KR102556423B1 - Lead-inserted seismic isolation bearing with improved negative reaction force - Google Patents

Abstract

The present invention, in an earthquake isolation bearing installed on a lower structure and supporting the upper structure, includes an upper plate 110 forming an upper surface of the earthquake isolation bearing; A lower plate 120 forming the lower surface of the earthquake isolation support; a rubber pad 160 provided between the upper plate 110 and the lower plate 120; an upper reinforcing plate 130 provided on top of the rubber pad 160 to contact the lower surface of the upper plate 110; a lower reinforcing plate 140 provided under the rubber pad 160 to contact the upper surface of the lower plate 120; Internal reinforcing plates 150 provided at regular intervals on the inside of the rubber pad 160; A lead core 170 is provided to pass through the upper reinforcement plate 130, the rubber pad 160, the inner reinforcement plate 150, and the lower reinforcement plate 140 vertically, and the lead core 170 , It relates to a lead-inserted seismic isolation bearing with improved negative reaction force performance including a main body portion 171 and a reaction force portion.

Description

Lead-inserted seismic isolation bearing with improved negative reaction force}

The present invention relates to a support installed between an upper structure and a lower structure of a bridge or building structure to absorb displacement, impact, and the like while supporting a load of the upper structure. More specifically, in an earthquake isolation bearing into which a lead core is inserted, by providing a reaction force portion in the lead core, various loads and displacements can be smoothly accommodated and the negative reaction force performance to more stably support the upper structure is improved. It relates to an improved lead-inserted seismic isolation bearing.

In general, support is installed between the upper structure and lower structure (foundation, column, pier, abutment) of a bridge or building structure, and supports the load of the upper structure, and at the same time occurs due to temperature change, creep, drying shrinkage and deflection It is used for seismic design and seismic isolation to secure the stability of structures against earthquakes by accommodating stretching, rotational displacement, and movement, and transmitting, isolating, and dissipating loads, vibrations, and shocks.

Comparing seismic design and seismic isolation, seismic design is designing to exceed the value of seismic force by increasing the member forces such as strength and ductility of structural members, and seismic isolation is superior in earthquake resistance by artificially lengthening the natural period of a structure. It is designed to reduce the size of the seismic force transmitted by avoiding and isolating the resonance of the earthquake and the structure by shifting it from the periodic band.

After grasping the dynamic characteristics of seismic waves, which show that seismic waves contain many high-frequency components but little low-frequency components, rather than the concept of seismic design, which is designed to resist seismic waves, the structure is flexible and does not transmit high-frequency components during an earthquake. seismic isolation is more effective.

Lead-inserted seismic isolation bearings are a type of earthquake isolation bearings, and lead is inserted into conventional laminated rubber bearings (rubber bearings in which a large number of rubber and steel plates are laminated) to lengthen the natural period of the structure to reduce the magnitude of the horizontal earthquake force itself. It is an earthquake isolation support.

Lead easily yields to temperature loads classified as long-term loads and transmits a small horizontal force caused by the temperature load of the upper structure to the lower structure. It has material properties.

In addition, for seismic loads, lead completely yields, and the natural period of the structure is increased with a flexible rubber layer to reduce the magnitude of the seismic force, and the vibration energy of the superstructure is isolated and dissipated by the nonlinear behavior of the lead to suppress the vibration of the superstructure.

As described above, the performance of the conventional lead-inserted seismic isolation bearing is capable of suppressing displacement for short-term loads and increasing the natural period to reduce the horizontal seismic force and suppress vibration of the upper structure in order to maintain the safety of the structure in the event of an earthquake. , there were some problems.

1 and 2 show an external perspective view and a plan view of a general lead-inserted seismic isolator (FIG. 1 is a case in which a rubber pad and upper and lower reinforcing plates are circular, and FIG. 2 is a case in which a rubber pad and upper and lower reinforcing plates are rectangular) are shown, 3 is a cross-sectional perspective view of a conventional lead-inserted earthquake isolation bearing, and FIG. 4 is a cross-sectional view of a conventional lead-inserted earthquake isolation bearing.

As shown in FIGS. 3 and 4, the lead core 17 of the conventional lead-inserted seismic isolation bearing has a cylindrical structure with a constant diameter vertically, and the structure of this lead core has the following problems.

In other words, when an overturning moment occurs in a structure due to an earthquake, the stability of the upper structure against the upper structure due to the overturning moment is insufficient, and when a horizontal force acts on the upper structure, the horizontal force is not fully transmitted due to the separation of the lead core. There was, and there was a problem of not properly responding to the side reaction force caused by the upward force acting on the upper structure.

Therefore, it is required to develop a lead-inserted seismic isolation bearing that has high stability against levitation caused by the overturning moment of the structure, can accurately transmit the horizontal force generated by horizontal displacement, and has an excellent anti-reaction function.

Registered Patent 10-1008664

In order to improve the above problems of the prior art, an object of the present invention is to provide a lead-inserted seismic isolation bearing with improved stability and stability against injury caused by an overturning moment acting on a structure during an earthquake and improved anti-collision performance. .

An object of the present invention is to provide a lead-inserted seismic isolation bearing with improved negative reaction force performance in which the lead core does not come off by the reaction force portion of the lead core even when rotational displacement, horizontal displacement, or upward displacement occurs.

In the present invention, in an earthquake isolation bearing installed on a lower structure to support an upper structure, the upper plate 110 forming an upper surface of the earthquake isolation bearing; A lower plate 120 forming the lower surface of the earthquake isolation support; a rubber pad 160 provided between the upper plate 110 and the lower plate 120; an upper reinforcing plate 130 provided on top of the rubber pad 160 to contact the lower surface of the upper plate 110; a lower reinforcing plate 140 provided under the rubber pad 160 to contact the upper surface of the lower plate 120; Internal reinforcing plates 150 provided at regular intervals on the inside of the rubber pad 160; A lead core 170 provided so as to pass through the upper reinforcing plate 130, the rubber pad 160, the inner reinforcing plate 150, and the lower reinforcing plate 140 vertically and in close contact with each other, and the lead core 170 ), the body portion 171; an upper reaction force portion 172 provided at an upper end of the main body portion 171; It includes a lower reaction force part 173 provided at the lower end of the body part 171, and the body part 171, upper reaction force part 172 and lower reaction force part 173 are made of lead and integrally provided. The cross-sectional shape is circular, the diameter of the body portion 171 is constant vertically, and the diameters of the upper reaction force portion 172 and the lower reaction force portion 173 are larger than the diameter of the body portion 171. Therefore, the upper reaction force part 172 and the lower reaction force part 173 form a structure that is caught on the upper reinforcement plate 130 and the lower reinforcement plate 140, respectively. to provide.

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It is characterized in that the diameter of the upper reaction force part 172 increases as it goes upward, and the diameter of the lower reaction force part 173 increases as it goes downward.

It is characterized in that the diameters of the upper reaction force part 172 and the lower reaction force part 173 are constant.

It is characterized in that the diameter of the upper reaction force part 172 increases and then decreases while going upward, and the diameter of the lower reaction force part 173 increases and then decreases while going downward.

The upper end of the main body part 171 is located at the same height as the lower surface of the upper reinforcing plate 130 or higher than the lower surface of the upper reinforcing plate 130, and the lower end of the main body part 171 is located at the same height as the lower reinforcing plate 140. It is characterized in that it is located at the same height as the upper surface of the ) or lower than the upper surface of the lower reinforcing plate 140.

The upper end of the body portion 171 is located above the lower surface of the upper reinforcing plate 130, and the lower end of the main body portion 171 is located below the upper surface of the lower reinforcing plate 140. .

The upper reaction force part 172 and the lower reaction force part 173 are characterized in that they are provided in singular or plural numbers, respectively.

The upper reaction force part 172 and the lower reaction force part 173 are characterized in that they are provided in singular or plural numbers, respectively.

The lead-inserted seismic isolation bearing with improved reaction force performance according to the present invention has the following effects.

First, even if rotational displacement occurs during the use of the structure, the upper and lower reaction parts provided on the upper and lower parts of the lead core are structured so that the upper and lower reinforcing plates are hooked, respectively, so that the lead core does not escape. There is no separation between the upper plate and the lower plate. Therefore, it is possible to sufficiently secure stability and safety against rotational displacement.

Second, when a negative reaction force is generated, the upper reaction part and the lower reaction part provided on the upper and lower parts of the lead core are each hooked to the upper reinforcement plate and the lower reinforcement plate, so that the lead core does not escape, and the lead core and A separation does not occur between the upper plate and the lower plate, and it is possible to appropriately respond to the negative reaction force.

Third, when horizontal displacement occurs, the upper reaction force part and the lower reaction force part are deformed to prevent separation of the lead core or occurrence of a gap, and the design horizontal force can be accurately transmitted by the earthquake isolation bearing of the present invention.

1 is an external perspective view and a plan view (when rubber pads and upper and lower reinforcing plates are circular) of a conventional lead-inserted seismic isolator.
2 is an external perspective view and a plan view (when the rubber pad and the upper and lower reinforcing plates are rectangular) of a conventional lead-inserted seismic isolator.
3 is a cross-sectional perspective view of a conventional lead-inserted earthquake isolation bearing.
4 is a cross-sectional view of a conventional lead-inserted earthquake isolation bearing.
5 is a cross-sectional perspective view of the lead-inserted seismic isolation bearing of the present invention.
6 is a plan view of a lead-inserted seismic isolation bearing of the present invention.
7 is a cross-sectional view (first embodiment) of a lead-inserted earthquake isolation bearing of the present invention.
8 is a cross-sectional view (second embodiment) of a lead-inserted earthquake isolation bearing of the present invention.
9 is a partially enlarged view of a cross-sectional view (first embodiment) of the lead-inserted earthquake isolation bearing of the present invention.
10 is a partially enlarged view of a cross-sectional view (another form of the first embodiment) of the lead-inserted earthquake isolation bearing of the present invention.
11 is a partially enlarged view of a cross-sectional view (second embodiment) of a lead-inserted earthquake isolation bearing of the present invention.
Figure 12 is a partial enlarged view of the cross-sectional view of the lead-inserted earthquake isolation bearing of the present invention, (a) shows an embodiment in which two reaction parts are provided in the first embodiment, and (b) shows the reaction force in the second embodiment It shows an embodiment in which two parts are provided, and (c) and (d) indicate a third embodiment.
13 (conventional) and 14 (the present invention) are for explaining the case where rotational displacement occurs in the upper structure.
15 (conventional) and 16 (the present invention) are for explaining the case where an upward force (reaction force) is generated in the upper structure.
17 (conventional) and 18 (the present invention) are for explaining the case where horizontal displacement occurs in the upper structure.

Hereinafter, embodiments of the present invention will be described in detail so that those skilled in the art can easily practice with reference to the accompanying drawings. However, the present invention may be embodied in many different forms and is not limited to the embodiments described herein. And in order to clearly explain the present invention in the drawings, parts irrelevant to the description are omitted, and similar reference numerals are attached to similar parts throughout the specification. Throughout the specification, when a certain component is said to "include", it means that it may further include other components without excluding other components unless otherwise stated. Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

The lead-inserted seismic isolation bearing with improved side reaction force performance of the present invention is installed between the upper structure and lower structure (foundation, column, pier, abutment) of a bridge or building structure to stably support the upper structure.

As shown in FIGS. 5, 6, and 7, the lead-inserted earthquake isolation bearing 100 of the present invention includes an upper plate 110, a lower plate 120, an upper reinforcing plate 130, a lower reinforcing plate 140, It includes an internal reinforcing plate 150, a rubber pad 160, and a lead core 170.

The top plate 110 forms the upper surface of the lead-inserted earthquake isolation bearing 100 of the present invention, and is used to fix the earthquake isolation bearing 100 to the upper structure 200. When the top plate 110 is fixed to the upper structure 200, a sole plate or other fixing device may be further provided on top of the top plate.

Bolt holes for fastening the upper reinforcing plate 130 with bolts may be formed in the upper plate 110 .

The lower plate 120 forms the lower surface of the lead-inserted earthquake isolation bearing 100 of the present invention, and is used to fix the earthquake isolation bearing 100 to the lower structure 300. When the lower plate 120 is fixed to the lower structure 300, a Marsonley plate or other fixing device may be further provided under the lower plate.

A bolt hole for fastening the lower reinforcing plate 140 with bolts may be formed in the lower plate 120, and an anchor 121 for fixing the lower plate to the lower structure may be provided under the lower plate 120. .

The upper reinforcing plate 130 is provided on top of the rubber pad 160 to come into contact with the lower surface of the upper plate 110 . The upper reinforcing plate 130 may be fastened to the upper plate through bolt holes formed in the upper plate 110 .

The upper surface of the upper reinforcing plate 130 is exposed to the upper part of the rubber pad and comes into contact with the upper plate 110, and the entire side surface and lower surface of the upper reinforcing plate 130 are inserted into the rubber pad.

The lower reinforcing plate 140 is provided under the rubber pad 160 to contact the upper surface of the lower plate 120 . The lower reinforcing plate 140 may be fastened to the lower plate through bolt holes formed in the lower plate 120 .

The lower surface of the lower reinforcing plate 140 is exposed to the lower part of the rubber pad and comes into contact with the lower plate 120, and the entire side surface and upper surface of the lower reinforcing plate 140 are inserted into the rubber pad.

The internal reinforcing plates 150 are provided in plural numbers and are provided inside the rubber pad 160 at regular intervals up and down.

The rubber pad 160 is provided between the upper plate 110 and the lower plate 120 and accommodates an internal reinforcing plate therein.

The lead core 170 is provided to pass through the upper reinforcing plate 130, the rubber pad 160, the inner reinforcing plate 150, and the lower reinforcing plate 140 vertically. To this end, the upper reinforcing plate 130 ), the rubber pad 160, the inner reinforcing plate 150, and the lower reinforcing plate 140 are provided with through-holes so as to communicate vertically, and the lead core is provided to completely adhere to the through-holes.

The lead core 170 provided in the lead-inserted seismic isolation bearing of the present invention has a technical feature in that the lead core 170 includes reaction forces on the upper and lower portions. That is, the lead core 170 of the present invention includes a body portion 171 and a reaction force portion, and the reaction portion includes an upper reaction portion 172 provided at an upper end of the body portion 171 and the body portion 171. It includes a lower reaction force part 173 provided at the lower end.

The body portion 171, the upper reaction force portion 172, and the lower reaction force portion 173 are made of lead and are integrally provided with each other.

The body portion 171 forms the main body of the lead core 170, has a circular cross-section, and has a constant diameter vertically.

The vertical length of the body portion 171 may vary depending on the embodiment, the upper end of the body portion 171 is formed at the same height as the lower surface of the upper reinforcing plate 130, and the lower end of the body portion 171 An embodiment formed at the same height as the upper surface of the lower reinforcement plate 140 (FIGS. 7, 9, 12 (a), (c)) and the upper end of the body portion 171 is the upper reinforcement plate 130 An embodiment in which the lower end of the body portion 171 is formed at a lower position than the upper surface of the lower reinforcing plate 140 (FIGS. 8, 10, 12 (b), (d) ) is possible.

The height of one of the upper reaction force part 172 and the lower reaction force part 173 and the position of the upper and lower ends of the main body can be determined in consideration of the specifications of the upper and lower structures, the specifications of the earthquake isolation bearing, the design load, and the design displacement.

The cross-sectional shapes of the upper reaction force part 172 and the lower reaction force part 173 are circular, and the diameter of the reaction force part is smaller than the diameter of the main body part 171. It can be provided by making it larger.

The shape of making the diameters of the upper reaction force part 172 and the lower reaction force part 173 larger than the diameter of the body part 171 may be implemented in various ways.

As a first embodiment, the diameters of the upper reaction force part 172 and the lower reaction force part 173 gradually increase as they go up and down, respectively (Figs. 7, 9 and 10).

That is, the diameter of the upper reaction force part 172 increases as it goes upward, and the diameter of the lower reaction force part 173 increases as it goes downward, and the upper inclined part 131 inside the upper reinforcing plate 130 By forming and forming the lower inclined portion 141 inside the lower reinforcing plate 140, the upper reaction portion 172 and the upper inclined portion 131 are completely in close contact with the lower reaction portion 173 and the lower inclined portion. The upper reaction portion 172 forms an engaging structure with the upper reinforcing plate 130, and the lower reaction portion 173 forms an engaging structure with the lower reinforcing plate 140 by ensuring that the portion 141 is completely in close contact. do.

The structure of the upper reaction force part 172 and the lower reaction force part 173 and the structure of the upper reinforcement plate 130 and the lower reinforcement plate 140 are the same as in the first embodiment, thereby improving stability against levitation due to overturning moment. It is possible to effectively prevent the separation of the lead core due to rotational displacement, horizontal displacement, and upward displacement.

If the angle between the upper inclined portion 131 and the lower inclined portion 141 and the vertical line is 1 degree or more, the effect can be exhibited, and is preferably 30 degrees or more and 45 degrees or less. The angle at which the effect can be maximized takes into account the height and diameter of the upper inclined portion 131 and the lower inclined portion 141, the thickness of the upper reinforcing plate 130 and the lower reinforcing plate 140, and the size of the negative reaction force. decide by

The first embodiment may be implemented differently depending on the specifications, design load, displacement, etc. of the earthquake isolation bearing, and the heights (h) of the upper reaction force part 172 and the lower reaction force part 173 are respectively upper reinforcing plate 130 And the embodiment in which the thickness of the lower reinforcement plate 140 is the same (FIG. 9) and the heights h of the upper reaction portion 172 and the lower reaction portion 173 are the upper reinforcement plate 130 and the lower reinforcement plate ( 140) is possible.

In addition, in the first embodiment, in addition to the upper inclined portion 131 and the lower inclined portion 141 being formed linearly as above, the diameters of the upper reaction force portion 172 and the lower reaction force portion 173 are respectively vertically It can also be implemented in the form of gradually increasing curvilinearly. In this case, the cross-sectional shape of the upper inclined portion 131 and the lower inclined portion 141 is not a straight line but a curved shape.

In the second embodiment, the diameters of the upper reaction force portion 172 and the lower reaction force portion 173 are constant vertically (Figs. It becomes a right angle C shape). The second embodiment forms the upper stepped portion 132 inside the upper reinforcing plate 130 and forms the lower stepped portion 142 inside the lower reinforcing plate 140 to have the same structure, so that the upper The reaction force part 172 forms an engaging structure with the upper reinforcement plate 130, and the lower reaction force part 173 forms an engaging structure with the lower reinforcement plate 140.

In the second embodiment, since the upper reaction force part and the lower reaction force part must be formed to be hooked to the upper reinforcement plate and the lower reinforcement plate, respectively, the upper end of the main body part 171 is located above the lower surface of the upper reinforcement plate 130 , It is preferable that the lower end of the main body portion 171 is positioned lower than the upper surface of the lower reinforcing plate 140 (FIGS. 11 and 12 (b)).

The upper stepped portion 132 and the lower stepped portion 142 of the second embodiment are at right angles.

In the third embodiment, the diameter of the upper reaction force portion 172 increases and then decreases while going upward, and the diameter of the lower reaction force portion 173 increases and then decreases while going downward (FIG. 12 (c), ( d)).

The third embodiment is an embodiment in which the diameter of the reaction force part changes linearly (Fig. 12 (c)) (that is, the shape of the side cross-sections of the upper reaction force part and the lower reaction force part becomes a protruding wedge shape < shape) and the diameter of the reaction force part This curvilinearly changing embodiment (Fig. 12(d)) (i.e., a curved shape in which the side cross-sectional shapes of the upper reaction force portion and the lower reaction force portion protrude (or become a ⊂ shape) is possible.

The third embodiment may be implemented differently depending on the specifications, design load, displacement, etc. of the seismic isolation bearing. 12 (c)) and the heights of the upper reaction portion 172 and the lower reaction portion 173 are the thicknesses of the upper reinforcement plate 130 and the lower reinforcement plate 140, respectively. A smaller embodiment (Fig. 12 (d)) is possible. 12 (c) and (d) show that two reaction force units are formed, but it is of course possible that only one reaction force unit is provided in the structure of the third embodiment.

In addition, in the first to third embodiments as described above, not only the upper reaction unit 172 and the lower reaction unit 173 can be configured to have a plurality of upper and lower units.

12 (a) shows that the upper and lower reaction parts of the first embodiment are provided, and the upper end of the body part 171 is formed at the same height as the lower surface of the upper reinforcing plate 130, FIG. 12 (b) shows that the second embodiment has two upper and lower reaction units, and the upper end of the main body part 171 is formed above the lower surface of the upper reinforcing plate 130, and FIG. 12 (c) is of the third embodiment. It is shown that two upper and lower reaction units are provided, and the upper end of the body part 171 is formed at the same height as the lower surface of the upper reinforcing plate 130, and FIG. Among the three embodiments, two upper and lower reaction units having a curved diameter of the upper reaction unit are provided, and the upper end of the body part 171 is formed above the lower surface of the upper reinforcing plate 130. 12 illustrates and explains the upper reaction force unit, the lower reaction force unit may be provided symmetrically in the same structure as the upper reaction force unit.

In addition, various embodiments are possible within the scope of the technical spirit of the present invention. For example, in FIGS. 12 (a) and 12 (c), two reaction force units are continuously provided, but may be provided so as to be spaced apart at regular intervals vertically as shown in FIGS. 12 (b) and 12 (d), Three or more reaction force parts may be provided, and the upper end of the body part 171 may be formed above the lower surface of the upper reinforcing plate 130 while having a plurality of reaction force parts of the first and third embodiments. In addition, the first, second, and third embodiments may be mixed with each other, and the cross-sectional shape of the side of the reaction force part may also be changed within the scope of the technical idea of the first to third embodiments.

Hereinafter, the operating mechanism of the lead-inserted seismic isolation bearing with improved reaction force performance of the present invention will be described.

13 and 14 illustrate cases in which rotational displacement occurs in the upper structure, FIG. 13 shows a conventional lead-inserted earthquake isolation bearing, and FIG. 14 shows a lead-inserted earthquake isolation bearing of the present invention. .

In the conventional lead-inserted seismic isolation bearing of FIG. 13, when rotation occurs, the upper plate rotates and the lead core is separated, resulting in a gap between the upper surface of the lead core and the lower surface of the upper plate. 14, the present invention, as shown in FIG. 14, the upper reaction portion 172 forms an upper reinforcing plate 130 and an engaging structure, and the lower reaction portion 173 has a lower reinforcing plate 140 and an engaging structure. As a result, it is possible to prevent the separation of the lead core.

15 and 16 illustrate a case in which an upward force (reaction force) is generated in the upper structure, FIG. 15 shows a conventional lead-inserted earthquake isolation bearing, and FIG. is shown

In the conventional lead-inserted seismic isolation bearing of FIG. 15, when an upward force occurs, the upper plate is lifted up and the lead core is separated, causing a gap (gap) to occur between the upper surface of the lead core and the lower surface of the upper plate. However, as shown in FIG. 16, the present invention has a structure in which the upper reaction part 172 and the lower reaction part 173 are hung inside the upper reinforcement plate 130 and the lower reinforcement plate 140, respectively, so that lead The separation of the core and the negative reaction force can be prevented.

17 and 18 illustrate cases in which horizontal displacement occurs in the upper structure, FIG. 17 shows a conventional lead-inserted earthquake isolation bearing, and FIG. 18 shows a lead-inserted earthquake isolation bearing of the present invention. .

In the conventional lead-inserted seismic isolation bearing of FIG. 17, when a horizontal force is generated, the lead core is separated according to the horizontal movement of the top plate, and it is difficult to accurately transmit the design horizontal force. However, the present invention is similar to that shown in FIG. Likewise, the upper reaction force part 172 and the lower reaction force part 173 are hung inside the upper reinforcement plate 130 and the lower reinforcement plate 140, respectively, so that the separation of the lead core can be prevented and the design horizontal force can be reduced. be able to convey accurately.

Although the present invention has been described with reference to the embodiments shown in the drawings, this is only exemplary, and those skilled in the art will understand that various modifications and equivalent other embodiments are possible therefrom. Therefore, the true technical protection scope of the present invention should be determined by the technical spirit of the appended claims.

100. Seismic Isolation Support
110. Top plate
120. Lower plate 121. Anchor
130. Upper Reinforced Plate
131. Upper ramp
132. Upper stepped part
140. Lower reinforcement plate
141. Lower slope
142. Lower chin part
150. Internal reinforcement plate
160. Rubber pad
170. Lead core
171. Body part
172. Upper Reaction Force
173. Lower Reaction Force
h. Height of one upper reaction force part
10. Conventional seismic isolation bearings
11. Top plate
12. Lower plate
13. Upper reinforcement plate
14. Lower reinforcement plate
15. Internal reinforcement plate
16. Rubber pad
17. Lead core
200. Superstructure 300. Substructure

Claims (10)

In the earthquake isolation bearing installed on the lower structure to support the upper structure,
An upper plate 110 forming an upper surface of the earthquake isolation support;
A lower plate 120 forming the lower surface of the earthquake isolation support;
a rubber pad 160 provided between the upper plate 110 and the lower plate 120;
an upper reinforcing plate 130 provided on top of the rubber pad 160 to contact the lower surface of the upper plate 110;
a lower reinforcing plate 140 provided under the rubber pad 160 to contact the upper surface of the lower plate 120;
Internal reinforcing plates 150 provided at regular intervals on the inside of the rubber pad 160;
It includes a lead core 170 provided to be in close contact while penetrating the upper reinforcing plate 130, the rubber pad 160, the inner reinforcing plate 150, and the lower reinforcing plate 140 vertically,
The lead core 170 includes a body portion 171; an upper reaction force portion 172 provided at an upper end of the main body portion 171; It includes a lower reaction force part 173 provided at the lower end of the main body part 171,
The body part 171, the upper reaction force part 172 and the lower reaction force part 173 are made of lead and provided integrally, and have a circular cross-sectional shape,
The diameter of the body portion 171 is constant up and down,
The diameters of the upper reaction force part 172 and the lower reaction force part 173 are provided larger than the diameter of the main body part 171,
A structure is formed in which the upper reaction force part 172 and the lower reaction force part 173 are caught on the upper reinforcement plate 130 and the lower reinforcement plate 140, respectively.
Lead-inserted seismic isolation bearing with improved anti-reaction performance. delete delete According to claim 1,
The diameter of the upper reaction force portion 172 increases upward,
Characterized in that the diameter of the lower reaction force portion 173 increases downward
Lead-inserted seismic isolation bearing with improved anti-reaction performance. According to claim 1,
Characterized in that the diameters of the upper reaction force portion 172 and the lower reaction force portion 173 are constant
Lead-inserted seismic isolation bearing with improved anti-reaction performance. According to claim 1,
The diameter of the upper reaction force portion 172 increases and then decreases as it goes upward,
Characterized in that the diameter of the lower reaction force portion 173 increases and then decreases while going down
Lead-inserted seismic isolation bearing with improved anti-reaction performance. According to claim 4 or 6,
The upper end of the body portion 171 is located at the same height as the lower surface of the upper reinforcing plate 130 or higher than the lower surface of the upper reinforcing plate 130,
Characterized in that the lower end of the body portion 171 is located at the same height as the upper surface of the lower reinforcing plate 140 or lower than the upper surface of the lower reinforcing plate 140
Lead-inserted seismic isolation bearing with improved anti-reaction performance. According to claim 5,
The upper end of the body portion 171 is located above the lower surface of the upper reinforcing plate 130,
Characterized in that the lower end of the body portion 171 is located lower than the upper surface of the lower reinforcing plate 140
Lead-inserted seismic isolation bearing with improved anti-reaction performance. The method of any one of claims 1, 4 to 6 and 8,
Characterized in that the upper reaction force part 172 and the lower reaction force part 173 are provided in singular or plural numbers, respectively.
Lead-inserted seismic isolation bearing with improved anti-reaction performance. According to claim 7,
Characterized in that the upper reaction force part 172 and the lower reaction force part 173 are provided in singular or plural numbers, respectively.
Lead-inserted seismic isolation bearing with improved anti-reaction performance.

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