KR101766895B1 - seismic retrofitting structure of concrete structure - Google Patents

Abstract

The present invention relates to a seismic reinforcement structure of a building having a new structure of improving a seismic performance of a building. According to the seismic reinforcement structure of a building disclosed herein, when the building vibrates by an earthquake in a lateral direction and a vertical direction, a support (20) and a weight (50) vibrate in a lateral direction, and the weight (50) vibrates in a vertical direction to attenuate the vibrations of the building, thereby being able to improve a seismic performance of a building. In particular, the present invention is advantageous in that such a seismic structure is able to be applied to an existing building being installed.

Description

Seismic Retrofitting Structure of Concrete Structure

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to an anti-seismic structure of a new structure capable of improving seismic performance of a building.

In general, houses, office buildings, apartments, and various other types of buildings are designed to withstand a constant strength of an earthquake in design. Recently, as the strength of an earthquake increases, Performance is gradually improving.

In order to improve the seismic performance of the building, it is necessary to increase the strength of the columns, walls, or slabs of the building. As such, as a method of increasing the strength of pillars, walls or slabs of a building, A method of thickening the thickness is mainly used.

However, when the thickness of the columns, walls, or slabs of the building is increased, not only an enormous construction cost is increased but also the interior space of the building is reduced and the weight of the building itself is increased. There was a difficult problem.

Particularly, in the case of this method, there is a problem that the seismic performance can not be improved in the case of the existing construction.

Therefore, there is a need for a new method to solve such a problem.

Patent No. 10-1257667,

SUMMARY OF THE INVENTION It is an object of the present invention to provide an earthquake-proof reinforcement structure of a new structure capable of improving seismic performance of a building.

The upper and lower slabs (1, 2) are vertically spaced apart from each other. Vertical walls (3) extending in the vertical direction and having upper and lower ends fixed to the upper and lower slabs (1, 2) (11) provided to extend laterally from upper and lower sides of the vertical wall (3), and a second guide rail (11) provided on the upper surface of the lower slab (2) Second and third guide rails 12 and 13 extending parallel to the first guide rail 11 and extending in the vertical direction and having a middle portion extending laterally to the first guide rail 11, (20) slidably coupled to the first and second guide rails and having upper and lower ends slidably and laterally slidably coupled to the second and third guide rails (12, 13) Is elastically supported to elastically slide in the lateral direction A first damper 40 connected to the support 20 to attenuate the lateral vibration of the support 20 and a second damper 40 connected to the support 20 in such a manner that the weight A second elastic member 60 connected to the weight 50 so as to support the weight 50 so as to be elastically lifted and moved along the support base 20 and a second elastic member 60 connected to the weight 50, And a second damper (70) for attenuating the vibration of the building (50).

According to another aspect of the present invention, the support 20 includes a cylinder 21 which is vertically extended and has a cylindrical shape having a through hole formed in the upper and lower surfaces thereof, and is slidably coupled to the first guide rail 11 laterally, Upper and lower piston members 22 and 23 vertically coupled to each other in the cylinder 21; upper and lower piston rods 24 and 25 extending upward and downward from the upper and lower piston members 22 and 23; , Upper and lower slide blocks (24, 25) rotatably coupled to upper and lower ends of the upper and lower piston rods (24, 25) so as to be laterally slidable to the second and third guide rails And friction members (22a, 23a) closely attached to the inner circumferential surface of the cylinder (21) are provided on the circumferential surfaces of the upper and lower piston members (22, 23) When the slabs (1, 2) are vibrated in the vertical direction, And the weight (50) is coupled to the outside of the cylinder (21) so as to be able to ascend and descend, while the stone members (22, 23) are raised and lowered to attenuate the vibration of the upper and lower slabs An earthquake-proof reinforcement structure of a building is provided.

According to another aspect of the present invention, there are provided a first measurement means 80 for measuring a lateral vibration width of the support 20, a second measurement means 90 for measuring a vertical vibration width of the weight 50, (100) for receiving signals of the first and second measuring means (80,90), and an alarm means (110) operated in accordance with a control signal of the control means (100) Wherein the control means (100) receives data of a vibration amplitude of the support (20) measured by the first measurement means (80) and a vibration amplitude of the weight (50) measured by the second measurement means (90) And when the vibration width of the support (20) and the vibration width of the weight (50) exceed a preset value, the warning means (110) is operated to output a warning of escape Structure is provided.

According to another aspect of the present invention, the control means 100 is connected to an elevator controller 120 for controlling the operation of the elevator of the building, and operates the alarm means 110 and the elevator controller 120, Wherein the door is stopped when the elevator is moved to the closest floor and then the door is stopped.

According to another aspect of the present invention, the first measurement means 80 includes a rack gear train 81 formed to extend laterally in the first guide rail 11, And an angle measuring sensor 83 connected to the pinion gear 82 and measuring a rotation angle of the pinion gear 82. The pinion gear 82 is rotatably coupled to the rack gear train 81, And the second measurement means 90 includes a rack gear train 91 formed to extend vertically in the cylinder 21 and a rack gear train 91 rotatably coupled to the weight 50, And an angle measurement sensor (93) connected to the pinion gear (92) and measuring a rotation angle of the pinion gear (92), wherein the first and second measurement means Further comprising a first and a second generator (131, 132) connected to the pinion gears (82, 92) of the first, The earthquake-proof reinforcement structure, the structure, characterized in that using the electricity generated from the generator 2 (131 and 132) as a power source is provided.

According to the seismic strengthening structure of the building according to the present invention, when the building is vibrated laterally and vertically by the earthquake, the support base 20 and the weight 50 are vibrated laterally, and the weight 50 is vertically The vibration of the building is attenuated, thereby improving the seismic performance of the building.

In particular, such an anti-seismic reinforcing structure has an advantage that it can be applied to existing buildings.

1 is a side view of a building seismic retrofitting structure according to the present invention,
FIG. 2 is a side cross-sectional view showing a building seismic-strengthening structure according to the present invention,
3 to 7 are elevation views showing the operation of the building seismic retrofitting structure according to the present invention,
8 is a side cross-sectional view showing a second embodiment of a building seismic retrofitting structure according to the present invention,
9 is a circuit diagram showing a second embodiment of a building seismic retrofitting structure according to the present invention.
10 is a circuit configuration diagram illustrating a modified example of the second embodiment of the building seismic retrofitting structure according to the present invention.
11 is a side cross-sectional view showing a third embodiment of a building seismic retrofitting structure according to the present invention,
12 is a circuit block diagram of a third embodiment of a building seismic retrofitting structure according to the present invention.

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

1 to 7 illustrate an anti-seismic structure of a building according to the present invention, wherein the building includes upper and lower slabs 1 and 2 so as to be spaced apart in the vertical direction, and upper and lower ends, 1, 2) are provided in the same manner as in the prior art.

According to the present invention, the seismic reinforcing structure of the building comprises a first guide rail 11 provided so as to extend laterally from upper and lower sides of the vertical wall 3, Second and third guide rails 12 and 13 provided on the upper surface of the lower slab 2 so as to be in parallel with the first guide rail 11 and extending in the vertical direction, (20) slidably coupled to the first guide rail (11) in the lateral direction and slidably coupled to the second and third guide rails (12, 13) laterally; A first elastic member 30 provided on the support base 20 and elastically supporting the support base 20 so as to elastically slide in the lateral direction and a second elastic member 30 connected to the support base 20 to reduce lateral vibration of the support base 20, , A first damper (40) which is movable up and down on the outside of the support base A second elastic member 60 connected to the weight 50 to support the weight 50 so as to be elastically lifted up and down along the support 20 and a second elastic member 60 connected to the weight 50, And a second damper (70) for attenuating the vibration of the weight (50).

To be more specific, the first guide rails 11 are formed as upper and lower pairs and are fixedly coupled to the vertical wall 3 by anchor bolts so as to extend in the horizontal direction.

The second guide rail 12 is provided on the lower side of the upper slab 1 and the third guide rail 13 is provided on the lower side of the lower slab 2 so as to be positioned on both sides of the vertical wall 3. [ Respectively.

The support base 20 includes a cylinder 21 extending in the vertical direction and formed in a cylindrical shape having a through hole formed in the upper and lower surfaces thereof and slidably coupled to the first guide rail 11 in the lateral direction, Upper and lower piston members 22 and 23 vertically coupled to each other so as to be able to move up and down in the upper and lower piston members 22 and 23. The upper and lower piston rods 24 and 25, And upper and lower slide blocks (26, 27) rotatably coupled to upper and lower ends of the first and second guide rails (24, 25) so as to be laterally slidable to the second and third guide rails .

At this time, a pair of latching protrusions 21a protruding outward are formed on the outer peripheral surface of the cylinder 21 so as to be spaced apart from each other in the vertical direction.

Friction members 22a and 23a are provided on the circumferential surfaces of the upper and lower piston members 22 and 23 so as to be in close contact with the inner circumferential surface of the cylinder 21. As shown in FIG. 7, The upper and lower piston members 22 and 23 are lifted together with the upper and lower piston rods 24 and 25 when the side slabs 1 and 2 are vibrated in the vertical direction or the building is twisted, The upper and lower slide blocks 26 and 27 are rotated so as to correspond to the inclination of the third guide rails 12 and 13 to attenuate the vibrations of the upper and lower slabs 1 and 2. [

The first elastic member 30 is provided on both sides of the first guide rail 11 and uses a compression coil spring for supporting both the upper and lower ends of the upper and lower piston rods 24 and 25. As shown in Figs. When the building is laterally moved by an earthquake, the support 20 and the weight 50 are elastically supported so as to be vibrated laterally.

To this end, the first guide rail 11 is formed with a locking protrusion 11a for supporting the outer end of the elastic member.

The first damper 40 uses an air damper whose one end is fixed to the first guide rail 11 and the stopper is connected to the piston. The support 20 is supported by the first elastic member 30, So that the oscillation of the support 20 is rapidly reduced by attenuating the lateral kinetic energy of the support 20.

Such an air damper is the same as that used for a shock absorber of a vehicle, and various configurations have been developed and used, and a detailed description thereof will be omitted.

The weight 50 is made of a metal material having a high specific gravity and is provided with a coupling hole 51 through which the cylinder 21 is coupled so as to penetrate the upper and lower surfaces of the cylinder 21, As shown in Fig.

The second elastic member 60 is made of an extruded coil spring connected to the outside of the cylinder 21 so that its upper and lower ends are brought into close contact with the upper and lower sides of the engagement step 21a and the cylinder 21, As shown in Fig. 6, the weight 50 is supported so as to be elastically vibrated in the vertical direction.

The second damper 70 uses an air damper whose one end is fixed to the cylinder 21 and the other end is fixed to the weight 50. The weight 50 is supported by the second elastic member 60 The vibration of the weight 50 is rapidly reduced by expanding and contracting the vibration of the weight 50 in the vertical direction to attenuate the kinetic energy of the weight 50 in the up and down direction.

The second damper 70 is constructed in the same manner as the first damper 40 described above, and a detailed description thereof will be omitted.

And the reference numeral 4, which is not described, shows a cover panel which is installed so as to cover and cover the outside of the seismic strengthening structure.

The operation of the structure constructed as described above will be described as follows.

3 to 5, when the earthquake is generated and the building is vibrated in the lateral direction, the support 20 and the weight 50 are supported by the first elastic member 30 The building is vibrated so as to have a pulse of a phase different from that of the vibration of the building, thereby attenuating the lateral vibration of the building.

3, when the building starts to vibrate to the left due to an earthquake, the first guide rail 11 vibrates to the left together with the building, while the support 20 and the weight (for example, 50) will not move while stopped by inertia.

Therefore, when the first elastic member 30 on the right side is compressed by the support 20 and the weight 50 and the first elastic member 30 is sufficiently compressed, as shown in FIG. 4, The support member 20 and the weight 50 are pushed to the left by the members 30 while being supported by the first to third guide rails 13. [

5, when the building is vibrated to the right, the support 20 and the weight 50, which are pushed to the left side, are pushed to the left side as shown in Fig. 5 at the time when the support 20 and the weight 50 are pushed to the left The structure that vibrates to the right side is pushed to the left side while compressing the first elastic member 30 on the left side.

The first elastic member 30 on the left side is again compressed and the building is pushed back to the left when the support 20 and the weight 50 are pushed to the right. (50).

Therefore, when the building is vibrated in the lateral direction, the support 20 and the weight 50 vibrate in the lateral direction at a slow tempo and slower than the vibration period of the building, thereby canceling the vibration of the building, Thereby reducing the width.

When the earthquake is reduced and the vibration of the building is stopped, the support base 20 and the weight 50 are quickly stopped by the first damper 40, so that the support base 20 and the weight 50, Thereby preventing it from being shaken in the lateral direction.

6, when the structure 50 vibrates in the up-and-down direction along the support platform 20, the above-described method (the support 20 and the weight 50) (A method of attenuating the lateral vibration of the building while the building 50 is vibrated in the lateral direction).

7, when the upper and lower slabs 1 and 2 are vibrated in the vertical direction by the vibration of the building and the vertical wall 3 and the upper and lower slabs 1 and 2 are twisted, The upper and lower piston rods 24 and 25 and the upper and lower pistons of the upper and lower slabs 20 are lifted and the vibration of the upper and lower slabs 1 and 2 and the torsion of the vertical wall 3 and the upper and lower slabs 1 and 2 Decay.

According to the earthquake-proofing structure of the building thus configured, when the building is vibrated laterally and vertically by the earthquake, the support base 20 and the weight 50 are vibrated laterally, and the weight 50 is moved vertically By vibrating the building while vibrating, there is an advantage that the seismic performance of the building can be improved.

In particular, such an anti-seismic reinforcing structure has an advantage that it can be applied to existing buildings.

The support base 20 includes a cylinder 21 extending vertically and having a through hole formed in the upper and lower surfaces thereof and connected to the first guide rail 11 so as to be slidable laterally, The upper and lower piston members 22 and 23 are vertically extended from the upper and lower piston members 22 and 23. The upper and lower ends of the upper and lower piston members 22 and 23 are connected to the second and third guide rails 12 and 13 And the upper and lower piston members (22, 23) are provided on the circumferential surface thereof with a friction member (24, 25) which is in close contact with the inner circumferential surface of the cylinder (21) The upper and lower piston members 22 and 23 are vertically moved by the earthquake to cause the upper and lower slabs 1 and 2 to move up and down. And the weight (50) is configured to attenuate vibration of the cylinder (21) When the upper and lower slabs 1 and 2 are vertically vibrated by the vibration of the building or when the vertical wall 3 and the upper and lower slabs 1 and 2 are twisted, The upper and lower piston rods 24 and 25 and the upper and lower pistons of the upper and lower side slabs 1 and 2 move up and down so that the vibrations of the upper and lower slabs 1 and 2 and the torsion of the vertical wall 3 and the upper and lower slabs 1 and 2 can be attenuated. There is an advantage.

8 and 9 illustrate a second embodiment according to the present invention. The first measurement means 80 measures the lateral vibration amplitude of the support 20, and the second measurement means 80 measures the vertical vibration amplitude of the weight 50 (100) for receiving signals of the first and second measuring means (80, 90), and a second measuring means (90) And an alarm unit 110 for outputting the alarm signal.

The first measurement means 80 includes a rack gear train 81 formed to extend laterally to the first guide rail 11 and a second gear train 81 rotatably coupled to the cylinder 21 of the support platform 20, A pinion gear 82 engaged with the gear train 81 and an angle measuring sensor 83 connected to the pinion gear 82 and measuring the rotation angle of the pinion gear 82, The angle measuring sensor 83 measures the angle at which the pinion gear 82 is rotated so that the angle of the pinion gear 82 in the rack gear train 81 It is possible to measure the distance in which the support member 20 is laterally slid.

The second measuring means 90 includes a rack gear train 91 formed to extend vertically in the cylinder 21 and a rack gear train 91 rotatably coupled to the weight 50 and engaged with the rack gear train 91 And an angle measuring sensor 93 connected to the pinion gear 92 and measuring the rotation angle of the pinion gear 92. When the weight 50 is slid in the vertical direction, The angle measurement sensor 93 measures the angle at which the pinion gear 92 is rotated so that the weight 50 is rotated in the vertical direction The distance of the slide can be measured.

The control means 100 receives and stores the data of the oscillation width of the support 20 measured by the first measuring means 80 and the oscillation width of the weight 50 measured by the second measuring means 90 , And when the vibration width of the support base (20) and the vibration width of the weight (50) exceed a predetermined value, the warning means (110) is operated to output a warning of evacuation.

The alarm means 110 uses a fire alarm provided in the building, and outputs light and a warning sound during operation, thereby guiding people inside the building to quickly evacuate.

According to the earthquake-proof reinforcement structure of the structure thus constructed, when the earthquake is generated and the support base 20 is vibrated in the lateral direction or the weight 50 is vibrated in the vertical direction, 1 and the second measuring means 80 and 90 are received and stored so that the vibration value data stored in the control means 100 is backed up and analyzed in the future so that the actual vibration of each part of the building Value, and can be used as data for determining whether to install an additional seismic reinforcement structure.

When the vibration amplitude of the support base 20 and the vibration amplitude of the weight 50 measured by the first measurement means 80 and the second measurement means 90 exceeds a preset value , The alarming means 110 is operated to output a warning for evacuation.

Therefore, when the vibration amplitude of the building is excessively large due to the earthquake, the alarm is outputted in advance to evacuate the people in the building, thereby securing the safety of the people have.

The control means 100 controls the oscillation width of the support 20 and the oscillation width of the weight 50 measured by the first measuring means 80 and the second measuring means 90 to be a preset value The warning means 110 is operated to output a warning of evacuation. However, in the case of a building equipped with an elevator, as shown in FIG. 10, the control means 100 controls the operation of the elevator of the building To the elevator controller 120, which controls the elevator controller 120.

In this case, the control means 100 determines that the oscillation width of the support 20 and the oscillation width of the weight 50, which are measured by the first measuring means 80 and the second measuring means 90, The alarming unit 110 is activated and the operation of the elevator controller 120 is controlled so that the elevator is moved to the closest floor and then stopped when the door is opened.

Accordingly, there is an advantage that, when a danger occurs in a building, the elevator is forcibly stopped so that people in the elevator or people in the room can evacuate through the stairs without using the elevator.

In other words, if people take refuge in an elevator after an earthquake occurs, the elevator can be broken down and people can be trapped in the elevator. In the present invention, by forcibly stopping the elevator, , Thereby preventing people from getting trapped in the elevator.

11 and 12 illustrate a third embodiment according to the present invention in which the first and second generators 131 and 132 are connected to the pinion gears 82 and 92 of the first and second measuring means 80 and 90, And the control means 100 is configured to use the electricity generated by the first and second generators 131 and 132 as a power source.

Accordingly, when an earthquake occurs and the support base 20 and the weight 50 are vibrated horizontally and vertically to rotate the pinion gears 82 and 92, the first and second generators 131 and 132, The control means 100 is operated to receive and record the signals output from the first and second measuring means and operate the alarm means 110. [

According to the earthquake-reinforcement structure constructed as described above, since the control means 100 is operated by the electricity outputted from the first and second generators 131 and 132, the separate power source is applied to the control means 100 There is an advantage that the control means 100 operates normally even if a power failure occurs due to an earthquake.

11. First guide rail 12. Second guide rail
13. Third guide rail 20. Support
30. First elastic member 40. First damper
50. Weight 60. Second elastic member
70. Second damper 80. First measuring means
90. Second measuring means 100. Control means
110. Alarming means

Claims (5)

The upper and lower slabs 1 and 2 are vertically spaced apart from each other,
And a vertical wall (3) extending in the vertical direction and having upper and lower ends fixed to the upper and lower slabs (1, 2)
A first guide rail 11 extending laterally from upper and lower sides of the vertical wall 3,
Second and third guide rails (12, 13) provided parallel to the first guide rail (11) on the lower side of the upper slab (1) and the upper side of the lower side slab (2)
And the middle portion is slidably coupled to the first guide rail 11 in the lateral direction and the upper and lower ends thereof are slidably coupled to the second and third guide rails 12 and 13 in the lateral direction A support table 20,
A first elastic member 30 provided on the first guide rail 11 and elastically supporting the support base 20 so as to elastically slide in the lateral direction,
A first damper 40 connected to the supporter 20 to attenuate the lateral vibration of the supporter 20,
A weight 50 which is vertically coupled to the outside of the support 20,
A second elastic member 60 connected to the weight 50 to support the weight 50 so as to be elastically lifted along the support base 20,
And a second damper (70) connected to the weight (50) and attenuating vibration of the weight (50).
The method according to claim 1,
The support 20 includes a cylinder 21 extending vertically and having a through hole formed in the upper and lower surfaces thereof, a cylinder 21 slidably coupled to the first guide rail 11 in the lateral direction,
Upper and lower piston members 22 and 23 vertically coupled to the cylinder 21,
Upper and lower piston rods (24, 25) extending in the vertical direction in the upper and lower piston members (22, 23)
Upper and lower slide blocks (26, 26) coupled to upper and lower ends of the upper and lower piston rods (24, 25) so as to be vertically rotatable and laterally slidably connected to the second and third guide rails (12, 27)
The peripheral surfaces of the upper and lower piston members 22 and 23 are provided with friction members 22a and 23a which are in close contact with the inner peripheral surface of the cylinder 21,
The upper and lower piston members 22 and 23 are lifted and lowered to attenuate the vibrations of the upper and lower slabs 1 and 2 when the upper and lower slabs 1 and 2 are vibrated in the vertical direction by an earthquake, And the weight (50) is vertically coupled to the outside of the cylinder (21).
3. The method of claim 2,
A first measuring means 80 for measuring a lateral vibration width of the support 20,
A second measuring means (90) for measuring a vertical vibration width of the weight (50)
A control means (100) for receiving signals of the first and second measuring means (80, 90)
Further comprising an alarm means (110) activated according to a control signal of the control means (100) to output an alarm,
The control means 100 receives and stores the data of the oscillation width of the support 20 measured by the first measuring means 80 and the oscillation width of the weight 50 measured by the second measuring means 90 , And when the vibration width of the support (20) and the vibration width of the weight (50) exceed a preset value, the warning means (110) is operated to output a warning of evacuation.
The method of claim 3,
The control means 100 is connected to an elevator controller 120 for controlling the operation of the elevator of the building,
Wherein the alarming unit (110) is operated and the operation of the elevator controller (120) is controlled so that the elevator is moved to the closest floor and then stopped when the door is opened.
The method of claim 3,
The first measurement means (80)
A rack gear train 81 formed to extend laterally in the first guide rail 11,
A pinion gear 82 rotatably coupled to the cylinder 21 of the support 20 and engaged with the rack gear train 81,
And an angle measurement sensor (83) connected to the pinion gear (82) and measuring the rotation angle of the pinion gear (82)
The second measuring means (90)
A rack gear train 91 formed to extend vertically in the cylinder 21,
A pinion gear 92 rotatably coupled to the weight 50 and engaged with the rack gear train 91,
And an angle measurement sensor (93) connected to the pinion gear (92) for measuring a rotation angle of the pinion gear (92)
Further comprising first and second generators (131, 132) connected to the pinion gears (82, 92) of the first and second measuring means (80, 90)
Wherein the control means (100) uses electricity generated from the first and second generators (131, 132) as a power source.

Images