KR102331331B1 - Seismic controling system of constructure and construction method thereof - Google Patents

Abstract

Various embodiments relate to a vibration damping system for a building, wherein the vibration damping system for a building includes a plurality of first rigid members spaced apart from each other and disposed in parallel with a plurality of second rigid members disposed perpendicular to the plurality of first rigid members. A vibration damping system for a building in which a viscous damping device is provided on a line connecting a junction where rigid members intersect, comprising: a first reinforcing plate fixedly arranged in parallel with the plurality of first rigid members on one side of the junction; a second reinforcing plate that is fixedly arranged in parallel with the plurality of second rigid members and is perpendicular to the first reinforcing plate; a gusset plate including a vertical portion joined to the front surface of the first reinforcing plate, a horizontal portion joined to the front surface of the second reinforcing plate, and a connecting portion protruding in a direction in which the line extends; One end is connected to the connecting portion, the other end is a brace connected to the end of the viscous damping device by friction bonding; may include. Various other embodiments are possible.

Description

A building's vibration damping system and its construction method

Various embodiments to be described below relate to a vibration damping system for a building for fixing a high-capacity viscous damping device for damping shaking or vibration generated by an earthquake or wind, etc. to the frame of the building, and a construction method thereof.

Recently, due to a series of large earthquakes occurring at home and abroad, awareness of earthquake damage and the necessity of seismic design is spreading, and interest in earthquake-resistant reinforcement methods for buildings is gradually increasing.

In general, seismic design refers to designing a building strong enough to resist vibration energy caused by an earthquake. way. Through the 1994 Northridge earthquake in the United States and the 1995 Kobe earthquake in the United States, even if a building was designed according to the seismic design standards, structural damage caused by the earthquake could not be avoided and the safety of the face could be threatened. Interest in vibration suppression technology that can be safely preserved is growing. A typical damping device is a damper. Conventional damping device technology in Korea uses a single damping device such as a viscous damper, a viscoelastic damper, a friction damper, and a metallic yield damper to provide a damping effect. is looking at

The existing viscous damping device used in buildings has a small load (damping force against vibration) and a high-capacity viscous damping device was not considered in the design stage of the building structure. Due to the increased risk of earthquakes due to the two earthquakes in Gyeongju and Pohang in 2016 and 2017, the application of high-capacity damping devices to large structures such as high-rise buildings is being actively considered.

However, the design in which the existing damping device is connected to the structural frame of the building focuses only on the drawing of the connection structure to the damping device, so proper reinforcement for the shear force applied by the damping device to the connecting structure is not accompanied, so the reinforcement effect of the damping device There is a problem in that it falls or rather puts a burden on the frame.

7 is a graph showing the displacement and load of the damping device when the conventional damping device is connected to the frame of the building by a hinge.

Referring to FIG. 7, in the conventional damping device, a hinge connection is applied to the end to correspond to the size of each different frame, so a slip phenomenon inevitably occurs in the hinge connection structure in which the hole is larger than the diameter of the rod. This slip phenomenon appears as a gap in the damping history. The gap means a difference in which the displacement value is shifted at the turning point at the maximum displacement of the damping history shown in FIG. 7 . In a low-capacity damping device, the degradation of energy dissipation ability due to the gap is not large, but there is a problem in that the degree of the gap increases as the capacity of the damping device increases. Considering the gap, the numerical model of the damping device becomes complicated, and there is a problem in that it is difficult to predict its behavior.

Various embodiments disclosed in this document can provide a vibration damping system for a building capable of dissipating vibration energy caused by earthquakes or winds by firmly bonding a high-capacity damping device to a building in the design stage of the building, and a construction method thereof.

The technical problems to be achieved in this document are not limited to the technical problems mentioned above, and other technical problems not mentioned can be clearly understood by those of ordinary skill in the art to which the present invention belongs from the description below. There will be.

In the building vibration damping system according to various embodiments of the present disclosure, for example, a plurality of first rigid members disposed parallel to each other and a plurality of second rigid members disposed perpendicular to the plurality of first rigid members intersect each other. A vibration damping system for a building provided with a viscous damping device on a line connecting a joint, comprising: a first reinforcing plate fixedly arranged in parallel with the plurality of first rigid members on one side of the joint; a second reinforcing plate that is fixedly arranged in parallel with the plurality of second rigid members and is perpendicular to the first reinforcing plate; a gusset plate including a vertical portion joined to the front surface of the first reinforcing plate, a horizontal portion joined to the front surface of the second reinforcing plate, and a connecting portion protruding in a direction in which the line extends; One end is connected to the connecting portion, the other end is a brace connected to the end of the viscous damping device by friction bonding; may include.

In various embodiments, the inner surface of the other end of the brace and the upper and lower surfaces of the end of the viscous damping device may be frictionally joined at two surfaces by a plurality of friction bolts.

In various embodiments, a plurality of through-holes to which the plurality of friction bolts are fastened may be respectively provided at the other end of the brace and the end of the viscous damping device.

In various embodiments, the plurality of through-holes may have a long hole shape in the longitudinal direction of the brace or in the longitudinal direction of the viscous damping device.

In various embodiments, the first reinforcing plate includes a plurality of third rigid members fixed to the rear surface and fitted between the plurality of first rigid members, and the second reinforcing plate is fixed to the rear surface and the plurality of third rigid members are fixed to the rear surface. It may include a plurality of fourth rigid members sandwiched between the two rigid members.

In various embodiments, the plurality of third rigid members and the plurality of fourth rigid members may be 'L' shaped.

In various embodiments, when the plurality of third rigid members are sandwiched between the plurality of first rigid members and the plurality of fourth rigid members are sandwiched between the plurality of second rigid members, the plurality of third rigid members At least some of the members and at least some of the plurality of fourth rigid members may cross each other.

In various embodiments, the vertical portion of the gusset plate may be joined to the front surface of the first reinforcing plate by welding, and the horizontal portion of the gusset plate may be joined to the front surface of the second reinforcing plate by welding.

In one embodiment, the connecting portion of the gusset plate and one end of the brace may be connected by fastening a bolt and a nut, or the gusset plate and the brace may be integrally formed.

In various embodiments, the viscous damping device may dissipate the impact applied to the building using silicon viscosity.

In the method for constructing a building vibration damping system according to various embodiments of the present disclosure, for example, a plurality of first rigid members disposed parallel to each other and a plurality of second rigid members disposed perpendicular to the plurality of first rigid members may be provided. A method of constructing a vibration damping system for a building provided with a viscous damping device on a line connecting the junctions intersecting with each other, the method comprising: fixing and arranging a first reinforcing plate in parallel with the plurality of first rigid members on one side of the junction; fixing and disposing a second reinforcing plate parallel to the plurality of second rigid members on one side of the joint; bonding a gusset plate to the front surface of the first reinforcing plate and the front surface of the second reinforcing plate; and connecting the gusset plate and the viscous damping device through a brace.

In various embodiments, the process of connecting the gusset plate and the viscous damping device through a brace, the process of connecting one end of the brace and the gusset plate, and the other end of the brace and the end of the viscous damping device It may include a process of connecting by friction bonding.

In various embodiments, the process of connecting the other end of the brace and the end of the viscous damping device by friction bonding, the inner surface of the other end of the brace and the upper and lower surfaces of the end of the viscous damping device are a plurality of friction bolts It may include a process of friction bonding on the two surfaces by

In various embodiments, the process of friction-joining the inner surface of the other end of the brace and the upper and lower surfaces of the end of the viscous damping device on two surfaces by a plurality of friction bolts, provided at the other end of the brace and the length of the brace A through hole having a long hole shape in the direction and a through hole provided at an end of the viscous damping device and having a long hole shape in the longitudinal direction of the viscous damping device includes a process of adjusting a position at which the plurality of friction bolts are fastened can do.

In various embodiments, the process of fixing and disposing a first reinforcing plate parallel to the first rigid member on one side of the junction includes a plurality of third rigid members provided on the rear surface of the first reinforcing plate. 1 may include a process of sandwiching between the rigid members.

In various embodiments, the process of fixing and arranging a second reinforcing plate parallel to the second rigid member on one side of the junction includes a plurality of fourth rigid members provided on the rear surface of the second reinforcing plate to the plurality of second reinforcing plates. It may include a process of sandwiching the two rigid members.

In various embodiments, the process of installing a formwork on the outside of the plurality of first rigid members and the plurality of second rigid members; and pouring concrete into the formwork.

In various embodiments, the process of joining the gusset plate to the front surface of the first reinforcing plate and the front surface of the second reinforcing plate includes welding a vertical portion of the gusset plate to the front surface of the first reinforcing plate, and and welding the horizontal portion of the gusset plate to the front surface of the second reinforcing plate.

In one embodiment, the process of connecting one end of the brace and the gusset plate may include a process of connecting one end of the brace and the gusset plate by fastening a bolt and a nut.

In various embodiments, the viscous damping device may dissipate the impact applied to the building using silicon viscosity.

The vibration damping system for a building and its construction method according to various embodiments can exhibit an excellent vibration damping effect by bonding a high-capacity damping device to the frame of the building, thereby transferring the energy dissipation ability of the damping device to the building can be applied.

In the vibration damping system for a building and its construction method according to various embodiments, the tolerance and frame standards of steel or concrete members that may occur during construction by leaving a predetermined margin in the longitudinal direction of the damping device at the connection part of the damping device and the building error can be dealt with.

Effects obtainable in the present disclosure are not limited to the above-mentioned effects, and other effects not mentioned may be clearly understood by those of ordinary skill in the art to which the present disclosure belongs from the description below. will be.

1A is a perspective front view of a vibration damping system for a building according to various embodiments of the present disclosure;
1B is a perspective front view of a vibration damping system of a building in a state in which a viscous damping device is mounted according to various embodiments of the present disclosure;
Figure 2a is an enlarged perspective view of the part where the viscous damping device and the brace are connected.
Figure 2b is an enlarged front view of the part where the viscous damping device and the brace are connected.
3 is a view showing a configuration mounted on a junction of a building among the vibration damping system of a building according to various embodiments of the present disclosure;
4 is a view showing a reinforcing plate according to various embodiments.
5 is a flowchart of a method of constructing a vibration damping system for a building according to various embodiments of the present disclosure;
6 is a view illustrating a method of constructing a vibration damping system for a building according to various embodiments of the present disclosure;
7 is a graph showing the displacement and load of the damping device when the conventional damping device is connected to the frame of the building by a hinge.

Hereinafter, various embodiments of the present document will be described with reference to the accompanying drawings.

The various embodiments of this document and the terms used therein are not intended to limit the technical features described in this document to specific embodiments, and should be understood to include various modifications, equivalents, or substitutions of the embodiments. In connection with the description of the drawings, like reference numerals may be used for similar or related components. The singular form of the noun corresponding to the item may include one or more of the item, unless the relevant context clearly dictates otherwise. As used herein, "A or B", "at least one of A and B", "at least one of A or B," "A, B or C," "at least one of A, B and C," and "A , B, or C" each may include any one of the items listed together in the corresponding one of the phrases, or all possible combinations thereof. Terms such as “first”, “second”, or “first” or “second” may simply be used to distinguish the component from other such components, and refer to those components in other aspects (e.g., importance or order) is not limited.

1A is a perspective front view of a vibration damping system for a building according to various embodiments, and FIG. 1B is a perspective front view of a damping device of a vibration damping system for a building according to various embodiments of the present disclosure. 3 is a view showing a configuration mounted on a junction of a building among the vibration damping system of a building according to various embodiments of the present disclosure;

1A, 1B, and 3 , the vibration damping system 100 of a building according to various embodiments is a viscous damping device of high capacity (eg, 100 tons) at a junction where rigid members forming the frame of the building intersect vertically. It is possible to absorb or dissipate vibration energy caused by earthquakes or winds by fixing them. The vibration damping system 100 of a building according to various embodiments includes a plurality of first rigid members 1 that are spaced apart from each other and disposed in parallel, and a plurality of first rigid members 1 disposed perpendicular to the plurality of first rigid members 1 . The viscous damping device 150 may be provided on a line connecting the junction part 3 where the two rigid members 2 intersect. For example, the first rigid member 1 may be a column reinforcing bar constituting a frame of a building, and the second rigid member 2 may be a prosthetic reinforcing bar. The viscous damping device 150 is a device for damping vibration by an impact load of 50 to 100 tons (t), and silicon may be used as a viscous fluid.

The vibration damping system 100 of a building according to various embodiments is a reinforcing plate 110 , 120 , a gusset plate 130 and a brace 140 in order to fix the viscous damping device 150 to the junction 3 of the frame of the building. may include. The reinforcing plate includes a first reinforcing plate 110 and a second reinforcing plate 120 , the first reinforcing plate 110 is fixedly arranged in parallel with the first rigid member 1 , and the second reinforcing plate 120 . ) may be fixedly arranged in parallel with the second rigid member 2 to form a right angle to each other at one side of the first reinforcing plate 110 and the joint 3 . One end of the gusset plate 130 is disposed at an angle formed by the first reinforcing plate 110 and the second reinforcing plate 120, and the other end is a line connecting the junction 3 where the first and second rigid members intersect. It may be formed to extend or protrude upward. The gusset plate 130 may include a vertical portion and a horizontal portion provided at one end, and a connection portion provided at the other end. In this case, the vertical portion may be bonded to the front surface of the first reinforcing plate 110 , and the horizontal portion may be bonded to the front surface of the second reinforcing plate 120 . For example, the vertical portion may be joined to the front surface of the first reinforcing plate 110 by welding, and the horizontal portion may also be joined to the front surface of the second reinforcing plate 120 by welding.

In various embodiments, the brace 140 is disposed on a line connecting the junction 3, one end 141 is connected to the gusset plate, the other end 142 is to be connected to the end of the viscous damping device 150 can The one end 141 may be made of H-shaped steel, and may be connected to the connection portion of the gusset plate 130 by fastening bolts and nuts. In one embodiment, the brace 140 may be formed integrally with the connection portion of the gusset plate 130 .

Figure 2a is an enlarged perspective view of the part where the viscous damping device and the brace are connected, and Figure 2b is an enlarged front view of the part where the viscous damping device and the brace are connected.

2A and 2B, in various embodiments, the viscous damping device 150 is connected to the brace 140 at both ends to be supported by the brace 140 and to be disposed on a diagonal line connecting the junction 3 can In order for the viscous damping device and the brace to be connected to each other, the end of the viscous damping device 150 and the other end 142 of the brace may each have a plurality of through-holes 143 . In the embodiment shown in Figure 2b, the other end 142 of the brace is a first fixing plate and the inner surface is arranged in contact with the upper surface of the upper surface of the end of the viscous damping device, the second fixing plate is arranged in contact with the lower surface of the end of the viscous damping device may include. Six through-holes may be formed in the first fixing plate, six through-holes may be formed in the second fixing plate, and six through-holes may be formed at an end of the viscosity damping device.

In various embodiments, the friction bolt 160 (or high-strength bolt) may pass through the through hole of the first fixing plate, the through hole of the viscous damping device, and the through hole of the second fixing plate to be fastened to the nut 161 . The end of the viscous damping device and the other end of the brace may be connected by friction bonding. At this time, the inner surface of the other end 142 of the brace and the upper surface of the end of the viscous damping device 150 are frictionally joined by a friction bolt, and the inner surface of the other end 142 of the brace and the end of the viscous damping device 150 . can be frictionally joined by friction bolts. That is, the other end of the brace 140 and the end of the viscous damping device 150 may be frictionally joined at two surfaces by the friction bolt 160 .

In various embodiments, the viscous damping device 150 and the brace 140 are a friction force proportional to the normal drag force (N1, N2, N3, N4), which is a force pressed by the friction bolt 160 fastened with the nut through the through hole. (f) this viscous damping device 150 and the brace 140 can be connected by friction bonding by acting on the two surfaces in contact with each other. The connection by frictional bonding of the viscous damping device 150 and the brace 140 does not cause relative movement or sliding between the viscous damping device 150 and the brace 140 even when the viscous damping device reciprocates by an impact load. Therefore, a slip phenomenon that may occur in the hinge connection structure does not occur, and a phenomenon in which a gap occurs in the damping history of the viscous damping device 150 can be prevented. In addition, the connection by two-sided friction bonding of the upper and lower surfaces of the viscous damping device 150 and the brace 140 may prevent relative angular movement or distortion between the viscous damping device 150 and the brace 140 from occurring. .

In various embodiments, the plurality of through-holes formed at the end of the viscous damping device 150 and the plurality of through-holes 143 formed at the other end of the brace 140 are each in the longitudinal direction of the viscous damping device 150 or It may have a long hole shape in the longitudinal direction of the brace 140. The viscous damping device 150 is a device for damping vibration by an impact load of 50 to 100 tons (t). In the process of connecting the viscous damping device 150 to the brace 140, a bolt is inserted into the through hole. In order to compress or expand the length of the viscous damping device 150, a load of 50 to 100 tons (t) must be applied, so it can be a great burden on construction. Therefore, since the through hole has a long hole shape in the longitudinal direction of the viscous damping device 150 or in the longitudinal direction of the brace 140, the length of the viscous damping device 150 is predetermined in the longitudinal direction without compression or expansion. It is possible to respond to tolerances of steel or concrete members that may occur during construction and errors due to frame standards.

4 is a view showing a reinforcing plate according to various embodiments.

3 and 4 , in various embodiments, the reinforcing plate may include a first reinforcing plate 110 and a second reinforcing plate 120 forming a right angle to the first reinforcing plate 110 . As described above, the gusset plate 130 may be bonded to the front surface of the reinforcing plates 110 and 120 . 4 shows the rear surfaces of the reinforcing plates 111 and 120 . A plurality of rigid members 111 and 121 having a 'L' shape may be coupled to the rear surface of the reinforcing plate, and the coupling between the rear surface of the reinforcing plates 111 and 120 and the rigid members 111 and 121 is coupled to the couplers 112 and 122 ) can be done by

3 , the plurality of third rigid members 111 may be fixed to the rear surface of the first reinforcing plate and sandwiched between the plurality of first rigid members 1 . The plurality of fourth rigid members 121 may be fixed to the rear surface of the second reinforcing plate and sandwiched between the plurality of second rigid members 2 . When the plurality of third rigid members 111 are sandwiched between the plurality of first rigid members 1 and the plurality of fourth rigid members 121 are sandwiched between the plurality of second rigid members 2 , the plurality of third rigid members At least some of the three rigid members 111 and at least some of the plurality of fourth rigid members 121 may cross each other. For example, the plurality of third rigid members 111 and the plurality of fourth rigid members 121 may be 'L'-shaped reinforcing bars.

In various embodiments, a plurality of rigid members 111 and 121 are fixedly coupled to the rear surfaces of the reinforcing plates 110 and 120 to include a plurality of first rigid members 1 or a plurality of second rigid members 2 , etc. A plurality of rigid members (111, 121) by being inserted into the frame of the building to be, the shear force applied to the frame by the operation of the viscous damping device can be evenly distributed without being biased on a specific surface of the joint part (3) of the frame It can perform the role of shear reinforcement, and can properly resist pulling out by the viscous damping device.

5 is a flowchart illustrating a method for constructing a vibration damping system for a building according to various embodiments of the present disclosure, and FIG. 6 is a diagram illustrating a method for constructing a vibration damping system for a building according to various embodiments of the present disclosure.

5 and 6 , in the method 200 for constructing a vibration damping system for a building according to various embodiments of the present disclosure, a plurality of first rigid members 1 and a plurality of first rigid members ( 1) is a method of providing a high-capacity viscous damping device 150 on a diagonal line connecting the junction 3 of the frame of the building in which a plurality of second rigid members 2 disposed perpendicular to each other intersect. For example, the first rigid member 1 may be a column reinforcing bar constituting a frame of a building, and the second rigid member 2 may be a prosthetic reinforcing bar. The viscous damping device 150 is a device for damping vibration (reciprocating motion) by an impact load of 50 to 100 tons (t), and silicon may be used as a viscous fluid.

In various embodiments, the method 200 for constructing a vibration damping system of a building includes a process 210 of fixedly arranging a first reinforcing plate and a second reinforcing plate, a process 220 of bonding the gusset plate, and a gusset plate and a viscous damping device may include a process 230 for connecting the through braces.

The process 210 is a process of fixing and disposing the first reinforcing plate 110 in parallel with the plurality of first rigid members 1 on one side of the junction part 3 and a plurality of second rigid members on one side of the junction part 3 ( 2) and may include a process of fixing and disposing the second reinforcing plate 120 in parallel with the second reinforcing plate 120 . The process of fixing and arranging the first reinforcing plate 110 in parallel with the plurality of first rigid members 1 on one side of the junction 3 is a process of arranging a plurality of third rigidity members provided on the rear surface of the first reinforcing plate 110 . It may include a process of sandwiching the member 111 between the plurality of first rigid members (1). In addition, the process of fixing and arranging the second reinforcing plate 120 in parallel with the plurality of second rigid members 2 on one side of the junction 3 is performed by a plurality of second reinforcing plates 120 provided on the rear surface of the second reinforcing plate 120 . 4 may include a process of sandwiching the rigid member 121 between the plurality of second rigid members 2 .

In various embodiments, the method 200 for constructing a vibration damping system of a building includes a process of installing a formwork on the outside of the plurality of first rigid members 1 and a plurality of second rigid members 2 after the process 210 and a formwork within the formwork It may further include the process of pouring concrete.

In various embodiments, the process of sandwiching the plurality of 'L'-shaped rigid members 111 and 121 provided on the rear surface of the reinforcing plate between the plurality of first rigid members or the plurality of second rigid members, respectively, is the vibration damping of the building. The system construction method 200 can be easily implemented. Through the process of pouring concrete after the above process, the plurality of rigid members 111 and 121 are formed so that the shear force applied to the frame by the operation of the viscous damping device is evenly distributed without being biased on the specific surface of the joint 3 of the frame. It can perform the role of shear reinforcement that allows the

The process 220 may include bonding the gusset plate 130 to the front surface of the first reinforcing plate 110 and the front surface of the second reinforcing plate 120 . The process of joining the gusset plate 130 to the front surface of the first reinforcing plate 110 and the second reinforcing plate 120 includes the process of welding and joining the vertical portion of the gusset plate to the front surface of the first reinforcing plate and the gusset plate. It may include a process of welding the horizontal portion to the front surface of the second reinforcing plate.

The process 230 may include a process of connecting one end of the brace 140 and the gusset plate 130 and a process of connecting the other end of the brace 140 and the end of the viscous damping device 150 by friction bonding. have. The process of connecting one end of the brace 140 and the gusset plate 130 may include a process of connecting one end of the brace 140 and the gusset plate 130 by fastening bolts and nuts. In one embodiment, when the brace 140 is integrally formed with the gusset plate 130 , the process of connecting one end of the brace 140 and the gusset plate 130 may be omitted.

In various embodiments, the process of connecting the other end of the brace 140 and the end of the viscous damping device 150 by friction bonding, the inner surface of the other end 142 of the brace 140 and the viscous damping device 150 It may include a process of friction-bonding the upper surface and the lower surface of the end of the two surfaces by a plurality of friction bolts (160). That is, in the process of connecting by friction bonding, the surface in contact between the inner surface of the other end 142 of the brace 140 and the upper surface of the end of the viscous damping device 150 is frictionally joined by a plurality of friction bolts 160 and a process of friction-joining the inner surface of the other end 142 of the brace 140 and the lower surface of the end of the viscous damping device 150 by friction bonding with a plurality of friction bolts 160 . Through the process of friction bonding on two surfaces by a plurality of friction bolts 160, as described with reference to FIGS. 2A and 2B, the viscous damping device 150 and the brace 140 pass through the through-hole to form a nut and The frictional force (f) proportional to the normal drag force (N1, N2, N3, N4) that is the force pressed by the friction bolt 160 to be fastened is the viscous damping device 150 and the brace 140 are in contact with each other two sides (eg, brace) By acting on the surface where the inner surface of the other end of the viscous damper is in contact with the upper surface of the viscous damper and the inner surface of the other end of the brace and the lower surface of the viscous damper are in contact), they can be connected by friction bonding.

In various embodiments, the process of friction bonding on two surfaces by a plurality of friction bolts 160 is provided at the other end 142 of the brace and has a long hole shape in the longitudinal direction of the brace 140 and viscous It may include a process of adjusting a position at which a plurality of friction bolts 160 are fastened in a through hole provided at the end of the damping device 150 and having a long hole shape in the longitudinal direction of the viscous damping device 150 . Viscosity damping device by having a through hole formed at the other end of the brace and the end of the viscous damping device through which the plurality of friction bolts 160 pass has a long hole shape in the longitudinal direction of the brace or in the longitudinal direction (vibration direction) of the viscous damping device. By leaving a predetermined margin in the longitudinal direction of the viscous damping device without compressing or expanding the length of 150, it is possible to respond to tolerances of steel or concrete members and errors according to frame standards that may occur during construction.

Claims (20)

A viscous damping device is installed on a line connecting a junction where a plurality of first rigid members disposed parallel to each other and a plurality of first rigid members disposed perpendicular to the plurality of first rigid members intersect each other in the design stage. As a vibration damping system for a building that is attached to a building,
a first reinforcing plate fixedly arranged in parallel with the plurality of first rigid members on one side of the joint portion;
a second reinforcing plate that is fixedly arranged in parallel with the plurality of second rigid members and is perpendicular to the first reinforcing plate;
One end is vertically fixed to the rear surface of the first reinforcing plate and fitted between the plurality of first rigid members, and the other end is formed to face the junction in parallel with the first rigid member, arranged at regular intervals in a L-shape a plurality of third rigid members;
One end is vertically fixed to the rear surface of the second reinforcing plate and fitted between the plurality of second rigid members, and the other end is formed to face the joint portion in parallel with the second rigid member, arranged at regular intervals in a L-shape a plurality of fourth rigid members;
a gusset plate including a vertical portion joined to the front surface of the first reinforcing plate, a horizontal portion joined to the front surface of the second reinforcing plate, and a connection portion protruding in a direction in which the line extends;
One end is connected to the connecting portion, the other end is a brace connected by friction bonding with the end of the viscous damping device; includes,
At least a part of the other ends of the plurality of third rigid members and at least a part of the other ends of the plurality of fourth rigid members intersect each other at the joint portion.
The method according to claim 1,
The inner surface of the other end of the brace and the upper and lower surfaces of the end of the viscous damping device are frictionally joined on two surfaces by a plurality of friction bolts, a vibration damping system for a building.
3. The method according to claim 2,
A plurality of through-holes to which the plurality of friction bolts are fastened are respectively provided at the other end of the brace and the end of the viscous damping device.
4. The method of claim 3,
The plurality of through-holes have a long hole shape in the longitudinal direction of the brace or in the longitudinal direction of the viscous damping device, the vibration damping system of the building.
delete delete delete The method according to claim 1,
The vertical portion of the gusset plate is joined to the front surface of the first reinforcing plate through welding,
The horizontal portion of the gusset plate is joined to the front surface of the second reinforcing plate through welding.
The method according to claim 1,
The connection part of the gusset plate and one end of the brace are connected by fastening a bolt and a nut, or the gusset plate and the brace are integrally formed, a vibration damping system for a building.
The method according to claim 1,
The viscous damping device dissipates the impact applied to the building using silicon viscosity, a vibration damping system for a building.
A viscous damping device is installed on a line connecting a junction where a plurality of first rigid members disposed in parallel with each other and a plurality of second rigid members disposed perpendicular to the plurality of first rigid members intersect each other in the design stage. A method of constructing a vibration damping system for a building provided by being joined to a building, comprising:
A process of fixing and disposing a first reinforcing plate in parallel with the plurality of first rigid members on one side of the joint portion;
The process of fixing and disposing a second reinforcing plate in parallel with the plurality of second rigid members on one side of the joint portion;
a process of sandwiching a plurality of third rigid members between the plurality of first rigid members so that one end is vertically provided at a predetermined interval on the rear surface of the first reinforcing plate, and the other end is at least partially extended to the junction;
a process of sandwiching a plurality of fourth rigid members between the plurality of second rigid members so that one end is vertically provided at a predetermined interval on the rear surface of the second reinforcing plate, and the other end is at least partially extended to the junction;
bonding a gusset plate to the front surface of the first reinforcing plate and the front surface of the second reinforcing plate; and
The process of connecting the gusset plate and the viscous damping device through a brace; including, a construction method of a vibration damping system for a building.
12. The method of claim 11,
The process of connecting the gusset plate and the viscous damping device through a brace,
The process of connecting one end of the brace and the gusset plate,
Containing the process of connecting the other end of the brace and the end of the viscous damping device by friction bonding, the construction method of a vibration damping system for a building.
13. The method of claim 12,
The process of connecting the other end of the brace and the end of the viscous damping device by friction bonding,
Containing the process of friction bonding the inner surface of the other end of the brace and the upper and lower surfaces of the ends of the viscous damping device on two surfaces by a plurality of friction bolts, the construction method of a vibration damping system of a building.
14. The method of claim 13,
The process of friction-joining the inner surface of the other end of the brace and the upper and lower surfaces of the ends of the viscous damping device on two surfaces by a plurality of friction bolts,
The plurality of through-holes provided at the other end of the brace and having a long hole shape in the longitudinal direction of the brace and a through hole provided at the end of the viscous damping device and having a long hole shape in the longitudinal direction of the viscous damping device. A method of constructing a vibration damping system for a building, comprising the process of adjusting a position at which the friction bolt is fastened.
delete delete 12. The method of claim 11,
installing a formwork on the outside of the plurality of first rigid members and the plurality of second rigid members; and
Further comprising the process of pouring concrete in the formwork, the construction method of the vibration damping system of the building.
12. The method of claim 11,
The process of bonding the gusset plate to the front surface of the first reinforcing plate and the front surface of the second reinforcing plate,
The process of welding the vertical portion of the gusset plate to the front surface of the first reinforcing plate, and
Including the step of welding the horizontal portion of the gusset plate to the front surface of the second reinforcing plate, the construction method of the vibration damping system of a building.
13. The method of claim 12,
The process of connecting one end of the brace and the gusset plate is,
Containing the process of connecting one end of the brace and the gusset plate by fastening bolts and nuts, the construction method of a vibration damping system for a building.
12. The method of claim 11,
The viscous damping device dissipates the impact applied to the building using silicon viscosity, the construction method of the vibration damping system of the building.

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