base material 3 is smaller than that of the base material 3. It is supposed to be small. In the case of the joist 20, the dry wall screw 2 that acts as a fixture from the upper surface 20a side
Since it is bonded to the base material 3 by 1, the corner type connecting portion 4
Is located on the lower side and the upper surface 20a of the joist 20 is
A groove 22 having a depth capable of accommodating the head portion 21a of the dry wall screw 21 is formed continuously in the longitudinal direction. By doing so, the head portion 21a of the drywall screw 21 is not exposed from the joist upper surface 20a, and there is no obstacle when the floor material 1 is stretched on the joist upper surface 20a. Reference numeral 23 is a buffer plate made of hard synthetic rubber interposed between the joist 20 and the base material 3, and 24 is a reinforcing bead formed on both side surfaces of the joist 20. In the case of the present embodiment, the underfloor height is increased by the presence of the joists 20, but there is no problem if the base material 3 having a low height is used. Other configurations, functions and effects are the same as those of the first embodiment, and the description will be omitted to avoid duplication.

Embodiment 3 FIG. 11 shows a building base structure according to Embodiment 3 of the present invention.

In the case of this embodiment, the shape of the base material 3 is largely different from that of the first embodiment. That is, the base material 3 of this embodiment
Has a U-shaped cross-sectional shape in which the slab 2 side is open and the width of the slab 2 side is narrower than the floor material 1 side, and for mounting a fixed pin that is continuous in the longitudinal direction at the open end of the slab 2 side. It is a metal member having the flange portions 25, 25 of. Then, while the upper surface 3a of the base material 3 is used as a floor material adhering surface, the concrete pin 8 is driven in from the flange portion 25 and is jointed together on the slab 2 together with the vertical adjustment pieces 11 and 12. Reinforcing beads 10, 10 ... Are also formed on both side surfaces 3c, 3d of the base material 3 of this embodiment. In addition, the buffer plate 14 includes the flange portions 25, 25.
And the upper adjustment piece 11 are interposed. According to this structure, the slide adjustment amount can be secured without increasing the slide direction length of the adjustment pieces 11 and 12, and the base material 3 can be fixed by driving the concrete pin 8 into the flange portion 25. Example 1
The notch hole 7 for work is unnecessary and the structure of the base material 3 is simplified. Moreover, the obtained underlayer structure is lightweight, robust, and has excellent workability and low cost. Other configurations, functions and effects are the same as those of the first embodiment, and the description will be omitted to avoid duplication.

Example 4 FIGS. 12 and 13 show a building base structure according to Example 4 of the present invention.

In the case of this embodiment, in the base structure of the third embodiment (that is, the floor base structure shown in FIG. 11), a plurality of joists perpendicular to the base material 3 are provided between the floor material 1 and the base material 3. 20
(The same structure as that of the second embodiment) is interposed at a predetermined interval. Other configurations and operational effects are the same as those described in the first, second, and third embodiments, and the description thereof will be omitted to avoid duplication.

Fifth Embodiment FIG. 14 shows a building base structure according to a fifth embodiment of the present invention.

In the case of this embodiment, the shape of the base material 3 is greatly different from that of the first embodiment. That is, the base material 3 of this embodiment
Is an opening 2 continuous in the longitudinal direction on the end face 3b on the slab 2 side.
It is a metal square tube having 6 and mounting plates 27 for mounting the fixing pins are arranged at predetermined intervals across the rim of the opening 26 in the longitudinal direction. In the present embodiment, ribs 28, 28 extending in the anti-slab direction (upward in the case of the present embodiment) are integrally provided on both longitudinal rims of the opening 26, and the ribs 28, 28 are integrally formed. The mounting plate 27 straddling
Are arranged via a cushioning material 29. Further, a plurality of cutout holes 7 used as working holes are formed in the upper surface 3a of the base material 3 so as to correspond to the mounting plate 27.
A robust base material by a very simple structure and work in which the cutout hole 7 is used as a working hole and the base material 3 and the slab 2 are joined by a concrete pin 8 via a mounting plate 27 at a position corresponding to the cutout hole 7. The structure will be obtained. Both side surfaces 3c and 3d of the base material 3 of this embodiment are
Also, reinforcing beads 10, 10, ... Are formed.
Other configurations, functions and effects are the same as those of the first embodiment, and the description will be omitted to avoid duplication.

Embodiment 6 FIGS. 15 and 16 show a building base structure according to Embodiment 6 of the present invention.

In the case of this embodiment, in the foundation structure of Embodiment 5 (that is, the floor foundation structure shown in FIG. 14), a plurality of joists perpendicular to the foundation material 3 are provided between the floor material 1 and the foundation material 3. 20
(The same structure as that of the second embodiment) is interposed at a predetermined interval. Other configurations and operational effects are the same as those described in the first, second, and fifth embodiments, and the description thereof will be omitted to avoid duplication.

Embodiment 7 FIG. 17 shows a building base structure according to Embodiment 7 of the present invention.

The building base structure of the present embodiment is a base structure for puffed walls, and the structure is used between the top-coated board 1 for walls, which is an interior material, and the slab 2 for concrete walls. The base material 3 having the same structure as that used in No. 1 is arranged in parallel at a predetermined interval. In the case of this embodiment, since there is no possibility that a large load is applied to the base material 3, the buffer plate 14 and the bead 10 are omitted. Other configurations, functions and effects are the same as those of the first embodiment, and the description will be omitted to avoid duplication.

Embodiment 8 FIG. 18 shows a building base structure according to Embodiment 8 of the present invention.

The building base structure of the present embodiment is a base structure for puffed walls, and the structure between the top wall board 1 for walls which is an interior material and the slab 2 for walls made of concrete is used. The base material 3 having the same structure as that used in No. 3 is arranged in parallel at a predetermined interval. In the case of this embodiment, since there is no possibility that a large load is applied to the base material 3, the buffer plate 14 and the bead 10 are omitted. Other configurations, functions and effects are the same as those in the first and third embodiments, and the description thereof will be omitted to avoid duplication.

Ninth Embodiment FIG. 19 shows a building base structure according to a ninth embodiment of the present invention.

The foundation structure for a building of the present embodiment is a foundation structure for puffed walls, and it is used as an interior material between the top-coated board 1 for walls and the concrete slab 2 for walls. The base material 3 having the same structure as that used in No. 5 is arranged in parallel at a predetermined interval. In the case of this embodiment, the bead 10 is omitted because there is no possibility that a large load is applied to the base material 3. Other configurations and operational effects are the same as those in the first and fifth embodiments, and thus the description thereof will be omitted to avoid duplication.

Embodiment 10 FIG. 20 shows a building base structure according to Embodiment 10 of the present invention.

The base structure for a building of this embodiment is a base structure for a ceiling, which is an interior material, and is a top-applied board 1 for a ceiling.
And a slab 2 for ceiling made of concrete, a base material 3 having the same configuration as that of the first embodiment is interposed in parallel at a predetermined interval. In the case of this embodiment, since there is no possibility that a large load is applied to the base material 3,
The buffer plate 14 and the bead 10 are omitted. Other configurations, functions and effects are the same as those of the first embodiment, and the description will be omitted to avoid duplication.

Embodiment 11 FIG. 21 shows a building base structure according to Embodiment 11 of the present invention.

The building base structure of this embodiment is a base structure for a ceiling, and is a ceiling-applied top board 1 for an interior material.
And a slab 2 for ceiling made of concrete, a base material 3 having the same structure as that of the third embodiment is interposed in parallel at a predetermined interval. In the case of this embodiment, since there is no possibility that a large load is applied to the base material 3,
The buffer plate 14 and the bead 10 are omitted. Other configurations, functions and effects are the same as those in the first and third embodiments, and the description thereof will be omitted to avoid duplication.

Embodiment 12 FIG. 22 shows a building base structure according to Embodiment 12 of the present invention.

The base structure for a building of the present embodiment is a base structure for a ceiling, and is a top board 1 for a ceiling which is an interior material.
And a slab 2 for ceiling made of concrete, a base material 3 having the same structure as that of the fifth embodiment is interposed in parallel at a predetermined interval. In the case of this embodiment, since there is no possibility that a large load is applied to the base material 3,
The bead 10 is omitted. Other configurations and operational effects are the same as those in the first and fifth embodiments, and thus the description thereof will be omitted to avoid duplication.

In each of the above-mentioned embodiments, the concrete slab is adopted and the concrete pin is adopted as the fixing pin. However, when the foam concrete is used as the slab, the concrete is used as the fixing pin. You can also use screws. When using concrete screws, it is necessary to previously form screw holes for inserting concrete screws in the vertical adjustment pieces 11 and 12 and the metal pressing plate 13.

The invention of the present application is not limited to the configuration of each of the above-described embodiments, and it goes without saying that the design can be changed as appropriate without departing from the scope of the invention.

[Brief description of drawings]

[0096]

FIG. 1 is a perspective view showing a main part of a building base structure according to a first embodiment of the present invention.

FIG. 2 is a cross-sectional view showing a main part of a building underlayer structure according to Example 1 of the present invention.

FIG. 3 is an exploded enlarged perspective view of an adjustment piece used in the base structure for a building according to the first embodiment of the present invention.

FIG. 4 is a back view of the upper adjustment piece used in the building base structure according to the first embodiment of the present invention.

FIG. 5 is a back view of the lower adjustment piece used in the building base structure according to the first embodiment of the present invention.

6A to 6D are explanatory views showing an assembling procedure of the building base structure according to the first embodiment of the present invention.

FIG. 7A is a diagram showing a state in which the maximum adjustment height of the adjustment piece used in the foundation structure for a building according to the first embodiment of the present invention is obtained, and FIG. 7B is the first embodiment of the present invention.
It is a figure which shows the state in which the minimum adjustment height of the adjustment piece used in the foundation structure for buildings concerning this is obtained.

FIG. 8 is a perspective view showing a structure of an end portion of a base material when a base material having a low height is used in the base structure for a building according to the first embodiment of the present invention.

FIG. 9 is a cross-sectional view showing a main part of a foundation structure for a building according to a second embodiment of the present invention.

10 is a sectional view taken along line XX of FIG.

FIG. 11 is a cross-sectional view showing a main part of a base structure for a building according to a third embodiment of the present invention.

FIG. 12 is a cross-sectional view showing a main part of a building base structure according to a fourth embodiment of the present invention.

13 is a sectional view taken along line XIII-XIII in FIG.

FIG. 14 is a cross-sectional view showing the main parts of the foundation structure for a building according to Embodiment 5 of the present invention.

FIG. 15 is a cross-sectional view showing the main parts of a building underlayer structure according to Example 6 of the present invention.

16 is a sectional view taken along line XVI-XVI of FIG.

FIG. 17 is a cross-sectional view showing a main part of a base structure for a building according to Embodiment 7 of the present invention.

FIG. 18 is a cross-sectional view showing the main parts of a building underlayer structure according to Example 8 of the present invention.

FIG. 19 is a cross-sectional view showing the main parts of a foundation structure for a building according to Embodiment 9 of the present invention.

FIG. 20 is a cross-sectional view showing the main parts of a building underlayer structure according to Example 10 of the present invention.

FIG. 21 is a cross-sectional view showing the main parts of a building base structure according to Example 11 of the present invention.

FIG. 22 is a cross-sectional view showing the main parts of a building base structure according to Embodiment 12 of the present invention.

[Explanation of symbols]

1 is an interior material (floor material, top-coated board), 2 is a slab, 3 is a base material, 3a is an end surface of an interior material, 3b is an end surface on the slab side, 7 is a notch hole, and 8 is a fixing pin (concrete pin). , 11, 1
2 is an adjusting piece, 11a and 12a are tapered surfaces, 11b,
12b is a parallel surface, 15 is a ridge, 16 is a groove, 17 is a mark reference end, 18 is a positioning projection, 19 is a positioning fastener (screw), 25 is a flange, 26 is an opening, and 27 is an opening. Mounting plate.

─────────────────────────────────────────────────── ─── Continuation of front page (58) Fields surveyed (Int.Cl. ⁷ , DB name) E04F 15/00

Claims (9)

(57) [Claims] [0001] 1. Between the interior material (1) and the slab (2),
The slab (2) Ri greens and interposed in a parallel state fixed metallic base material (3) at a predetermined distance with respect to said slab (2) and the base member by a fixing pin (8) ( With 3)
The space between them is sewn together by the fixing pin (8) and
A taper surface (1
1a) and (12a) are abutted against each other, and
Parallel planes (11b) and (12b) whose superficial sides are parallel to each other
A pair of wedge-shaped adjustment pieces (11), (1
2) a base structure for slidably buildings ing was interposed, said both adjusting piece (11), in (12)
The taper surfaces (11a) and (12a) have sliding directions.
Convex strips (15) that extend and fit together slidably
And a concave groove (16) are respectively formed,
Of the adjustment pieces (11) and (12), the base material (3)
Sliding direction of the adjustment piece (11) located on the side
Partially cut the tip so that it is orthogonal to the slide direction.
The reference end of the mark (17) and the reference end of the mark
(17) protruding from the both adjustment pieces (11),
Fastening part of positioning fastener (19) for joining (12)
And a positioning protrusion (18) that forms a base layer structure for a building. 2. Between the interior material (1) and the slab (2),
Fixed to the slab (2) by a fixing pin (8)
Metal base material (3) in parallel state
Of the slab (2) and the base material (3)
The space between them is sewn together by the fixing pin (8) and
A taper surface (1
1a) and (12a) are abutted against each other, and
Parallel planes (11b) and (12b) whose superficial sides are parallel to each other
A pair of wedge-shaped adjustment pieces (11), (1
2) Slidingly interposing the base structure for buildings
There are two adjustment pieces (11) and (12)
The taper surfaces (11a) and (12a) have sliding directions.
Convex strips (15) that extend and fit together slidably
And a concave groove (16) are respectively formed,
On the back side of the adjustment pieces (11) and (12),
The recesses (34) and (30) formed by hollowing out the central part are
Ken creation for the underlying structure you, characterized in that respectively are formed. 3. The recesses (3) formed by hollowing out the central portions of the rear surfaces of the adjusting pieces (11), (12).
4), (30) is building a foundation structure of claim 1 Symbol mounting, characterized in that it is formed, respectively. 4. The base material (3) is a hollow metal square tube, and a plurality of cutout holes used as working holes are formed on an end surface (3a) of the interior material (1) side. 4. The base structure for a building according to claim 1, wherein (7) is formed so as to correspond to a fixed position of the fixing pin (8). 5. The base material (3) has a U-shaped cross-sectional shape in which the slab (2) side is open and the width of the slab (2) side from the interior material (1) side is narrower. The metal member having flanges (25), (25) for attaching a fixed pin continuous in the longitudinal direction at both ends on the slab (2) side, which is a metal member. The base structure for a building according to any one of 1. 6. The base material (3) is a metal square tube having an opening (26) continuous in the longitudinal direction at an end face (3b) on the slab (2) side, and the longitudinal direction of the opening (26). Mounting plates (27) for mounting the fixing pins are arranged at predetermined intervals across the rim, and the end surface (3a) on the interior material (1) side of the base material (3) serves as a working hole. A plurality of notch holes (7) to be used are formed corresponding to the mounting plate (27), and the base structure for a building according to any one of claims 1 to 3. . 7. The base structure for a building according to any one of claims 1 to 6, wherein the slab (2) is for a floor. 8. The base structure for a building according to claim 1, wherein the slab (2) is for a wall. 9. The base structure for a building according to claim 1, wherein the slab (2) is for a ceiling.