KR20180038777A - Complex Structural System for Reducing Noise And Vibration - Google Patents

Abstract

The present invention relates to a noise and vibration reduction type complex building structure system. The noise and vibration reduction type complex building structure system has a rigid-frame and wall type mixed structure comprising pillars, beams, and walls. At the same time, bottom slab is designed as one-way hollow slab. According to the present invention, the complex building structure system comprises: a rigid-frame structure portion comprising the pillars vertically installed in a building and the beams horizontally installed in the upper ends of the pillars; the load bearing wall connected to a part of the pillars or spaced apart from a part of the pillars at a predetermined distance to be installed; and the hollow slab which is installed horizontally above the beam to form a floor surface or a ceiling of a building and in which a plurality of hollow bodies extending in one direction are reclaimed at predetermined intervals.

Description

{Complex Structural System for Reducing Noise And Vibration}

The present invention relates to an architectural structural system, and more particularly, to a composite structural structural system of a noise and vibration reduction type having a ramp and a wall type mixing structure of a column, a beam and a wall and a floor slab .

Existing apartment houses mainly consist of a structure with a bearing wall. The wall structure is composed of a slab and a bearing wall, so that it is widely applied to the construction of a residential building because it is easy to construct. In the conventional apartment house, the wall structure is formed of a bearing wall supporting the load of a partition wall building that divides a space inside the house as well as a generation boundary wall dividing the generation, so that the upper and lower walls are positioned at the same position in the vertical and vertical directions And a continuous structure to be installed. Such a wall structure is excellent in seismic performance, stratification, workability, and economy, but has a low bending stiffness of the slab and a large impact due to the vibration of the vertical member (wall).

The ramen structure is a structure made up of pillars and beams without a bearing wall, which is advantageous for heavy impact sound because of reduction of vibration due to reduction of vertical member and flexural rigidity of beam. However, it is disadvantageous to increase of floor height, workability and economical efficiency, .

The flat plate structure is a structure consisting of columns and slabs. There is no beam like a wall structure, and the load of the slab is transmitted to the foundation through the column like a beam structure. However, since the details of the structure for securing the vibration performance due to the long span, the weight of the bottom plate, and the shear performance are very complicated, it is economically disadvantageous to use the construction structure system to be.

Patent No. 10-0829223 Patent No. 10-0585850

An object of the present invention is to provide a composite building structure system capable of effectively reducing interlayer noise and having excellent economy.

According to an aspect of the present invention, there is provided a composite building structure system including a plurality of pillars vertically installed on a structure, and a plurality of beams horizontally installed on an upper end of the pillars; A load bearing wall connected to a part of the plurality of pillars or spaced apart from the load bearing wall by a predetermined distance; And a hollow slab installed horizontally above the beam to form a bottom surface or a ceiling of the building, wherein a plurality of hollow bodies extending in one direction are embedded at regular intervals.

The composite structure system according to the present invention has a structure in which a ramen structure and a wall structure are mixed, so that it is possible to select a variable plane according to a user's preference, unlike the existing wall structure and solve the problem of unbalanced moment of a flat slab, Design is possible. In addition, by structuring the flat slab into a ramen structure, it is possible to secure the structural advantage and the economical efficiency according to the process.

In addition, since the hollow slab of the present invention has a structure in which a plurality of unidirectional hollow bodies are arranged in one direction, the self-weight of the structure can be reduced, the cross-section of the column due to load sharing can be reduced, The design is simple, and the disadvantages of conventional flat slabs can be solved.

1 is a perspective view schematically illustrating a composite building structure system according to an embodiment of the present invention.
2 is a cross-sectional view showing the construction of a hollow slab of a composite building structure system according to the present invention.
3 is a longitudinal sectional view showing a composite building structure system according to the present invention.
4 is a cross-sectional view of a beam applied to a composite building structure system according to the present invention.
5 is a perspective view of a one-directional hollow body applied to a hollow slab of a composite building structure system according to the present invention.
FIG. 6 is a perspective view showing a state in which the one-directional hollow body shown in FIG. 5 is applied.
FIG. 7 is a cross-sectional view of a hollow portion of the hollow slab in which the one-directional hollow body shown in FIG. 5 is constructed.
8 is a plan view showing a part of a uni-directional hollow body according to another embodiment of the present invention.
9 is a perspective view showing a part of a uni-directional hollow body according to another embodiment of the present invention.
10 is a cross-sectional view illustrating a portion of a uni-directional hollow body according to another embodiment of the present invention.
11 is a cross-sectional view showing a part of a uni-directional hollow body according to another embodiment of the present invention.
12 is a side view of a buoyancy prevention device applied to a hollow slab of a composite building structure system according to the present invention.
13 is a cross-sectional view of the main portion of the buoyancy prevention device shown in Fig.
14 is a cross-sectional view showing the buoyancy prevention device shown in Fig. 12 in an exploded manner.
15 is an enlarged view of a portion A in Fig.
16 is a side view of an anti-buoyancy device according to another embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of a noise and vibration reduction type composite structure system according to the present invention will be described in detail with reference to the accompanying drawings.

1 and 2, a composite building structure system according to the present invention comprises a plurality of columns 1 vertically installed on a floor structure, a plurality of columns 1 connected to the upper ends of the columns 1, A load-bearing wall 3 connected to a part of the plurality of columns 1 or spaced apart from the column 1 by a predetermined distance; And a hollow slab 4 which is horizontally installed to form a plurality of hollow bodies 100 extending in one direction and forming an in-house plane.

The ramen structure portion is composed of a plurality of columns 1 and a horizontal beam 2, which are installed perpendicularly to the ground at corner portions of the inner plane of the house. The column 1 and the beam 2 of the ramen structure can be constructed by applying columns and beams having a known ramen structure.

The beam 2 is a haunch-type band-beam having a substantially pentagonal or hexagonal cross-section as shown in Figs. 4 (a) and 4 (b) desirable. If the beam 2 is made of a wide band beam, it is advantageous to close the punching front end of the hollow slab 4 and the column 1 and to solve the unbalanced moment generated in the hollow slab 4, Let the system behave like a ramen structure.

The bearing wall 3 is made of concrete or block and is connected to a part of a plurality of columns 1 of the ramen structure part or is spaced apart by a certain distance. The load bearing wall 3 may be constructed by applying a load bearing wall to a known wall structure.

As described above, the composite building structure system of the present invention has a structure in which the ramen structure and the wall structure are mixed, and thus the variability is improved.

The hollow slab 4 is constructed by placing a long pipe-shaped unidirectional hollow body 100 and a reinforcing bar on a slab formwork, and then placing concrete or cement mortar on the slab formwork. The buoyancy preventing device 200 is used to prevent the hollow body 100 from floating and floating by concrete or cement mortar when the hollow slab 4 is installed.

Since the hollow slab 4 has a structure in which a plurality of one-way hollow bodies 100 are embedded, it is possible to reduce the self weight of the structure, reduce the cross section of the column due to load sharing, There is an advantage that the disadvantages of existing flat slabs can be solved.

As shown in FIGS. 5 to 7, in this embodiment, the hollow body 100 includes two hollow members 110 having a hollow pipe shape in which hollow is hollow, and two hollow members 110 integrally connected to each other And a synthetic resin material such as EPS.

The hollow member 110 has a structure in which the two hollow members 110 are arranged in parallel to each other while being spaced apart from each other by a predetermined distance, and are integrated by the joint portion 120. The hollow member 110 has a pipe shape having a hollow portion 111 formed to penetrate from the one end to the other end in the longitudinal direction. The hollow portion 111 may be formed in a circular or elliptical shape, but may be formed in a polygonal shape such as a square or an octagon.

Each of the hollow members 110 preferably has a flat outer surface 112. When the outer surface of the hollow member 110 is formed as a flat surface rather than a curved surface as described above, when the plurality of hollow bodies 100 are installed, the cross section of the concrete between the hollow body 100 and the hollow body 100 is shown in FIG. As shown in Fig. 4, it has a constant width from the upper side to the lower side, and the moment of inertia of the cross section has the same size as the conventional one.

A plurality of the joint portions 120 are arranged at regular intervals between the two hollow members 110 along the longitudinal direction of the hollow member 110 to integrally connect the two hollow members 110. Therefore, a through hole 122 penetrating in the vertical direction is formed between the respective joint portions 120. The through hole 122 forms a space filled with concrete, so that the adhesion force between the hollow body 100 and concrete can be greatly increased. In addition, the through hole 122 forms a passageway that can be installed while the reinforcing steel bar is vertically laid, or when a wire or other structure passes in the vertical direction, and a buoyancy for preventing the buoyancy of the hollow body 100 And acts to form a passage through which the prevention device 200 can pass.

The joint part 120 may be formed integrally with the hollow member 110. Alternatively, the joint part 120 may be formed as an individual body, and may be fixedly coupled to the inner side surface of the hollow member 110 through a separate fastening member. . The upper surface and the lower surface of the joint 120 may have a flat rectangular shape, but the upper surface and the lower surface may have a concave shape that is concave downward and upward, respectively, as in this embodiment. If the upper and lower surfaces of the joint part 120 have a curved shape, the load of the concrete can be uniformly dispersed on the upper and lower surfaces of the joint part 120, so that the support strength can be improved.

As shown in FIG. 8, in order to further increase the adhesive force with concrete when the concrete is filled in the through hole 122 between the joint portions 120, concrete is applied to the inner surface of the through hole 122 The concavities and convexities 123 may be formed. Here, the concavities and convexities 123 are formed in a trapezoidal column shape, which is more advantageous for increasing the adhesive force.

In order to prevent the concrete from flowing into the hollow portion 111 of the hollow member 110 when the hollow slab is installed by pouring the concrete, the hollow portion of the hollow member 110 is formed at both ends of the hollow member 110 111 is closed.

The shielding member 130 may have a rectangular flat plate shape as shown in FIG. In this case, U-shaped slide rails 140 may be installed at both ends of the hollow member 110 so that both end portions of the shield 130 are slidably coupled. The shielding member 130 slides along the slide rail 140 while sliding both ends of the shielding member 130 to both sides of the slide rail 140 so that one end of the hollow portion 111 of the hollow member 110 It is possible to prevent the introduction of the concrete and to prevent the shielding member 130 from being detached from the hollow member 110 during the inflow of the concrete.

10, the shielding member 130 may have a fitting portion 131 inserted into the hollow portion 111 in a size and shape corresponding to the hollow portion 111 of the hollow member 110, And a cover part 132 having a larger size than the fitting part 131 on the outer side of the fitting part 131 and closely attached to the outer surface of the end part of the hollow member 110.

In this case, the cover 132 may be fixed to the end of the hollow member 110 by a separate fastening means or an adhesive.

11 shows another embodiment of the shielding member 130. The shielding member 130 of this embodiment is disposed in the hollow portion 111 of the hollow member 110 disposed on one side of a hollow body 100 And a second shielding part 130a inserted into the hollow part 111 of one side of the other hollow body 100 arranged side by side on one side of the hollow body 100, The first shielding part 130a and the second shielding part 130b are integrally formed to shield the hollow part 111 of the hollow member 110, And also serves as an interval member for keeping the interval of the display unit 100 constant.

The first shielding part 130a and the second shielding part 130b are respectively formed with the fitting parts 131a and 131b inserted into the hollow part 111 like the shielding member 130 shown in FIG. 132b which are in close contact with the outer surface of the end of the hollow member 110 at the outer sides of the first and second shielding portions 131a, 131b, and the cover portion 132a of the first shielding portion 130a and the cover portion 132a, And the cover portion 132b of the shielding portion 130b are integrated with each other.

Since the one-way hollow body 100 of the present invention can reduce the concrete cross-sectional area to reduce the amount of concrete used, it is possible to improve the economical efficiency, It is very easy to construct and has an excellent vibration absorbing ability against a heavy impact source.

The buoyancy preventing device 200 for preventing the hollow body 100 from floating during the construction of the hollow slab 4 may be installed horizontally and horizontally on the upper side of the hollow body 100, And presses the upper vertical reinforcing bars 43a and the upper vertical reinforcing bars 43b downward. 12 to 15, the buoyancy prevention device 200 according to the present embodiment includes a support portion 210 having a lower end portion fixedly coupled to the slab formwork 41, A first support 220 and a second support 230 for supporting the upper transverse reinforcement 43a and the upper transverse reinforcement 43b respectively disposed in the transverse and longitudinal directions on the upper side of the hollow body while being fitted together, And a nut member 240 which is formed on an upper end of the first support member 220 and the second support member 230 and fixes the first support member 220 and the second support member 230 to the support member 210.

The support part 210 is formed in a long circular bar shape and is installed in the slab formwork 41 so as to extend in the vertical direction. The male threads 211 and 212 are formed on the outer peripheral surfaces of the lower end portion and the upper end portion of the support portion 210. The male threads 211 formed at the lower portion are fixed to the slab die 41 And the nut member 240 is spirally engaged with the male screw thread 212 formed on the upper part.

The first and second support rods 220 and 230 have a rectangular cross section and are respectively formed with through holes 221 and 231 through which the upper ends of the support portions 210 are inserted, As shown in Fig.

The first support platform 220 is disposed on the lower side of the second support platform 230 so as to be in close contact with the upper end of the upper horizontal reinforcing bar 43a for constructing the hollow slab and the second support platform 230 supports the first support platform 220 So as to support the upper longitudinal reinforcing bar 43b while being in close contact with the upper end of the upper longitudinal reinforcing bar 43b.

A cylindrical guide boss (not shown) is inserted into the through hole 221 of the first support base 220 in the outer periphery of the through hole 231 of the second support base 230 disposed above the first support base 220 232 are formed to extend downward. When the first support 220 is coupled to the upper end of the support 210 and then the second support 230 is coupled to the upper end of the support 210, the guide boss 232 of the second support 230 The contact area between the first support 220 and the second support 230 increases while the nut member 240 is inserted into the upper end of the support 210. The nut member 240 is inserted into the through hole 221 of the first support 220, The urging force of the nut member 240 is transmitted to the first supporter 220 through the guide boss 232 when the second supporter 230 is pressed downward, 230 can stably support the upper transverse reinforcement 43a and the upper transverse reinforcement 43b without shaking.

Gripping portions 223 and 233 in the form of gear teeth which are in contact with the upper ends of the reinforcing bars may be formed on the lower surfaces of the first and second supports 220 and 230 along the longitudinal direction. The concave and convex portions 223 and 233 prevent slippage between the lower surface of the first support platform 220 and the second support platform 230 and the upper transverse reinforcement 43a and the upper longitudinal reinforcement 43b, .

16, when the first support bar 220 and the second support bar 230 are in close contact with and supported by the upper horizontal bar 43a and the upper vertical bar 43b, In order to eliminate the clearance due to the difference in height between the lower surface of the second support table 230 and the upper end of the upper transverse reinforcement 43a and the upper transverse reinforcement 43b and to prevent slippage by increasing frictional force therebetween, An elastic pad 260 of a flexible resin such as rubber or silicone may be attached to the lower surface of the support table 220 and the second support table 230.

The nut member 240 is in the form of a polygonal ring having a female screw thread 241 formed on the inner circumferential surface of the hole formed at the center thereof and is coupled to the male screw thread 212 of the support portion 210. The nut member 240 applies a downward force to the first and second supports 220 and 230 on the upper side of the second support 230 so that the first and second supports 220 and 230 From separating from the support portion 210.

When the first support 220 and the second support 230 are connected to each other by sandwiching the first support 220 and the second support 230 on the upper portion of the support 210, Since the upper horizontal reinforcing bars 43a and the upper vertical reinforcing bars 43b are simultaneously supported on the upper side of the hollow body 100, the construction can be easily and quickly performed.

The architectural structure system according to the present invention can select a variable plane according to a user's preference, unlike the existing wall structure, and can solve the problem of unbalanced moment of the flat slab, thereby enabling a simple design. In addition, by structuring the flat slabs into a ramen structure, it is possible to secure the structural advantages and economical efficiency of each process.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it will be understood by those skilled in the art that various changes and modifications may be made without departing from the spirit and scope of the present invention as defined by the appended claims. And it is to be understood that such modified embodiments belong to the scope of protection of the present invention defined by the appended claims.

1: Column 2: Beam
3: proof wall 4: hollow slab
41: slab formwork 42:
43: upper reinforcing bar 43a: upper side reinforcing bar
43b: upper longitudinal reinforcing bar 100: hollow body
110: hollow member 111: hollow member
112: Outer side 120:
122: Through hole 123: concave and convex
130: shielding member 140: slide rail
200: Buoyancy prevention device 210:
212: male threads 220: first support
221: through hole 230: second support
231: second support bar 232: guide boss
240: nut member 250: fixing nut
260: elastic pad 270: interference avoidance washer

Claims (15)

A plurality of columns vertically installed on the structure, and a plurality of beams horizontally installed on the upper end of the column;
A load bearing wall connected to a part of the plurality of pillars or spaced apart from the load bearing wall by a predetermined distance;
A hollow slab installed horizontally above the beam to form a bottom surface or a ceiling of the building and having a plurality of hollow bodies extending in one direction at a predetermined interval;
And a noise suppression type composite structure structure system. The system of claim 1, wherein the ramen structure is a band-beam having a pentagonal or hexagonal cross-sectional shape. The method according to claim 1,
Two hollow members having a hollow hollow pipe shape and arranged in parallel to each other while maintaining a constant gap;
A joint part which is arranged between the two hollow members at intervals along the longitudinal direction and integrally joins the two hollow members;
And a noise suppression type composite structure structure system. 4. The system as claimed in claim 3, wherein the hollow member has a circular or elliptical cross-sectional shape having a flat outer surface. [4] The system of claim 3, wherein the joint has a curved surface shape in which the upper surface and the lower surface are concave downward and upward, respectively. The system of claim 3, further comprising a shielding member installed at both ends of the hollow member to close the hollow portion of the hollow member. The slide rail according to claim 6, wherein the shielding member is formed in the shape of a quadrangular flat plate, and both end portions of the hollow member are provided with U-shaped slide rails to which both end portions of the shielding member slide while being coupled. Reduced Composite Building Structure System. [7] The apparatus of claim 6, wherein the shielding member has a size and shape corresponding to the hollow portion of the hollow member and is inserted into and coupled to the inside of the hollow portion, And a cover portion that is in close contact with an outer surface of an end portion of the noise suppressing structure. [7] The apparatus according to claim 6, wherein the shielding member comprises: a first shielding portion inserted and coupled into a hollow portion of the hollow member disposed at one side of the hollow member; and a second hollow member disposed adjacent to one side of the hollow member Wherein the first shielding portion and the second shielding portion are integrally formed to shield the hollow portion of the hollow member and at the same time, Wherein the noise reduction system includes a noise suppression system. 4. The system as claimed in claim 3, wherein a trapezoidal columnar concavity and convexity are formed on an inner surface of the space between the joints to increase the adhesive force with concrete. The method as claimed in claim 1, wherein in the process of constructing the hollow slab by supporting the upper horizontal reinforcing bar and the upper vertical reinforcing bar horizontally while crossing in the horizontal direction and the vertical direction on the upper side of the hollow body in the hollow slab, Further comprising a buoyancy preventing device for preventing a floating of the hollow body. [12] The apparatus as claimed in claim 11, wherein the lower end portion is fixedly coupled to the slab formwork and is installed to extend in the vertical direction with respect to the slab formwork;
A first support which is formed in a through hole to be inserted into an upper end of the support portion and is closely attached to an upper end portion of an upper horizontal reinforcing bar arranged in a horizontal direction from an upper side of the hollow body;
A second support which is formed in a through hole to be inserted into the upper end of the strut, and which is supported in close contact with an upper end of an upper longitudinal steel reinforced in a longitudinal direction at an upper side of the hollow body;
Fixing means for fixing the first support and the second support to the support portion so that the first support and the second support are kept in close contact with the upper horizontal reinforcement and the upper vertical reinforcement, respectively;
And a noise suppression type composite structure structure system. 13. The apparatus according to claim 12,
A male thread formed on an outer circumferential surface of an upper portion of the strut;
A nut member that is spirally coupled to the male thread of the strut at the upper side of the second support so as to press and support the first support and the second support downward;
And a noise suppression type composite structure structure system. The structure of claim 12, wherein a cylindrical guide boss inserted into the through hole of the first support base is formed on the outer peripheral edge of the through hole of the second support base so as to extend downward. system. 13. The system of claim 12, wherein a flexible resin elastic pad is attached to the lower surface of the first support and the second support.

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