KR101385155B1 - Reinforced concrete structure for vibration control using concrete shear key and the construction method therefor - Google Patents

Abstract

Provided are a concrete structure and a construction method for the same. When a concrete structure such as a residential building is constructed on an adjacent part of a section in which the vibration or the noise exists such as a railroad area, a vibration and noise reduction technique of a high level is necessary. Thus, the concrete structure can control noise or vibration to be efficiently blocked by providing an integrated vibration control device of a concrete shear key shape which is to block the vibration and comprises a shear key, a vibration resistant pad, and a tensile control member. [Reference numerals] (AA,BB,CC,EE) Vibration; (DD,FF) Uneven structure

Description

Concrete Structure for Vibration Control Using Concrete Shear Key and Construction Method {REINFORCED CONCRETE STRUCTURE FOR VIBRATION CONTROL USING CONCRETE SHEAR KEY AND THE CONSTRUCTION METHOD THEREFOR}

The present invention relates to a concrete structure for the vibration control using the concrete shear key and a construction method thereof, and more specifically, to control the vibration of the concrete structure to be installed in the vicinity of the section where vibration or noise (hereinafter, "vibration") is always present It relates to a concrete structure for the vibration control using the integrated vibration control device in the form of a concrete shear key for (absorption or blocking) and its construction method.

Generally, the top and bottom column arrangements may be different depending on the use of the building or for the purpose of changing the elevation. In this case, the transfer storey which transfers the axial load and horizontal load of the upper layer safely to the lower part for structural stability ) System.

That is, in the apartment complex or the apartment where the underground parking lot is designed, the lower part of the lower part is formed as an office, a shopping mall, a convenience store or a parking lot with a columnar ramen structure and an upper part is formed as an apartment (main part) The floor of the apartment wall of the apartment building and the lower part of the floor are not matched with each other, so that the transition layer is formed at the upper floor of the lower floor where the apartment starts to stably transfer the load of the upper part to the lower part.

FIG. 1A is a diagram illustrating a structure of a typical multi-family multi-unit house, in which a transition layer is formed.

In general, the multi-family multi-unit housing, as shown in Figure 1a, the beam-column ramen structure 20 suitable for the underground parking lot and the lower office space and the shear wall structure 10 or module suitable for the upper residential space It is composed of different (eg different column columns) beam-column structures, thereby providing a transition layer 30 for the transfer of stress between different structure types.

Since the transition layer 30 is a part where the shape and position of the concrete are changed when the concrete is poured into the building, it is possible to advance the entire air when the construction is performed quickly.

At this time, the transition layer 30 can be divided into a transfer girder and a transfer plate according to the structure.

For example, the transfer girder 31 is used in a multi-purpose building as shown in FIG. 1B, and the upper part of the basement floor and the ground floor, which are the parking lots of the multi-purpose building, have columnar beams and column structures (ramen structure). The second floor (residential part) is a wall-only wall structure without pillars. The beam and column structure is changed from the column structure to the wall structure, which is a transition layer, and is installed on both pillars of the transition layer from the upper side of the building. The transfer girder 31 is a combination of the loads transmitted to a plurality of walls to the lower pillars to be uniformly combined.

Transfer plate 32 is a plate formed of concrete to form a transition layer in the form of a reinforced concrete plate of a constant thickness as shown in Figure 1c to uniformly combine the loads transmitted to the plurality of walls from the upper side of the building and also to the lower column It is a structure.

Meanwhile, the multi-family multi-unit housing is located in the downtown area of a large city with convenient transportation, and in particular, since it may be installed adjacent to an area where a subway or a railroad passes through, the vibration generated from the vibration of the vehicle, the vibration of the subway, and the vibration of the railway. Alternatively, a situation is necessary for preventing noise from being transmitted to the upper driving section. For example, a dustproof pad may be used.

FIG. 1D illustrates some types of foundations of a building such as a multi-family multi-unit house, and in particular, it is possible to identify bearing foundations (stem foundations or mat foundations) 40 and pile foundations 50.

In the case of Korea, it is possible to secure a supporting layer such as rock among the thin paper, so the ground foundation (the foundation of the line or the mat foundation) (40) is used as the foundation of the building. The foundation of the foundation is the ground on which the building is to be constructed And a reinforced concrete base plate having a constant thickness. On the upper surface of the base plate, the lower part of the column to be installed in the basement (parking lot, etc.) of the building may be supported, and the wall of the basement layer may be supported.

In addition, a file base 50 for installing a file is provided on the bottom surface of the foundation. For example, a file is further provided on the bottom surface of the mat foundation 40 to secure a sufficient supporting force of the foundation.

In this case, when a road, a subway, and a railroad are installed around the building, vibrations are transmitted to the building. Such vibrations deteriorate the usability of the building. Therefore, a means for blocking such vibration is required. In particular, In buildings, such vibration prevention technology has a very important meaning.

Thus, the dustproof pad can be used as a means for blocking the vibration transmitted through the ground in the prior art.

Figure 1e illustrates the conventional anti-vibration pad, the anti-vibration pad 60 is mainly installed on the bottom plate to prevent the floor vibration of the building.

However, when the anti-vibration pad 60 is installed as the existing vibration or noise prevention technology, when the vibration source is close or the vibration is large, it is difficult to expect a sufficient vibration blocking effect.

Furthermore, a method of reducing vibration by installing vibration pads (rubber pads or springs) on the side of the foundation or on the bottom of the machine foundation may be applied. In particular, residential buildings in the vicinity of a section where constant vibration or noise exists, such as a railway site, etc. When constructing a concrete structure, such as a high level of vibration and noise reduction technology is required, the current state of the desired vibration or noise control is uncertain.

Korean Patent No. 10-544368 filed on Jan. 16, 2004, entitled "Precast transfer girder and method of constructing structure using same" (Filing date: Feb. 28, 2002), entitled "Hybrid truss system of load-bearing beams using steel rods" Korean Patent No. 10-585850 filed on June 1, 2004, entitled "Composite Structure Containing Cantilever Wall Structure Eliminating Transition Layer" Japanese Unexamined Patent Publication No. 2006-77414 (published on Mar. 23, 2006), entitled "Method and Apparatus for Vibration Control of Structures" U.S. Published Patent Application No. 2006-5477, published on Jan. 12, 2006, entitled " Earthquake resistance structure for building " US Patent No. 7540117 filed on August 4, 2003, entitled " Vibration isolation system for building "

Technical problem to be solved by the present invention for solving the above-mentioned problems, concrete structures such as multi-purpose building, mall, residential building (apartment, etc.), which is constructed in the vicinity of the section where vibration is always present, in particular, concrete structure It is to provide a concrete structure and a construction method for the vibration control using the concrete shear key is not affected by vibration or noise transmitted from the surrounding by enabling the vibration control in the base plate or transition layer of the.

As a means for achieving the above-mentioned technical object,

In the concrete structure for vibration control,

A base plate composed of a lower base plate constructed on the ground and an upper base plate constructed on the lower base plate; A concrete shear key formed of a concave-convex structure by pouring concrete, and restraining horizontal movement of the upper and lower base plates due to an earthquake or wind load; Dustproof consisting of a lower dustproof pad installed on the lower surface of the concrete shear key to absorb vibrations inside the upper and lower foundation plates and an upper dustproof pad installed on the upper surface of the concrete shear key to absorb vibrations inside the upper and lower foundation plates. pad; And a tension restraint member fixed to the upper and lower base plates and absorbing vertical displacement to constrain vertical loads.

Also preferably,

A concrete structure for vibration control, comprising: a transition layer installed on the concrete structure, the transition layer comprising a lower transition layer and an upper transition layer installed on the lower transition layer; A concrete shear key formed of a concave-convex structure by pouring concrete, and restraining horizontal movement of the upper and lower transition layers due to an earthquake or wind load; Dustproof consisting of a lower dustproof pad installed on a lower surface of the concrete shear key to absorb vibrations inside the upper and lower transition layers and an upper dustproof pad installed on an upper surface of the concrete shear key to absorb vibrations inside the upper and lower transition layers pad; And a tension restraint member fixed to the upper and lower transition layers and absorbing vertical displacement to constrain vertical loads.

Here, the concrete shear key is a concrete shear key formed of a concave-convex structure at the time of placing the concrete for the foundation plate or the transition layer construction, the lower concrete shear key and the upper concrete shear key, and the dustproof pad only on the upper and lower surfaces of the concrete shear key. It can be installed to block the vertical vibration generated from the ground vibration can restrain the horizontal displacement caused by the earthquake.

In this case, the concrete shear key, the lower dustproof pad, the upper dustproof pad, and the tension restraint material can be formed integrally during the construction of the base plate, so that the construction is made very simple.

According to the present invention, it is possible to construct a concrete structure such as a residential building even in the vicinity of a section in which vibration or noise is present, such as a railway site, thereby enabling economical use of the site.

1A is a view illustrating that a transition layer is formed as a structural form of a conventional multi-family multi-unit house,
Figure 1b is a diagram illustrating a transition layer formed of a transfer girder as a structural form of a conventional multi-stage multi-family house,
Figure 1c is a view illustrating that the transition layer is formed of a transfer plate as a structural form of a conventional multi-family multi-unit house,
1d is a diagram illustrating the mat and pile foundation of a conventional concrete structure,
Figure 1e is a diagram illustrating a dustproof pad is installed on the bottom plate to prevent the vibration between the floors of a conventional building,
Figure 2a is a view for explaining the concept of vibration control in the base plate of the concrete structure of the present invention.
Figure 2b is a view for explaining the concept of vibration control in the transition layer of the concrete structure of the present invention.
3 is a view illustrating that the concrete shear key is installed on the base plate of the concrete structure for vibration control according to the first embodiment of the present invention.
4 is a view illustrating that the concrete shear key and the tension restrictor are installed according to the first embodiment of the present invention.
5 is a view illustrating a cutaway perspective view of the concrete shear key according to the first embodiment of the present invention.
6 is a view illustrating that the concrete shear key is installed on the base plate of the concrete structure for vibration control according to the second embodiment of the present invention.
7 is a view illustrating that the concrete shear key and the tension restrictor are installed according to the second embodiment of the present invention.
8 is a view showing a perspective cutaway view of the concrete shear key according to the second embodiment of the present invention.
9a and 9b is a construction sequence diagram of the concrete shear key according to the embodiment 1 and 2 of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings, which will be readily apparent to those skilled in the art. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. In order to clearly illustrate the present invention, parts not related to the description are omitted, and similar parts are denoted by like reference characters throughout the specification.

Throughout the specification, when a part is said to "include" a certain component, it means that it can further include other components, without excluding other components unless specifically stated otherwise.

Example 1 Concrete Structure for Vibration Control with Integrated Vibration Control Device 100 in the Form of Concrete Shear Key 160 Installed on Base Plate 210 of Concrete Structure 200 and Construction Method thereof

[Concrete structure for vibration control with an integrated vibration control device 100 in the form of a concrete shear key 160 installed on the base plate 210 of the concrete structure 200]

Figure 2a is a diagram illustrating that the shear key of the uneven structure is installed on the base plate 210 of the concrete structure 200 for vibration control.

That is, for example, the front and back of the uneven structure that can block the vibration or noise that is installed in the base plate 210 of the concrete structure 200, such as a residential building in the neighborhood of the section where the constant vibration or noise, such as a railway site, etc. Concepts are disclosed.

Typically, the base plate 210 is a reinforced concrete structure formed to a certain thickness on the site where the concrete structure 200 is to be constructed.

On the upper surface of the base plate 210, a wall structure or a column structure constituting the concrete structure 200 is constructed. Accordingly, the load transmitted from the concrete structure 200 is transferred to the ground of the lower part through the base plate 210.

Since the base plate 210 is installed on the ground, if the vibration transmitted from the ground is not controlled, the foundation plate 210 has a great influence on the residential environment of the concrete structure 200 which is a residential building, especially because of the vibration transmitted to the concrete structure 200.

Accordingly, the present invention is based on the premise that the vibration is controlled by installing the anti-vibration pad 140 inside the base plate 210. However, the dustproof pad 140 may cause a problem in which the base plate 210 is dynamically separated or isolated.

In addition, this mechanical separation or quenching phenomenon does not cause a serious problem in the vertical load resistance such as the fixed load and live load of the base plate 210, but may cause a problem with the horizontal load such as seismic load and wind load.

Accordingly, the base plate 210 according to the first embodiment of the present invention is configured to have a shear key of the anti-vibration pad 140 and the concave-convex structure between the upper base plate 210a and the lower base plate 210b. By restraining the anti-vibration pad 140 between the base plate 210a and the lower base plate 210b with the tension binding member 150, the integrated vibration control device 100 in the form of a concrete shear key is provided as the shear key of the uneven structure. .

Specifically, the present invention will be described with reference to FIGS. 3 to 5.

3 is a view illustrating a cross-sectional shape of the base plate 210 of the concrete structure 200 for vibration control according to the first embodiment of the present invention, which illustrates that the concrete shear key 160 is installed, Figure 4 3 is a view illustrating the basic shape of the concrete shear key 160 and the tension binding member 150, Figure 5 is a cutaway perspective view of the concrete shear key 160 formed on the base plate 210 of the concrete structure 200 to be.

The integrated vibration control device 100 of the concrete shear key type for the vibration control according to the first embodiment of the present invention, the dustproof pad 140 is installed in the base plate 210 of the concrete structure 200, the tension binding material ( 150 and concrete shear key 160.

That is, the base plate 210 is composed of an upper base plate 210a and a lower base plate 210b as shown in FIG. It is formed to have a concrete shear key 160 of the concave-convex structure integrally formed between the 210a and the lower base plate (210b).

Specifically, the lower base plate 210b is first constructed with a half thickness of the rough base plate 210 on the ground, and the upper base plate 210a is engaged with the concrete shear key 160 to the lower base plate 210b. Is formed.

At this time, the lower dustproof pad 140b is disposed on the lower surface 161 of the concrete shear key 160 of the uneven structure to control the vibrations inside the upper base plate 210a and the lower base plate 210b as shown in FIGS. 3 and 4. The upper dustproof pad 140a is installed on the upper surface 162 of the concrete shear key 160 of the concave-convex structure to control the vibration of the upper base plate 210a and the lower base plate 210b.

The tensile constraint material 150 is fixed to the upper base plate 210a and the lower base plate 210b and absorbs the vertical displacement to restrain the vertical load. Specifically, the tension restrictor 150 may be re-arranged so as to absorb the vertical shrinkage of the upper and lower dustproof pads 140a and 140b in accordance with the increase in the vertical load at any one of the upper and lower fixing units. It is formed in the form, for example, the tension binding material 150 may be a bolted tension binding material.

In addition, the tensile constraint material 150 applies a STU (Shock Transmission Unit) system to strongly restrain a large displacement against an impact vibration at the time of an earthquake without restricting the displacement of the microvibration, so that noise or vibration Can be blocked.

That is, the horizontal movement due to the earthquake or wind load is constrained by the concrete shear key 160 of the concave-convex structure described later, but 1) the moment acting on the upper and lower base plates 210a and 210b, and 2) the earthquake or wind load. Due to the conduction moment, and 3) the direct motion of the earthquake, the tensile force in the vertical direction is generated as a vertical load on the upper and lower base plates 210a and 210b, which are partitioned by the dustproof pad 140. Accordingly, in order to effectively restrain the vertical load, a structural element for restraining a tensile force is required between the upper and lower foundation plates 210a and 210b.

Thus, the end of the tension binding member 150, as shown in Figure 4, is fixed between the upper and lower base plate (210a, 210b) structure, the tension binding member 150 is constructed in an unattached state It is then configured to absorb vertical displacements during construction and for vibration absorption.

Thus, in the integrated vibration control device 100 of the concrete shear key type for vibration control according to the first embodiment of the present invention, in order to correct the amount of shrinkage due to the compressive force, the tension binding member 150 is shown in FIG. As described above, it is formed in a form capable of re-calibration so as to absorb the vertical reduction amount of the dustproof pad 140 according to the increase of the vertical load in one of the upper and lower fixing units in stages. For example, the tensile constraint material 150 is formed by a bolt method or the like.

On the other hand, in Embodiment 1 of the present invention, the base plate 210 of the concrete structure consisting of the upper base plate (210a)-dustproof pad (140: 140a, 140b)-lower base plate (210b) described above tension member ( If it is firmly fixed using 150, there is a possibility that the vertical micro-vibration generated in the ground is transmitted to the upper concrete structure 200 through the tension restrictor 150. On the other hand, when the tensile constraint material 150 is loosely fixed, excessive vertical vibration can be absorbed, but structurally unstable.

Accordingly, in the integrated vibration control device 100 in the form of a concrete shear key for vibration control according to the first embodiment of the present invention, by applying a STU (Shock Transmission Unit) system to the tension restrictor 150, displacement in the microscopic vibration Although not restrained, by restraining large displacements strongly against impact vibrations such as earthquakes, it is possible to increase the safety due to abnormal vibrations during an earthquake while preventing noise or vibration caused by constant microscopic vibrations.

The concrete shear key 160 is formed in a concave-convex structure by placing concrete, restrains horizontal movement of the upper base plate 210a and the lower base plate 210b due to an earthquake or wind load, and for the resistance in the horizontal direction The sides are in contact with each other so that deformation does not occur. That is, the concrete shear key 160 of the concave-convex structure is provided with a dustproof pad 140 only in the plane of the upper base plate 210a and the lower base plate 210b for the vibration control of the base plate 210, at this time, horizontal Side of the concrete shear key 160 is in contact with the deformation so as not to occur in the direction of the resistance.

Accordingly, the concrete shear key 160 is the simplest type and can be configured with the concrete shear key 160 as shown in FIG. 5. The concrete shear key 160 is constructed so as to protrude a predetermined section to the upper portion during the concrete foundation of the lower base plate (210b), and also install the upper and lower dustproof pads (140a, 140b) after curing the concrete, and then, the upper foundation It can proceed by pouring the concrete of the plate (210a).

The concrete shear key 160 of the concave-convex structure is provided with the upper dustproof pad 140a and the lower dustproof pad 140b only on the upper surface 162 and the lower surface 161 to block vertical vibration generated from ground vibration. Therefore, the vertical movement is free and the horizontal movement due to the earthquake is constrained.

At this time, the upper and lower concave-convex concrete shear key 160 should restrain the horizontal displacement while allowing vertical displacement, so that the side of the concrete shear key 160 has a required performance in such a way that the steel or Teflon coated material is further attached. Construct to be satisfied. Furthermore, the one-way roll bearing (Roll-Bearing) free to vertical movement can be installed on the side of the concrete shear key 160 of the uneven structure.

As a result, according to the first embodiment of the present invention

The upper and lower base plates (210a, 210b) can be seen that the vibration is controlled by the concrete shear key 160, the lower dustproof pad 140b, the upper dustproof pad 140a and the tension restrictor 150. In this case, the concrete shear key 160, the lower dustproof pad (140b), the upper dustproof pad (140a) and the tension restrictor 150 can be formed integrally during the construction of the base plate 210, so the construction is very simple. Able to know.

 [Concrete structure construction method for vibration control with integrated vibration control device 100 in the form of concrete shear key 160 installed on the base plate 210 of the concrete structure 200]

Concrete structure construction method for the vibration control according to the first embodiment

First, as shown in FIG. 3, the foundation plate 210 is first constructed by digging the ground to be constructed.

The base plate 210 is constructed as a reinforced concrete structure as shown in Figure 9a and first to form a lower base plate 210b to a predetermined thickness so that the concrete shear key 160 can be formed. For example, the concrete shear key 160 may be formed by forming a plurality of shear grooves at regular intervals on the top surface and naturally forming a shear block between the shear grooves.

Thus, it can be seen that a plurality of lower surface 161 and upper surface 162 are formed in the lower base plate 210b.

Next, the lower dustproof pad 140b is installed on the upper surface of the front end block of the lower base plate 210b, and the upper dustproof pad 140a is also installed on the lower surface of the shear groove.

Next, the concrete for the construction of the upper base plate 210a is placed on the upper and lower anti-vibration pads 140a and 140b to form an integrated type in the form of a concrete shear key 160 on the base plate 210 of the final concrete structure 200. The vibration control device 100 is installed.

Next, as shown in FIG. 3, the tension restrictor 150 is installed between the upper and lower base plates 210a and 210b.

The upper and lower ends of the tension restraining material 150 are fixed to penetrate the upper base plate 210a and the lower base plate 210b and absorb the vertical displacement to restrain the vertical load. Bolt fastening type tensile constraint material may be used.

Accordingly, when the construction of the base plate 210 is completed, the concrete structure 200 is constructed on the top surface of the base plate.

Thus, as described above, the concrete type shear key 160 of the present invention is the simplest type and is constructed so as to protrude a certain section to the upper part during the concrete pouring of the lower base plate 210b, and also, the upper and lower dustproof pads after concrete hardening. After installing (140a, 140b), it can be seen that it can proceed in a way to pour the concrete of the upper base plate (210a).

[Embodiment 2: Concrete Structure for Vibration Control with Integrated Vibration Control Device 100 of Concrete Shear Key Type to be Installed in Transition Layer 220 of Concrete Structure]

[Concrete Structures for Vibration Control with an Integrated Vibration Control Device 100 of Concrete Shear Key Type to be Installed in the Transition Layer 220 of the Concrete Structure]

2b is a diagram illustrating that a shear key of an uneven structure is installed in the transition layer 220 of the concrete structure 200 for vibration control.

That is, the concept of a shear key of a concavo-convex structure capable of blocking vibration or noise in a section of the transition layer 220a or 220b where the lower ramen structure 230 and the upper shear wall structure 240, have.

That is, the concept of the shear key of the uneven structure that can block the vibration or noise in the transition layer 220 of the concrete structure 200, such as the columnar composite building, in the vicinity of the section where the constant vibration or noise, such as the railway site, etc. Is disclosed.

In the case of an apartment complex or an underground parking lot, the lower part of the lower part is formed as a column-shaped ramen-shaped office, a shop, a convenience store or a parking lot, and the upper part of the building is formed as an apartment In order to transfer the load of the upper part stably to the lower part because the main part of the column and the lower part of the column are not matched, a transition layer is formed at the upper floor of the lower part where the apartment starts.

Typically the transition layers 220a and 220b are used to transmit the stress of the upper shear wall structure 240 to the lower ramen structure 230 for the purpose of preventing uneven stress caused by the non- The upper shear wall structure 240 and the lower ramen structure 230 should be integrated through the transition layers 220a and 220b.

However, since it is assumed that the dustproof pad 140 for vibration absorption is installed inside the transition layers 220a and 220b, the upper shear wall structure 240 and the lower ramen structure 230 are caused by the dustproof pad 140. This may cause problems of mechanical separation or isolation.

In addition, the mechanical separation or quenching phenomenon does not cause a serious problem in the vertical load resistance such as the fixed load and the live load. However, the horizontal load such as the seismic load and the wind load may cause a problem.

Accordingly, the transition layer 220 according to the embodiment of the present invention, the dustproof pad 140 is provided between the lower transition layer 220a and the upper transition layer 220b, and is configured to have an uneven shear key. By installing the dustproof pad 140 between the lower transition layer 220a and the upper transition layer 220b to restrain the tension restraint 150, the integrated vibration control device 100 in the form of a concrete shear key is used as a shear key of an uneven structure. ).

After all, the present invention is the integrated vibration control device 100 of the concrete shear key type is installed on the concrete structure 200 is the base plate 210, Example 1 and the transition layer 220, Example 2 of the concrete structure 200 It can be seen that each or both may be formed on.

6, 7, and 8 with reference to the integrated vibration control device 100 in the form of a concrete shear key installed on the transition layer 220.

6 is a view illustrating a cross-sectional shape of the transition layer 220 of the concrete structure 200 for vibration control according to the second embodiment of the present invention, which illustrates that the concrete shear key 160 is installed, and FIG. 6 is a view illustrating a basic shape of the concrete shear key 160 and the tension binding member 150, Figure 8 is a cutaway perspective view of the concrete shear key 160 formed on the transition layer 220 of the concrete structure 200 to be.

The integrated vibration control device 100 of the concrete shear key type for the vibration control according to the second embodiment of the present invention, the dustproof pad 140 is installed in the transition layer 220 of the concrete structure 200, the tension binding material ( 150) and the concrete shear key 160 is not different from the first embodiment.

That is, as shown in FIG. 6, the transition layer 220 is formed of an upper transition layer 220a and a lower transition layer 220b, and an upper transition layer centering around portions where upper and lower dustproof pads 140a and 140b are installed. The 220a and the lower transition layer 220b may be configured to have the concrete shear key 160 having an uneven structure.

Also, the lower transition layer 220b is first constructed with a half thickness of the entire transition layer 220, and the upper transition layer 220a is formed in such a manner as to be engaged with the lower shear layer 220b by the concrete shear key 160. .

At this time, the lower dustproof pad 140b is disposed on the lower surface 161 of the concrete shear key 160 of the uneven structure to control the vibrations inside the upper transition layer 220a and the lower transition layer 220b as shown in FIGS. 6 and 7. The upper dustproof pad 140a is installed on the upper surface 162 of the concrete shear key 160 of the concave-convex structure to control vibrations in the upper transition layer 220a and the lower transition layer 220b.

The tensile constraint material 150 is also fixed to the upper transition layer 220a and the lower transition layer 220b and absorbs the vertical displacement to restrain the vertical load. Specifically, the tension restrictor 150 may be re-arranged so as to absorb the vertical shrinkage of the upper and lower dustproof pads 140a and 140b in accordance with the increase in the vertical load at any one of the upper and lower fixing units. It is formed in the form, for example, the tension binding material 150 may be a bolted tension binding material.

Also, the tensile constraint material 150 does not constrain the displacement in the microvibration by applying the STU (Shock Transmission Unit) system, but strongly restrains a large displacement against the shock vibration at the time of an earthquake so that noise or vibration Can be blocked.

That is, the horizontal movement due to the earthquake or wind load is constrained by the concrete shear key 160 of the concave-convex structure to be described later, but 1) the moment acting on the upper and lower transition layers 220a and 220b, and 2) the earthquake or wind load. Due to the conduction moment, and 3) the direct motion of the earthquake, the tensile force in the vertical direction is generated as the vertical load on the upper and lower transition layers 220a and 220b structured by the dustproof pad 140. Accordingly, in order to effectively restrain the vertical load, a structural element for restraining a tensile force is required between the upper and lower transition layers 220a and 220b.

Thus, the end of the tension binding member 150, as shown in Figure 6, is fixed between the upper and lower transition layer (220a, 220b) structure, the tension binding member 150 is constructed in an unattached state Afterwards, the construction is configured to absorb vertical displacement for vibration absorption.

Thus, in the integrated vibration control device 100 of the concrete shear key type for vibration control according to the second embodiment of the present invention, in order to correct the amount of shrinkage due to the compressive force, the tension restrictor 150 is shown in FIG. As described above, it is formed in a form capable of re-calibration so as to absorb the vertical reduction amount of the dustproof pad 140 according to the increase of the vertical load in one of the upper and lower fixing units in stages. For example, the tensile constraint material 150 may be formed by a bolt method or the like.

On the other hand, in the second embodiment of the present invention, the transition layer 220 of the concrete structure consisting of the upper transition layer (220a)-dustproof pads (140: 140a, 140b)-lower transition layer (220b) described above tension member ( If it is firmly fixed using 150, there is a possibility that the vertical micro-vibration generated in the ground is transmitted to the upper concrete structure 200 through the tension restrictor 150. On the other hand, when loosely fixing the tensile constraint material 150, there is an effect of absorbing the vertical microscopic vibration, but it is structurally unstable.

Accordingly, in the integrated vibration control apparatus 100 of the concrete shear key type for vibration control according to an embodiment of the present invention, by applying a STU (Shock Transmission Unit) system to the tension restrictor 150, the displacement is restrained in the microscopic vibration However, by restraining large displacement strongly against shock vibrations such as earthquakes, it is possible to increase the safety by abnormal vibrations during earthquakes while preventing noise or vibrations due to constant micro-vibration.

The concrete shear key 160 is also formed of a concave-convex structure by placing concrete, restrains horizontal movement of the upper transition layer 220a and the lower transition layer 220b due to an earthquake or wind load, and for the resistance in the horizontal direction The sides are in contact with each other so that deformation does not occur. That is, the concrete shear key 160 of the concave-convex structure has a dustproof pad 140 is installed only on the plane (161,162) of the upper transition layer 220a and the lower transition layer 220b for the vibration control of the transition layer 220, At this time, the side of the concrete shear key 160 is in contact with the deformation so as not to occur in the horizontal direction.

Accordingly, the concrete shear key 160 is the simplest type and may be configured as the concrete shear key 160 as shown in FIG. 8. The concrete shear key 160 is constructed so as to protrude a predetermined section to the upper part during the concrete casting of the lower transition layer (220b), and also install the upper and lower dustproof pads (140a, 140b) after the concrete hardening, and then, the upper transition The same can be done by pouring concrete of layer 220a.

The concrete shear key 160 of the concave-convex structure also has the upper dustproof pad 140a and the lower dustproof pad 140b only on the upper and lower surfaces 162 and 161, respectively, in order to block the vertical vibration generated from the ground vibration. By installing, vertical movement is free and horizontal movement due to earthquake is constrained.

At this time, the upper and lower concave-convex concrete shear key 160 should restrain the horizontal displacement while allowing vertical displacement, so that the side of the concrete shear key 160 to meet the required performance by using steel or Teflon coated material as well. Construct. Furthermore, the one-way roll bearing (Roll-Bearing) free to vertical movement can be installed on the side of the concrete shear key 160 of the uneven structure.

As a result, according to the second embodiment of the present invention

The upper and lower transition layers (220a, 220b) can be seen that the vibration is controlled by the concrete shear key 160, the lower dustproof pad (140b), the upper dustproof pad (140a) and the tension restrictor (150). In this case, the concrete shear key 160, the lower dustproof pad (140b), the upper dustproof pad (140a) and the tension binding material 150 can be formed integrally during the construction of the transition layer 220, the construction is very simple. Able to know.

[Concrete structure construction method for vibration control with integrated vibration control device 100 in the form of concrete shear key installed on the transition layer 220 of the concrete structure]

Concrete structure construction method for the vibration control according to the second embodiment

First, the concrete structure 200 is to excavate the ground to be constructed first to build the base plate. The base plate is formed by the method according to the first embodiment, but it is not necessary to provide the vibration proof pad. This is because in the second embodiment, the vibration insulating pad is provided on the transition layer.

Accordingly, as shown in FIG. 6, the lower ramen structure 230 of the concrete structure 200 is first constructed on the base plate, and the lower ramen structure 230 may be constructed as a beam-pillar structure.

Next, a lower transition layer 220b is formed on the lower ramen structure 230.

The lower transition layer 220b is constructed of a reinforced concrete structure and first forms the lower transition layer 220b to a predetermined thickness so that the concrete shear key 160 can be formed. For example, the concrete shear key 160 may be formed by forming a plurality of shear grooves at regular intervals on the top surface and naturally forming a shear block between the shear grooves.

As shown in FIG. 9B, a plurality of lower surfaces 161 and upper surfaces 162 may be formed on the lower transition layer 220b.

Next, the lower dustproof pad 140b is installed on the upper surface of the front block of the lower transition layer 220b, and the upper dustproof pad 140a is also installed on the lower surface of the shear groove.

Next, the concrete for the construction of the upper transition layer 220a is placed on the upper and lower dustproof pads 140a and 140b to form an integral type of concrete shear key 160 on the transition layer 220 of the final concrete structure 200. The vibration control device 100 is installed.

Next, a tension restrictor 150 is installed between the upper transition layer 220b and the lower transition layer 220b.

The tensile constraint material 150 is fixed at the upper and lower ends so as to pass through the upper transition layer 220b and the lower transition layer 220b, and absorbs the vertical displacement to restrain the vertical load. Bolt fastening type tensile constraint material may be used.

When the construction of the transition layer 220 is completed, the upper shear wall structure 240 is constructed on the upper surface of the transition layer 220 to complete the concrete structure 200.

As such, as described above, the concrete shear key 160 of the present invention is the simplest type, and is constructed so that a certain section protrudes upward when concrete is laid in the lower transition layer 220b, and further, upper and lower dustproof pads after concrete hardening. After installing (140a, 140b), it can be seen that it can proceed by pouring the concrete of the upper transition layer (220a).

The foregoing description of the present invention is intended for illustration, and it will be understood by those skilled in the art that the present invention may be easily modified in other specific forms without changing the technical spirit or essential features of the present invention. will be. It is therefore to be understood that the above-described embodiments are illustrative in all aspects and not restrictive. For example, each component described as a single entity may be distributed and implemented, and components described as being distributed may also be implemented in a combined form.

The scope of the present invention is defined by the appended claims rather than the detailed description and all changes or modifications derived from the meaning and scope of the claims and their equivalents are to be construed as being included within the scope of the present invention do.

100: integrated vibration control device
140: dustproof pad
140a: lower dustproof pad
140b: top dustproof pad
150: tensile constraint material
160: concrete shear key
200: Concrete structure
210: base plate
210a: upper base plate
210b:
220: transition layer
220a: upper transition layer
220b: lower transition layer
230: Lower ramen structure
240: upper shear wall structure

Claims (12)

In the concrete structure for vibration control,
A base plate 210 formed of a lower base plate 210b to be installed on the ground and an upper base plate 210a to be installed on the lower base plate 210b;
A concrete shear key 160 formed of a concave-convex structure by pouring concrete and restraining horizontal movement of the upper and lower base plates 210a and 210b due to an earthquake or wind load;
Inside the lower dustproof pad 140b and the upper and lower foundation plates 210a and 210b installed on the lower surface 161 of the concrete shear key 160 to absorb vibrations in the upper and lower foundation plates 210a and 210b. An anti-vibration pad 140 comprising an upper anti-vibration pad 140a installed on the upper surface 162 of the concrete shear key 160 to absorb vibration of the anti-vibration pad 140; And
And a tensile restraining material (150) fixed to the upper and lower base plates (210a, 210b) and absorbing a vertical displacement to restrain a vertical load,
The concrete shear key 160, the lower dustproof pad 140b, the upper dustproof pad 140a, and the tension restrictor 150 are integrally formed to block the vibration generated in the upper and lower foundation plates 210a and 210b. Concrete structure for vibration control using a concrete shear key, characterized in that. In the concrete structure for vibration control,
A transition layer 220 installed on the concrete structure and including a lower transition layer 220b and an upper transition layer 220a installed on the lower transition layer 220b;
A concrete shear key 160 formed of a concave-convex structure by pouring concrete and restraining horizontal movement of the upper and lower transition layers 220a and 220b due to an earthquake or wind load;
Inside the lower dustproof pad 140b and the upper and lower transition layers 220a and 220b installed on the lower surface 161 of the concrete shear key 160 to absorb vibrations in the upper and lower transition layers 220a and 220b. An anti-vibration pad 140 comprising an upper anti-vibration pad 140a installed on the upper surface 162 of the concrete shear key 160 to absorb vibration of the anti-vibration pad 140; And
And a tensile restraining material (150) fixed to the upper and lower transition layers (220a, 220b) and absorbing the vertical displacement to restrain the vertical load,
The concrete shear key 160, the lower dustproof pad 140b, the upper dustproof pad 140a, and the tension restrictor 150 are integrally formed to block the vibration generated in the upper and lower transition layers 220a and 220b. Concrete structure for vibration control using a concrete shear key, characterized in that. delete 3. The method according to claim 1 or 2,
The concrete shear key 160 is constructed so as to protrude a predetermined section to the upper part when placing the lower base plate (210b) or the lower transition layer (220b), the lower base plate (210b) or lower transition layer (220b) of After curing the concrete, the upper and lower anti-vibration pads (140a, 140b) is installed, and the concrete shear key, characterized in that formed by the concave-convex structure by pouring the upper base plate (210a) or upper transition layer (220a) concrete Concrete structure for vibration control using 5. The method of claim 4,
The concrete shear key 160 of the concave-convex structure is provided with the upper dustproof pad 140a and the lower dustproof pad 140b on only the upper surface 162 and the lower surface 161 to block vertical vibration generated from ground vibration. The concrete structure for the vibration control using the concrete shear key, characterized in that the vertical movement is free, but the horizontal movement due to the earthquake is constrained. 3. The method according to claim 1 or 2,
The concrete shear key 160 is a concrete structure for the vibration control using the concrete shear key, characterized in that the side to contact so that the deformation does not occur for the horizontal direction resistance. The method according to claim 6,
Concrete structure for vibration control using a concrete shear key, characterized in that to apply the Teflon material free to vertical movement on the side of the concrete shear key 160 or install a one-way roll bearing (Roll-Bearing). 3. The method according to claim 1 or 2,
The tension binding member 150 is in a form that can be re-arranged to absorb the vertical shrinkage of the upper and lower dustproof pads (140a, 140b) in accordance with the increase in the vertical load at any one of the upper and lower fixing unit Concrete structure for vibration control using a concrete shear key, characterized in that formed. 9. The method of claim 8,
The tension binding member 150 is a concrete structure for vibration control using a concrete shear key, characterized in that the bolt fastening type tension binding material. 8. The method of claim 7,
The tension restrictor 150 applies a STU (Shock Transmission Unit) system, but does not restrain displacement in the microscopic vibration, but strongly restrains the large displacement against the shock vibration during an earthquake, thereby preventing noise or vibration caused by the constant microscopic vibration. Concrete structure for vibration control using a concrete shear key, characterized in that. Digging the ground on which the concrete structure 200 is to be constructed;
The concrete is formed to have a predetermined thickness on the trench ground, and a plurality of shear grooves are formed on the upper surface at regular intervals, and a shear block is formed between the shear grooves to form a lower base plate 210b having the concrete shear key 160 formed thereon. The lower dustproof pad 140b is installed on the upper surface of the front block of the lower base plate 210b, the upper dustproof pad 140a is also installed on the lower surface of the shear groove, and the upper and lower dustproof pads 140a and 140b. Constructing the foundation plate 210 by pouring concrete for construction of the upper foundation plate 210a at the top; And
It includes; constructing a concrete structure 200 on the upper surface of the base plate 210;
The concrete shear key 160, the lower dustproof pad 140b, the upper dustproof pad 140a, and the tension restrictor 150 are integrally formed to block the vibration generated in the upper and lower foundation plates 210a and 210b. Concrete structure construction method for vibration control using a concrete shear key, characterized in that. Constructing the foundation plate by digging the ground to be constructed by the concrete structure 200 and constructing the lower ramen structure 230 of the concrete structure 200 on the foundation plate;
A lower transition layer 220b in which concrete shear keys 160 are formed by forming concrete in a predetermined thickness on the lower ramen structure 230, but forming a plurality of shear grooves at regular intervals on the upper surface, and a shear block formed between the shear grooves. ), A lower dustproof pad 140b is installed on an upper surface of the front end block of the lower transition layer 220b, an upper dustproof pad 140a is also installed on a lower surface of the shear groove, and the upper and lower dustproof pads 140a. (140b) constructing the transition layer 220 by pouring concrete for the construction of the upper transition layer 220a thereon; And
And constructing the concrete structure 200 by constructing the upper shear wall structure 240 on the upper surface of the transition layer 220.
The concrete shear key 160, the lower dustproof pad 140b, the upper dustproof pad 140a, and the tension restrictor 150 are integrally formed to block the vibration generated in the upper and lower transition layers 220a and 220b. Concrete structure construction method for vibration control using a concrete shear key, characterized in that.

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