KR102002976B1 - Balance adjustable supporting pad structure on slab - Google Patents

Abstract

The present invention relates to a structure for supporting a top structure (10) spaced upward from a concrete bottom surface and adjusting a height and a slope of the top structure. The structure is provided on the bottom surface (1) 111), and a plurality of coupling holes (150) are formed on the side walls; A plurality of cutouts 221 formed along the vertical direction at the lower end of the main body 210 and a plurality of cutouts 221 formed between the cutouts 221 And a plurality of movable parts (220) formed in the vertical direction and having a plurality of long holes (250) formed along the vertical direction; The plurality of movable parts 220 are inserted into the bottom fixing member 100 through the twisting part 111 so that the coupling member 150 and the fastening member 300), thereby providing a prefabricated support structure that is installed on a concrete floor having excellent workability and structural safety.

Description

[0001] DESCRIPTION [0002] BALANCE ADJUSTABLE SUPPORTING PAD STRUCTURE ON SLAB [0003]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a construction field, and more particularly, to a horizontally adjustable support structure that supports a heavy object such as a water tank,

A prefabricated water tank is installed in the basement or roof of the building, which is installed to be spaced apart from the bottom of the concrete by a certain distance for inspection and maintenance of the prefabricated water tank.

In this way, the supporting structure provided on the concrete floor for supporting the water tank is required to be easy to install and excellent structural safety.

In particular, when the water tank is large, a large number of supporting structures to be installed on a wide floor area are required. Since the concrete floor does not have a perfect horizontal structure, the height and tilt of the supporting structure are adjusted for each installation position of the supporting structure, It is necessary.

1 to 3 relate to Korean Patent Registration No. 10-1458144 (Stainless Steel Composite Tank).

As shown in the figure, the stainless steel water tank includes a floor frame 120 formed of a plurality of frames on the upper part of a base pad 110 made of concrete, a zinc-plated floor panel 130 made of a galvanized steel plate, a stainless steel The bottom panel 140 is stacked to form the bottom structure of the water tank and the upper part of the PDF panel 210 is configured to form the top plate structure of the water tank.

Here, the bottom structure of the water tank is made of concrete, and a plurality of base pads 110, which are elongated in the width direction of the water tank, are spaced apart from each other by a predetermined distance. A plurality of zinc-plated bottom panels 130 are installed along the longitudinal direction of the base pads 110 and the bottom frame 120 and the zinc plated A stainless steel floor panel 140 having a flat plate shape is provided on the floor panel 130 to constitute a bottom structure of the water tank.

Here, the bottom frame 120 has a shape of a polygonal shape of approximately "C" and is located at the edges in the width direction and the longitudinal direction of the water tank, thereby constituting the area of the water tank, Through an anchor bolt or the like.

In addition, the bottom frame 120 is formed with through-holes 122 through which the bolts pass so as to be integrally formed with the zinc-plated bottom panel 130 by fastening means such as bolts and nuts.

The bottom frame 120 is composed of a frame member 124 having a straight line and a connecting bracket 126 connecting the frame member 124 so as to be elongated in the longitudinal direction and the width direction of the water tank.

The connecting bracket 126 is located at each corner of the bottom frame 120 so as to connect both ends of the frame member 124, that is, the corner of the frame member 124. The connecting bracket 126 includes a frame member 124, The fastening means 102 such as a screw is used.

That is, the bottom frame 120 is formed in a rectangular shape such that the bottom of the water tank is formed as a rectangular shape.

The galvano bottom panel 130 is formed in the space between the bottom frames 120 which are configured to be spaced apart from each other by a predetermined distance so as to load the water tank together with the base pad 110 And a plurality of the water tank is constructed so as to maintain the rigidity of the bottom structure of the water tank.

The zinc layer floor panel 130 includes a side frame 132 formed vertically so as to be fastened to the floor frame 120 or to be fastened between the zinc floor panels 130, And an upper frame 134 which is positioned in the space between the base pads 110 and has the same position as the upper end of the floor frame 120 and on which the stainless steel floor panel 140 is mounted.

The side frame 132 of the zinc layer floor panel 130 is formed with a communication hole 136 formed in the inner periphery of the bottom frame 120 and communicating with the through hole 122 formed in the bottom frame 120, Or the zinc-plated bottom panels 130 may be welded to each other. However, the present invention is not limited thereto, and the zinc-plated bottom panels 130 may be welded to each other.

In addition, the upper frame 134 of the zinc-plated floor panel 130 is stacked with a stainless steel floor panel 140 for improving the water-tightness while supporting the load of the water tank, and a stainless steel floor panel 140 And the unit panels 10 constituting the wall surface of the water tank are welded.

The bottom frame 120 and the zinc-plated bottom panel 130 are made of a galvanized steel plate, and the bottom structure of the water tank is formed together with the base pad 110 to support the load of the water tank .

In addition, a gasket may be further provided between the bottom frame 120 and the zinc-plated bottom panel 130, thereby enhancing the fastening force of the bolts and the nuts and improving the bonding force between the frames.

The stainless steel floor panel 140 is stacked on the floor frame 120 and the zinc floor panel 130 to maintain rigidity with respect to the bottom structure of the water tank. The stainless steel floor panel 140 is made of stainless steel, And a thickness of at least 1.0t.

Since the stainless steel floor panel 140 is formed in the shape of a flat plate, it is easy to join with the bottom frame 120 constituting the bottom surface of the water tank, and the construction of the base channel is not necessary. .

In addition, the stainless steel floor panel 140 is joined to the bottom frame 120 at the ends of the peripheral surface, and the unit panels 10 constituting the wall surface of the water tank are welded together.

Figs. 4 to 15 relate to Korean Patent Registration No. 10-1482082 (height adjuster and water tank support with enhanced seismic performance).

The lower pedestal 10 and the upper pedestal 20 installed on the floor surface are screwed together by the screw portions 10 'and 20' so that the height of the upper pedestal 20 can be adjusted.

A cylindrical upper housing 25 and a lower housing 15 are pivotally coupled to the upper and lower supports 20 and 10 so that the upper housing 25 and the lower housing 15 Each comprise an upper ring 26 and a lower ring 16 for connection of the connection supports 30, 40, respectively.

Particularly, on the outer wall surfaces of the lower housing 15 and the upper housing 25, rail grooves 17 and 27 are formed in four directions in the vertical direction so that the height of the upper and lower rings 16 and 26 can be adjusted.

A pinhole 21 is formed in the upper pedestal 20 and a pin 22 for preventing the upper housing 25 from falling down is fastened to the pinhole 21.

One of the support pins 22 may be fastened in a through-hole manner, or the four individual pieces may be fastened at regular intervals to prevent the upper housing 25 from falling.

A plurality of water tank bases are installed in a manner connected to the interconnecting supports 30 and 40.

That is, the connection supports 30 and 40 are connected to the lower ring 16 and the upper ring 26 provided in the water tank supports in an X-shaped crossing manner or parallelly connected to each other, (30, 40) are connected to each other to perform a stable supporting function of the water tank (1).

Particularly, in the installation process, the height of each water tank support is appropriately adjusted according to the height of the floor so as to be closely attached to the bottom surface of the water tank 1. When the height of the support member is to be adjusted, It is possible to easily adjust the height by screwing the lower pedestal 10 with the lower pedestal 10.

Further, the upper and lower hooks 16 and 26 can be adjusted to move upward and downward along the rail grooves 17 and 27, respectively, so that the upper and lower hooks 16 and 26 are rotated at appropriate heights, So that the water tank 1 can be more stably supported by the connection with the connection supports 30 and 40. In this way,

Accordingly, the water tank support has a structure in which the upper and lower housings 15 and 25 can be attached to and detached from the upper and lower pedestals 10 and 20, Since the connection supports 30 and 40 are connected to the first and second support members 25, more stable support can be achieved.

16-19 relate to Korean Patent Registration No. 10-1499111 (Hybrid Foundation for Water Tanks).

The water tank WT is provided with a height adjustment hole 12 which is opened in a height direction at a lower portion in the shape of a rectangular parallelepiped which is vertically perforated. A plurality of main bodies 10 spaced from each other at a predetermined interval on a floor to be installed; A base plate 20 coupled to a bottom of each side of the main body 10 to support the main body 10 on a floor and having bolt holes 22 of a predetermined cross section formed on one side thereof, ; And a wing portion 30b that is coupled at right angles at both ends of the center portion 30a so as to have a plate shape as a whole, A connecting plate 30 to which the central portion 30a is closely contacted; The bolt hole 22 of the receiving plate 20 and the height adjusting hole 12 of the one side of the main body 10 and the height adjusting hole 12 located on the opposite side and the bolt hole Through bolts (40) fixed through the nuts (22) through the nuts (22); A mortar portion 50 filled in the body 10; And a connecting frame 60 having opposite ends fixed to the inside of the wing portion 30b of the connecting plate 30 to connect the adjacent bodies 10 with each other, And the height of the main body 10 is adjusted according to the position where the main body 10 is fixed.

The hybrid base for the water tank WT is largely composed of the main body 10, the foot plate 20, the connecting plate 30, the penetrating bolts 40, the mortar portion 50 and the connecting frame 60.

The receiving plate 20 and the connecting plate 30 are coupled to the upper and lower portions of the main body 10.

The main body 10 is a vertical member on the basis of a water tank WT and is formed in the form of a rectangular pipe made of a material such as a steel pipe. That is, a shape of a rectangular parallelepiped having a hollow therein, and the height thereof is preferably about 50 to 60 cm, so that it is desirable that the maintenance can be checked. Of course, it can be composed of various materials and heights if it meets current regulations and structural safety.

The main body 10 has four side surfaces, and a height adjustment hole 12 in the form of a slot or a slot is formed at the bottom of each side. The height adjustment hole 12 is long in the height direction and plays an important role in adjusting the distance of the upper end of the main body 10 from the ground.

The support plate 20 is coupled to the lower side of the main body 10 and serves as a bridge for supporting the main body 10. The support plate 20 is formed of a plate member having a cross-sectional shape of '?', And can be manufactured by bending one plate or welding two plates. At this time, one surface is coupled to the side surface of the main body 10, and the other surface is brought into contact with the ground surface.

In addition, a bolt hole 22 is formed in one surface of the support plate 20 and is punched to a predetermined diameter at a position corresponding to the height adjustment hole 12 of the main body 10. The bolt hole 22 of the support plate 20 and the height adjustment hole 12 of the main body 10 are coupled to each other while passing through the bolt hole 22 and the height adjustment hole 12, So that the through bolts 40 are fastened to each other and there is no lateral flow.

The through bolt 40 has a height adjusting hole 12 through which the bolt hole 22 and the height adjusting hole 12 are inserted and which is located on the opposite side of the body 10, The bolt hole 22 of the support plate 20 is also passed. At this time, the nuts (N) are fastened to the protruding part, so that the through bolts (40) are fixedly coupled. Here, the height of the main body 10 is determined by the position where the through bolt 40 passes through the height adjusting hole 12, which is long in the height direction.

In other words, the support plate 20 and the main body 10 are fixedly coupled to each other by fastening the through bolts 40. When the through bolts 40 passing through the bolt holes 22 of the support plate 20 abutting on the ground come into contact with the main body 10, The distance that the main body 10 is separated from the ground surface is determined according to the position of the main body 10 passing through the height adjustment hole 12 of the main body 10,

It is preferable that the bolt hole 22 of the support plate 20 and the bolt hole 22 of the support plate 20 adjacent to the support plate 20 are formed at positions which are different in height by the diameter of the through bolt 40. This is because a pair of through bolts 40 passing through the inside of the main body 10 are coupled to each other so as to intersect with each other. If they are passed at the same height, they will interfere with each other and become unreachable. It is possible to pass through the inside of the main body 10 while being in contact with each other and to have a more rigid structure.

On the other hand, if the height of the main body 10 needs to be adjusted, the fastened through bolt 40 can be dismantled and re-fastened by the above-described procedure, and workability is greatly improved.

The connecting plate 30 has a role of fixing the connecting frame 60 connecting the main body 10 to the main body 10 by a plate member having a " . The connecting plate 30 includes a central portion 30a coupled to a side surface of the main body 10 and a wing portion 30b extending vertically from both ends of the central portion 30a.

At this time, the main body 10 is provided with a coupling groove 14 having a predetermined cross section at its upper portion on each side, and a first coupling groove 32 is formed in the central portion 30a of the coupling plate 30 at a position corresponding to the coupling groove 14, And the main body 10 and the connecting plate 30 can be fixedly coupled to each other by a first fastening member B such as a bolt passing through the fastening groove 14 and the first fastening groove 32. [

The connection frame 60 is a member for connecting the main body 10 installed at a predetermined distance from the floor where the water tank WT is installed and connected to the connecting plate 30 . At this time, the connecting plate 30 is formed with a second binding groove 34 which is perforated in a predetermined section in each wing 30b, and the connecting frame 60 is connected to the second binding groove 34 of the wing 30b And can be fixedly coupled by a second fastener (B ') such as a through bolt.

Further, the connection frame 60 can be used as a lower frame of the water tank WT, which is made up of a pipe or a pipe. By omitting a part of the process for installing the water tank WT, .

However, the above-mentioned prior arts have been pointed out that the workability is not good because the operation of adjusting the height and tilt of the support structure (column) is inconvenient.

For example, in Korean Patent Registration No. 10-1482082 (height adjuster and water tank support with enhanced seismic performance), it is necessary to form a screw on the pipe, which is cumbersome.

The reference numerals of the prior art are intended to be limited only by the description of the prior art.

Korean Patent Registration No. 10-1458144 (Stainless Steel Composite Tank) Korean Registered Patent No. 10-1482082 (water tank support with height adjustment and seismic performance enhancement) Korean Patent Registration No. 10-1499111 (hybrid base for water tank)

SUMMARY OF THE INVENTION It is an object of the present invention to provide a prefabricated support structure that is installed on a concrete floor having excellent workability and structural safety.

In order to solve the above problems, the present invention provides a structure for supporting the upper structure (10) spaced upward from the concrete bottom surface and adjusting the height and tilt of the upper structure (10) A bottom fixing member (100) having a trough portion (111) formed on an upper portion thereof and a plurality of coupling holes (150) formed on a side wall thereof; A plurality of cutouts 221 formed along the vertical direction at the lower end of the main body 210 and a plurality of cutouts 221 formed between the cutouts 221 And a plurality of movable parts (220) formed in the vertical direction and having a plurality of long holes (250) formed along the vertical direction; The plurality of movable parts 220 are inserted into the bottom fixing member 100 through the twisting part 111 so that the coupling member 150 and the fastening member 300). ≪ RTI ID = 0.0 > [10] < / RTI >

It is preferable that the vertical section of the bottom fixing member 100 and the column member 200 have a polygonal structure.

The bottom fixing member 100 includes a bottom portion 120 coupled to the bottom surface 1; A body 110 formed on an upper portion of the bottom portion 120 and having a polygonal vertical section, the upper portion formed with the twisting portion 111, and the plurality of coupling holes 150 formed on the side wall; .

It is preferable that the movable part 220 is inserted into the bottom fixing member 100 through the twisting part 111 while being folded inward.

The main body 210 is preferably formed with a work hole 310 for fastening the fastening member 300.

The present invention relates to a structure for supporting an upper structure 10 spaced upward from a concrete bottom surface and controlling height and tilt of the upper structure 10. The upper structure 10 is installed on the bottom surface 1, A bottom fixing member 100 having a plurality of coupling holes 150 formed in side walls thereof; A first body portion 210a having a first trough portion 111a formed on an upper portion thereof and a plurality of first coupling holes 150a formed on a side wall thereof; A plurality of first movable portions 220a formed in a region between the first slits 221a and the first slits 221a and having a plurality of first long holes 250a formed along the vertical direction, A first pillar member 200a; A second body portion 210b having an upper end coupled to a lower portion of the upper structure 10 and a plurality of second cutouts 221b formed along a vertical direction at a lower end of the second body portion 210b, A second pillar member 200b having a plurality of second movable parts 220b formed in the area between the two cutouts 221b and having a plurality of second long holes 250b formed along the vertical direction; The plurality of first movable parts 220a of the first column member 200a are inserted into the bottom fixing member 100 through the twisting part 111 and the first and second movable parts 220a, A first fastening member 300a fastened to the long hole 250a in common; The plurality of second movable parts 220b of the second pillar member 200b are inserted into the first pillar member 200a through the first trough part 111a, And a second fastening member 300b fastened to the first long hole 150a and the second long hole 250b.

The inner surface of the first pole member 200a is preferably formed with a twist resistance portion 230 having a radially symmetric structure.

It is preferable that the torsion resistor 230 is formed in a plate shape extending along the longitudinal section.

The first engaging hole 150a is formed on the torsion resistance portion 230 and the fastening member 300 is fastened between the torsion resistor portion 230 and the first cutout portion 221a. It is preferable that the first work hole 310a is formed.

The present invention provides a method of constructing a horizontally adjustable support structure on a floor, comprising the steps of: installing the floor fixing member (100) on the floor (1); Inserting a plurality of movable parts (220) of the column member (200) into the bottom fixing member (100) through the twisting part (111); The provisional fastening member 320 is commonly fastened to some of the engagement holes 151 of the plurality of engagement holes 150 and a part of the long holes 251 of the plurality of long holes 250, A temporary fastening and adjusting step of adjusting a height and a slope of the slider; A first fixing step of jointing the coupling member (300) to the remaining coupling hole (152) of the plurality of coupling holes (150) and the remaining elongated hole (252) of the plurality of elongated holes (250) in common; The temporary fastening member 320 is removed and the temporary fastening member 320 is fastened to the partially fastening hole 151 and the partially elongated hole 251 to fasten the fastening member 300 in common The method comprising the steps of: (a) fixing a floor to a floor;

The temporary fastening and adjusting step may include a step of joining the plurality of holes 150 formed in the mutually opposing positions with each other, 251, it is preferable that the temporary fastening members 320 are fastened in common so as to adjust the height and tilt of the column member 200.

A plurality of engaging holes 150 are formed in a pair of side walls of the plurality of side walls of the bottom fixing member 100 facing each other. Each of the pair of movable parts 220 is formed with a plurality of long holes 250. The temporary fastening and adjusting step may include a step of joining the plurality of coupling holes 150 to the coupling holes 151 formed at mutually diagonal positions The temporary fastening members 320 may be commonly fastened to the elongated holes 251 formed at mutually diagonal positions of the plurality of elongated holes 250 to adjust the height and tilt of the post 200 .

The present invention provides a prefabricated support structure that is installed on a concrete floor having excellent workability and structural safety.

1 to 3 relate to Korean Patent Registration No. 10-1458144 (Stainless Steel Composite Tank).
Figs. 4 to 15 relate to Korean Patent Registration No. 10-1482082 (height adjuster and water tank support with enhanced seismic performance).
16-19 relate to Korean Patent Registration No. 10-1499111 (Hybrid Foundation for Water Tanks).
20 shows an embodiment of the present invention,
20 is an exploded perspective view of a first embodiment of a support structure;
Figures 21 to 24 are process drawings of a first embodiment of a method of constructing a support structure.
25 is an exploded perspective view of a second embodiment of a support structure.
Figures 26 to 28 are process drawings of a second embodiment of a method of applying a support structure.
29 is an exploded perspective view of a third embodiment of the support structure.
30 is a perspective view of a third embodiment of a support structure;
31 is a plan view of a third embodiment of a support structure.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

20 to 24, the present invention basically relates to a structure for supporting the upper structure 10 spaced upward from the bottom surface 1 by concrete or the like, and for adjusting the height and tilt And includes a bottom fixing member 100, a pillar member 200, and a fastening member 300.

The bottom fixing member 100 is provided on the bottom surface 1 and has a twisting portion 111 formed on an upper portion thereof and a plurality of coupling holes 150 formed on a side wall thereof.

The column member 200 includes a main body 210 having an upper end coupled to a lower portion of the upper structure 10, a plurality of cutouts 221 formed along the vertical direction at the lower end of the main body 210, And a plurality of movable parts 220 formed with a plurality of long holes 250 along the vertical direction.

The movable part 220 formed in the area between the cut-out part 221 may be slightly inclined with respect to the body part 210 because the cut part 221 is formed at the lower end of the body part 210. [ It is possible to bend deformation of the torsion bar.

The plurality of movable parts 220 are inserted into the bottom fixing member 100 through the twisting part 111 of the bottom fixing member 100 so that the coupling member 300 such as a bolt is inserted into the coupling hole 150 And is commonly tightened to the long hole 250.

The construction method of such a horizontally adjustable support structure is performed by the following process.

The floor fixing member 100 is installed on the floor 1.

The plurality of movable parts 220 of the column member 200 are inserted into the bottom fixing member 100 through the twisting part 111. [

The provisional fastening members 320 are commonly fastened to some of the engagement holes 151 of the plurality of engagement holes 150 and a part of the elongated holes 251 of the plurality of elongated holes 250, And the tilt is adjusted (Figs. 22 and 23).

Since the elongated hole 250 is formed in the movable part 220 of the column member 200, the height of the column member 200 can be adjusted so that the column member 200 and the floor fixing member 100 are coupled to each other at a desired height .

Further, when the bottom fixing member 100 and the column member 200 are temporarily fixed by the temporary fastening member 320 and the column member 200 is deformed in a desired direction with a tool such as a hammer, The slope of the column member 200 can be easily adjusted due to the movable portion 220 capable of bending deformation as described above (Fig. 22).

Here, the temporary fastening member 320 means a fastening member such as a bolt that is weakly coupled to the bottom fixing member 100 so as not to release the coupling between the bottom fixing member 100 and the pillar member 200, in order to facilitate the height and tilt adjustment.

When the elevation and inclination adjustment operations of the column member 200 are completed in the state where the temporary fastening member 320 is fastened, the remaining one of the plurality of engaging holes 150 and the plurality of elongated holes 250 The fastening members 300 are fastened to the remaining elongated holes 252 in common.

Here, since the fastening member 300 has a structure for permanent connection between the bottom fixing member 100 and the pillar member 200, the fastening member 300 is tightly coupled using a high tension bolt or the like.

Thereafter, the temporary fastening member 320 is removed, and the fastening member 300 is also commonly fastened to the partial engaging holes 151 and the elongated holes 251 to which the temporary fastening members 320 are fastened 24).

This makes it possible to easily form the rigid coupling structure of the column member 200 with respect to the bottom fixing member 100 and easily adjust the height and tilt of the column member 200.

Hereinafter, a concrete embodiment of the support structure and the construction method thereof according to the present invention will be described.

The effect of bending deformation of the movable portion 220 due to the formation of the cut portion 221 can be more stably obtained when the bottom fixing member 100 and the column member 200 have a polygonal structure such as a rectangular shape in the longitudinal section have.

To this end, the incision 221 is formed at each corner of the bottom fixing member 100 and the column member 200 whose vertical cross-section has a polygonal structure.

The bottom fixing member 100 includes a bottom portion 120 joined to the bottom surface 1 by an anchor or an adhesive; A body portion 110 formed by welding or the like on the upper portion of the bottom portion 120 and having a polygonal vertical section, a trough portion 111 formed on the upper portion, and a plurality of coupling holes 150 formed on the side wall, And the like.

In order to easily insert the column member 200 into the twisting portion of the bottom fixing member 100 and to easily adjust the height and tilt of the bottom portion of the bottom fixing member 100 relative to the width between the bottom outer surfaces of the plurality of the movable portions 220, It is preferable that the width between the inner surfaces is made large.

It is preferable that the thickness of the body 110 of the bottom fixing member 100 is larger than the thickness of the movable part 200 of the column member 200 in order to more reliably obtain the effect of adjusting the height and tilt of the column member 200 by the bending deformation of the movable member 220 220).

It is preferable that an additional reinforcing material be applied to the inner surface of the movable portion 220 rather than to form the movable portion 220 thicker when buckling of the movable portion 220 of the column member 200 is concerned.

When the nut is fastened to the inside of the bolt as the fastening member 300, it is preferable that a work hole 310 for fastening the upper fastening member 300 is formed on the body 210, Can be opened and closed by a separate stopper member.

As described above, in the state where the bottom fixing member 100 and the column member 200 are temporarily fixed (loosely engaged) by the temporary fastening member 320, a tool such as a hammer or the like is provided on the column member 200 When the movable member 220 of the column member 200 is moved in the direction of the arrow A in FIG. So that a stable coupling structure is achieved (FIG. 22).

A plurality of engagement holes 151 formed at mutually opposing positions of the plurality of engagement holes 150 and a plurality of elongated holes 251 formed at mutually opposing positions of the plurality of elongated holes 250 ) Are commonly clamped to adjust the height and tilt of the column member 200, there is added the effect of facilitating the adjustment operation.

21 and 23, a part of the coupling hole 151 (the coupling hole 150 of the front wall and the rear wall of the bottom fixing member 100) and a part of the elongated hole 251 (the front movable part and the rear movable part 251) (The joint hole 150 of the left side wall and the right side wall of the bottom fixing member 100) and the other joint hole 152 It is preferable for the workability to perform the above adjustment operation in a state where the provisional fastening member 320 is not engaged with the long hole 252 (the left movable part and the long hole 250 of the right movable part).

25 to 28, a plurality of coupling holes 150 are formed in a pair of sidewalls formed at mutually opposing positions of a plurality of sidewalls of the bottom fixing member 100, and a plurality of sidewalls of the plurality of sidewalls 220 There is added an advantage that a more rigid bolt connection structure can be achieved when a plurality of slots 250 are formed in each of the pair of movable parts 220 formed at mutually facing positions.

When a plurality of coupling holes 150 are formed on the side wall of the bottom fixing member 100 and one slot 250 of the coupling hole 150 and the movable portion 220 are coupled by a plurality of bolts, A more rigid coupling structure can be obtained.

In this case, with respect to the partial engagement holes 151 formed at mutually diagonal positions of the plurality of engagement holes 150 and the partial slots 251 formed at mutually diagonal positions among the plurality of slots 250, It is preferable that the fastening members 320 are fastened in common to adjust the height and tilt of the column member 200.

26 and 27, a part of the engaging holes 151 (the left engaging hole 150 of the front wall of the bottom fixing member 100 and the right engaging hole 150 of the rear wall) (The left elongated hole 250 of the front movable part and the right elongated hole 250 of the rear movable part) and the remaining engaging holes 152 (the bottom fixed member 100) The left joint hole 150 of the front wall of the front wall and the left joint hole 150 of the rear wall and all the joint holes 150 of the left wall and the right wall of the floor fixing member 100 and the remaining elongated holes 252 It is preferable that the upper adjustment operation is performed in a state where the temporary fastening member 320 is not engaged with the right elongated hole 250 of the rear movable part and the left elongated hole 250 and the left movable part and all the elongated holes 250 of the right movable part of the rear movable part. Lt; / RTI >

When the elevation and inclination adjustment operations of the column member 200 are completed in the state where the temporary fastening member 320 is fastened, the remaining one of the plurality of engaging holes 150 and the plurality of elongated holes 250 The fastening members 300 are commonly fastened to the remaining elongated holes 252 (Fig. 28).

Here, since the fastening member 300 has a structure for permanent connection between the bottom fixing member 100 and the pillar member 200, the fastening member 300 is tightly coupled using a high tension bolt or the like.

Thereafter, the temporary fastening member 320 is removed, and the fastening member 300 is jointly fastened to the partial engagement holes 151 and the elongated holes 251 to which the temporary fastening members 320 are fastened.

The height of the pillar member 200 and the inclination of the pillar member 200 are determined by the length of the long hole, the clearance between the body 110 of the bottom fixing member 100 and the movable part 220 of the pillar 200, The movable width of the movable portion 220, and the like.

In order to increase the degree of adjustment in spite of this limitation, a structure in which a plurality of the above-mentioned column members 200 are stacked may be applied.

This embodiment is constituted by a bottom fixing member 100, a first pillar member 200a, a second pillar member 200b, a first fastening member 300a and a second fastening member 300b (Fig. 29, 30).

The bottom fixing member 100 is provided on the bottom surface 1 and has a trench portion 111 formed thereon and a plurality of coupling holes 150 formed on the side wall thereof as in the above embodiment.

The first column member 200a has a first body portion 210a having a first trough portion 111a formed on an upper portion thereof and a plurality of first coupling holes 150a formed on a side wall thereof, A plurality of first slits 221a formed along the vertical direction at the lower end of the first slit 221a and a plurality of first slits 250b formed in the area between the first slit 221a and the plurality of first slits 250a along the vertical direction And one moving part 220a.

The second column member 200b includes a second body 210b having an upper end coupled to a lower portion of the upper structure 10 and a plurality of second cutouts formed along a vertical direction at a lower end of the second body 210b And a plurality of second movable parts 220b formed in the area between the second slits 221b and the second slits 221b and having a plurality of second long holes 250b formed along the vertical direction.

The first fastening member 300a is engaged with the engaging hole 150a in a state where the plurality of first movable parts 220a of the first column member 200a are inserted into the bottom fixing member 100 through the twisting part 111, And the first long hole 250a.

The plurality of second movable parts 220b of the second pillar member 200b are inserted into the first pillar member 200a through the first trough part 111a and the second pillar member 300b And is commonly tightened to the first coupling hole 150a and the second long hole 250b.

That is, the bottom fixing member 100 and the second column member 200b of this embodiment are substantially the same as the bottom fixing member 100 and the column member 200 of the above embodiment, 200a) is added to the first embodiment.

The lower part of the first column member 200a is the same as the structure of the upper column member 200 and the upper part of the first column member 200a is the same as the structure of the trunk part 110 of the upper floor fixing member 100 .

Accordingly, the first column member 200a can be coupled between the bottom fixing member 100 and the second column member 200b, and the coupling structure and the process are the same as in the above embodiment.

The height of the first column member 200a and the height of the second column member 200b can be adjusted so that the first and second column members 200a and 200b can be adjusted in height and inclination, It is possible to obtain the effect that the degree of adjustment of the height and the slope is increased as compared with the above embodiment.

If necessary, the degree of adjustment may be further increased by adding a third column member, a fourth column member, or the like.

Unlike the bottom fixing member 100 and the second pillar member 200b, the first pillar member 200a is not constrained by the other structure at its upper portion or lower portion, so that there is a fear that deformation may occur.

In order to prevent this, it is preferable that a torsional resistance portion 230 having a radial symmetrical structure is formed on the inner surface of the first columnar member 200a. Such a torsional resistance portion 230 may have a plate structure (Fig. 31).

The first operation hole 310a is formed through the side wall of the first pillar member 200a for the fastening operation of the fastening member 300. The first operation hole 310a is formed by the torsion- When the first work hole 310a is formed between the torsion resistor unit 230 and the first cutout unit 221a without being disturbed by the torsion resistor unit 230, There is an advantage that the fastening operation of the first fastening member 300a can be performed through the first work hole 310a (FIGS. 29 and 30).

The fastening operation of the fastening member 300a for engaging the first pillar member 200a and the bottom holding member 100 is performed before the engagement with the second pillar member 200b, Or may be accomplished through the upper opening of the first post 200a (when there is no first work hole 310a).

The fastening operation of the fastening member 300b for engaging the second pillar member 200b with the first pillar member 200a is performed before the fastening to the upper structure 10 by the second operation of the second pillar member 200b Hole 310b or through the upper side of the second pillar member 200b (when there is no second work hole 310b).

When the work hole 231 is formed at the core of the torsion resistor 230 and the trim is formed on the upper side of the second column member 200b, even if there is no first work hole 310a or second work hole 310b The fastening members 300a and 300b can be fastened through the upper flange of the second pillar member 200b before coupling to the upper structure 10. [

Also in the case of the support structure according to the present invention, the X-shaped bracing structure (Figs. 11 and 13) described in the prior art can be applied to form a reinforcing structure.
The first cutout portion 221a and the second cutout portion 221b are formed on the respective corner portions of the first pillar member 200a and the second pillar member 200b whose vertical cross-section has a polygonal structure The effect of bending deformation of the first movable part 220a and the second movable part 220b due to the formation of the first incision part 221a and the second incision part 221b can be more stably obtained.
The width between the upper end inner surfaces of the bottom fixing member 100 is larger than the width between the lower end outer surfaces of the first movable portion 220a and the width between the lower end outer surfaces of the second movable portion 220b, The first pillar member 200a and the second pillar member 200b can be easily attached to the bottom of the bottom fixing member 100 and the first pillar member 200a, It is easy to adjust the height and tilt.
The thickness of the body 110 of the bottom fixing member 100 is formed thicker than the thickness of the first movable part 220a of the first pillar 200a and the thickness of the first main part 210a The first movable member 220a and the second movable member 220b are deformed by the bending deformation of the first movable member 220a and the second movable member 220b when the thickness of the first movable member 220a is thicker than the thickness of the second movable member 220b of the second column member 200b And the effect of adjusting the height and tilt of the second column member 200b can be more stably obtained.
It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the invention as defined in the appended claims. It is to be understood that both the technical idea and the technical spirit of the invention are included in the scope of the present invention.

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1: Concrete floor 10: Superstructure
100: bottom fixing member 110: body part
111: twist portion 120: bottom portion
150, 151, 152: coupling ball 200:
210: main body 220: movable part
221: incision section 230: torsion resistance section
250, 251, 252: long hole 300: fastening member
310: work ball 320: temporary fastening member

Claims (12)

A method of constructing a horizontally adjustable support structure for supporting an upper structure (10) spaced upward from a bottom surface (1) and adjusting height and tilt,
The horizontally adjustable support structure comprises:
A bottom fixing member 100 provided on the bottom surface 1, having a trough portion 111 formed at an upper portion thereof and a plurality of coupling holes 150 formed at a side wall thereof;
A plurality of cutouts 221 formed along the vertical direction at the lower end of the main body 210 and a plurality of cutouts 221 formed between the cutouts 221 And a plurality of movable parts (220) formed in the vertical direction and having a plurality of long holes (250) formed along the vertical direction;
The plurality of movable parts 220 are inserted into the bottom fixing member 100 through the twisting part 111 so that the coupling member 150 and the fastening member 300, < / RTI >
The bottom surface of the bottom fixing member 100 and the column member 200 have a polygonal cross-
The bottom fixing member (100)
A bottom 120 coupled to the bottom surface 1;
A body 110 formed on an upper portion of the bottom portion 120 and having a polygonal vertical section, the upper portion formed with the twisting portion 111, and the plurality of coupling holes 150 formed on the side wall; Lt; / RTI >
The movable part 220 is inserted into the bottom fixing member 100 through the twisting part 111 in a folded state,
A work hole 310 for fastening the fastening member 300 is formed on the main body 210,
The cut-out portion 221 is formed at each corner of the column member 200 whose longitudinal section has a polygonal structure,
The width between the upper end inner surfaces of the bottom fixing member 100 is larger than the width between the lower end outer surfaces of the movable portion 220,
The thickness of the body portion 110 of the bottom fixing member 100 is formed thicker than the thickness of the movable portion 220 of the pillar member 200,
A method of constructing a horizontally adjustable support structure,
Installing the floor fixing member (100) on the floor surface (1);
Inserting a plurality of movable parts (220) of the column member (200) into the bottom fixing member (100) through the twisting part (111);
The provisional fastening member 320 is commonly fastened to some of the engagement holes 151 of the plurality of engagement holes 150 and a part of the long holes 251 of the plurality of long holes 250, A temporary fastening and adjusting step of adjusting a height and a slope of the slider;
A first fixing step of jointing the coupling member (300) to the remaining coupling hole (152) of the plurality of coupling holes (150) and the remaining elongated hole (252) of the plurality of elongated holes (250) in common;
The temporary fastening member 320 is removed and the temporary fastening member 320 is fastened to the partially fastening hole 151 and the partially elongated hole 251 to fasten the fastening member 300 in common And a car fixing step,
The temporary fastening and adjusting step comprises:
A plurality of engagement holes 151 formed at mutually opposing positions of the plurality of engagement holes 150 and a plurality of elongated holes 251 formed at mutually opposing positions of the plurality of elongated holes 250, The members 320 are commonly tightened to adjust the height and tilt of the column member 200,
A plurality of coupling holes 150 are formed in a pair of side walls formed at mutually opposing positions of the plurality of side walls of the bottom fixing member 100,
A plurality of elongated holes 250 are formed in the pair of movable parts 220 formed at mutually facing positions of the plurality of movable parts 220,
The temporary fastening and adjusting step comprises:
A plurality of engagement holes (151) formed at mutually diagonal positions of the plurality of engagement holes (150), and a plurality of elongated holes (251) formed at mutually diagonal positions of the plurality of elongated holes And the temporary fastening members (320) are commonly fastened to adjust the height and tilt of the column member (200). delete delete delete delete A structure for supporting the upper structure (10) spaced upward from the concrete bottom surface and adjusting the height and tilt of the upper structure (10)
A bottom fixing member 100 provided on the bottom surface 1, having a trough portion 111 formed at an upper portion thereof and a plurality of coupling holes 150 formed at a side wall thereof;
A first body portion 210a having a first trough portion 111a formed on an upper portion thereof and a plurality of first coupling holes 150a formed on a side wall thereof; A plurality of first movable portions 220a formed in a region between the first slits 221a and the first slits 221a and having a plurality of first long holes 250a formed along the vertical direction, A first pillar member 200a;
A second body portion 210b having an upper end coupled to a lower portion of the upper structure 10 and a plurality of second cutouts 221b formed along a vertical direction at a lower end of the second body portion 210b, A second pillar member 200b having a plurality of second movable parts 220b formed in the area between the two cutouts 221b and having a plurality of second long holes 250b formed along the vertical direction;
The plurality of first movable parts 220a of the first column member 200a are inserted into the bottom fixing member 100 through the twisting part 111 and the first and second movable parts 220a, A first fastening member 300a fastened to the long hole 250a in common;
The plurality of second movable parts 220b of the second pillar member 200b are inserted into the first pillar member 200a through the first trough part 111a, 150a and a second fastening member 300b jointed to the second long hole 250b,
A torsion resistive portion 230 having a radially symmetric structure is formed on the inner surface of the first columnar member 200a,
The torsional resistance unit 230 is a plate-like structure formed along the longitudinal direction,
The first coupling hole 150a is formed on the torsion resistor 230,
A first work hole 310a for fastening the first fastening member 300a is formed between the torsion resistor 230 and the first cutout 221a,
The first cutout 221a and the second cutout 221b are formed at each corner of the first pillar 200a and the second pillar 200b having a polygonal longitudinal section,
The width between the upper end inner surfaces of the bottom fixing member 100 is formed to be larger than the width between the lower end outer surfaces of the first movable portion 220a,
The width between the upper end inner surfaces of the first pillar member 200a is larger than the width between the lower end outer surfaces of the second movable portion 220b,
The thickness of the body 110 of the bottom fixing member 100 is formed thicker than the thickness of the first movable part 220a of the first pillar 200a,
Wherein a thickness of the first main body portion 210a of the first pillar member 200a is greater than a thickness of the second movable portion 220b of the second pillar member 200b. Type support structure. delete delete delete delete delete delete

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