KR200377338Y1 - Structure for earthquake-proof of a bridge pier - Google Patents

Abstract

The object of the present invention is to provide a seismic reinforcing structure for piers that can minimize collapse due to lack of flexural strength of the piers by using a weld-free pressure plate during seismic reinforcement of underwater piers and general piers.

The seismic reinforcing structure of the piers according to the present invention for achieving the above object is located on the lower outer surface of the piers and acupressure plate attached while wrapping the piers; An H beam fixedly installed on an upper portion of the piers while supporting a lower end of the acupressure plate; A steel bar for fixing the H beam to the upper base; A bracket fixedly installed between the H beam and the steel rod; A mortar that is cured and poured between the piers and the pressure plate; It is characterized by consisting of a concrete that is cured so that a certain portion is buried over the pressure plate and steel rods and brackets installed on the top of the base and the outside of the piers.

Description

Structure for earthquake reinforcement of bridge piers {Structure for earthquake-proof of a bridge pier}

The present invention relates to a structure for seismic reinforcement of bridge piers, and more particularly, to a structure for seismic reinforcement of piers intended to minimize the collapse of bridge piers by using a non-welding pressure plate in the piers during seismic reinforcement of underwater piers and general piers.

In general, the pier damage caused by earthquakes is mostly due to lack of strength.

Prior to the 1970s, the pier design criteria based on the allowable stress design method were designed to anticipate only small horizontal accelerations.

It is now known that lateral acceleration of more than 1g can occur in bridge piers, but the design before 1971 expected the design reference value of 0.06g, so many piers currently lack flexural strength.

If so, consider how much flexural strength the bridges designed with only small seismic forces are considered.

The interaction between the axial and flexural strengths of bridge piers and general seismic designs is as follows.

As can be seen from the above figure, the relationship between axial force and flexural strength is linear in the pier of general design, and about 45% of seismic design pier under the condition that axial force is not applied is about 30% under the condition that the bending moment is not applied. You can see the history of the.

In general, as the axial force increases, the flexural strength decreases, but for the axial force acting on a general pier, the general pier only exhibits the flexural strength of 1/3 to 1/4 of the seismic bridge design.

Therefore, in the case of general pier with a fine earthquake, there is a condition that the pier can collapse without special reinforcement.

In addition, if the lap joint is made on the pier reinforcing bar on the upper part of the foundation, or if sufficient overlap joint length is not secured, it may cause the piercing collapsing. If the anchorage is lost, core concrete collapse due to band reinforcement may occur rapidly, resulting in bending failure of the piers.

Under these conditions, the fracture is a failure due to lack of bending of the pier stiffness, and the pier without seismic reinforcement is deteriorated due to the collapse of the pier due to the weight of the superstructure.

In order to improve the toughness and shear strength of flexural failure of bridge piers or to improve the seismic resistance of overlapping joints, the steel plate lining method is typically implemented.

This method is processed by bending two steel plates (3) with a radius slightly larger than the pier (3) for the circular section piers (3) and fixing them with anchor bolts around the piers (3), and after the field welding in the longitudinal direction Grout the gap between 3) and the iron plate (3).

Usually, the ratio of the diameter of the piers 3 to the thickness of the steel plate 3 is generally 100: 1 to 200: 1. The steel plate 3 provides bending force in the plastic hinge region and is sheared according to the truss shear mechanism. It serves as a good strip reinforcing bar (10) to increase the strength. Moreover, the method of bonding the iron plate 3 with an epoxy resin and lining in a rectangle is also performed.

Here, in the conventional iron plate lining method, as shown in Figure 1, using the iron plate 6 to the upper portion of the foundation (2) to the upper portion of about 4m to the iron plate (6) after the existing piers ( As a method of seismic reinforcing the pier 3 by filling between 3) and the iron plate 6 with non-contraction mortar, there are the following problems.

First, in order to increase the flexural strength and the shear strength, the steel plate 6 has a thick thickness t, which is inconvenient in construction, and it is difficult to fix the steel plate 6 around the circular pier 3.

Second, in the field of welding two round iron plate (6) in the field, the quality of the welded part is degraded, and the use of the paddle plate (3) to the site where the iron plate (6) overlaps is not easy, the butt weld site is broken There is a concern.

Third, there is a risk of damaging the existing pier (3) by excessively perforating the anchor bolt to fix the iron plate (6) to the existing pier (3).

Fourth, it is not easy to pour the non-shrink mortar between the iron plate (6) and the existing piers (3), it is impossible to confirm whether the non-shrink mortar is surely filled by manpower casting.

In addition, in addition to the conventional iron plate lining method described above, the seismic reinforcement structure of the piers and its construction method have been filed with the patent application 2001-20031.

2 is a perspective view showing a conventional pier seismic reinforcement structure, Figure 3 is a cross-sectional view showing a conventional pier seismic reinforcement structure, Figure 4 is a cross-sectional view taken along line A-A of FIG.

As shown in these figures, the seismic reinforcement structure of a conventional pier includes a support plate (1) wrapped around the pier (3) attached to the lower outer surface of the pier (3); A restraining ring 4 installed outside the support plate 1 and spaced apart from the support plate 1; An L-shaped plate 8 which is covered by a lower portion of the constraining ring 4 supported by a plurality of anchor bolts 9 protruding from the foundation 2 below the piers 3; A reinforcing bar (5, 10) positioned between the support plate (1) and the restraining ring (4) and having its lower end embedded in the foundation (2); And it is characterized by consisting of the expanded concrete (7) is placed between the support plate (1) and the restraint ring (4) to apply prestress in the transverse direction.

In addition, the conventional method of constructing a seismic reinforcing structure of a piers includes the steps of attaching a thin plate-like support plate (1) to a lower outer peripheral surface of a piers (3) installed upright on the ground to support a top plate of a bridge; Drilling a hole in the foundation (2) formed under the bridge (3), inserting and fixing a plurality of reinforcing bars (5), and reinforcing bars (5) to reinforce the band reinforcing bars (10); Attaching the octagonal L-shaped plate (8) to the base (2) using an anchor bolt (9); Mounting a restraint ring (4) in the L-shaped plate (8); It is characterized in that it consists of a step of curing by pouring a high-performance expanded concrete (7) inside the restraining ring (4).

The seismic reinforcement structure and construction method of the conventional bridge piers having the configuration as described above have the advantage that can be effectively applied because the construction is simple without damaging the existing piers (3) can be shortened air In addition, by providing a prestress at the bottom of the pier (3), the integration with the existing pier (3) is strengthened, and the existing pier (3) is constrained by the prestress of the restraint ring (4) to improve the reinforcement capacity Since the seismic reinforcement structure of the pier (3) facing the earthquake has an advantage that is suitable.

However, the conventional seismic reinforcement structure and its construction method having the advantages as described above have the following problems.

First, as shown in Figs. 2 to 4 to the existing foundation (2) and the pillar, when integrated using the support plate (1) when the earthquake occurs and a large angle of rotation in the pier (3), L-shaped plate (8) ) And the base 2 are in contact with each other, the compressive force is applied to the L-shaped plate 8, there is a problem that the reinforcing effect is lost and there is a fear of breaking.

Second, in order to generate flexural strength of the pier (3), it is required to secure a sufficient anchoring length to sufficiently exhibit the strength of the reinforcing bar (5), but to exceed the existing pier (3) to secure the anchoring length of the reinforcing bar (5) There is a problem that needs to be drilled.

Third, the reinforcing bar 5 should be fixed to the foundation 2 more accurately in the axial reinforcing bar 5 than the transverse band reinforcing bar 10, but there is a problem that it is difficult to fix the axial reinforcing bar 5 to the foundation (2).

Fourth, when the seismic reinforcement of the pier (3) by reinforcing the reinforcing bar (5), the plastic hinge must be securely placed to have a flexural strength or shear strength reinforcement effect.

Fifth, in the pier (3) of the circular cross section, the binding effect is increased only by winding the reinforcing bar (10) or the spiral reinforcing bar at a narrow interval. Therefore, the reinforcing bar (5) should be closely arranged, and the column section of the pier (3) may be elliptical In the case of a non-circular cross section, that is, a rectangular cross section, the axial rebar 5 is easily buckled at the central portion of each surface, and it is difficult to effectively restrain the reinforcing bar 5 only near the right corner.

Sixth, in order to restrain the reinforcing bars 5 outside the right corner, the corners of the piers 3 should be cut off and corner bars should be placed in the 45 ° direction. How should be done, but the construction cost is high, and the middle restraint rebar is also difficult to reinforce because the hook must be made at the next end through the hole.

Accordingly, the present invention was devised to solve the problems described above, the pier to minimize the collapse due to the lack of bending strength of the pier by using the no-welding pressure plate during seismic reinforcement of underwater pier and general pier. The purpose of the present invention is to provide a seismic reinforcing structure.

The seismic reinforcing structure of the piers according to the present invention for achieving the above object is located on the lower outer surface of the piers and acupressure plate attached while wrapping the piers; An H beam fixedly installed on an upper portion of the piers while supporting a lower end of the acupressure plate; A steel bar for fixing the H beam to the upper base; A bracket fixedly installed between the H beam and the steel rod; A mortar that is cured and poured between the piers and the pressure plate; It is characterized by consisting of a concrete that is cured so that a certain portion is buried over the pressure plate and steel rods and brackets installed on the top of the base and the outside of the piers.

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

5a to 5e is a process diagram showing a state in which the seismic reinforcement structure of the piers according to the present invention is installed in a general piers, Figure 6 is a perspective view showing acupressure plate of the seismic reinforcement structure of the piers according to the present invention.

As shown in these figures, the seismic reinforcing structure (S) of the piers according to the present invention is located on the lower outer surface of the piers 20 and the pressure plate 30 is attached while wrapping the piers 20; An H beam 50 fixedly installed on an upper portion of the foundation 40 of the piers 20 while supporting the lower end of the pressure plate 30; A steel bar (60) for fixing the H beam (50) on the base (40); A bracket 70 fixedly installed between the H beam 50 and the steel bar 60; Mortar (80) to be cured between the pier 20 and the pressure plate (30); It is composed of a concrete 90 that is poured into a certain portion is buried over the pressure plate 30 and the steel bar 60 and the bracket 70 installed on the upper portion of the base and the pier 20.

That is, the structure (S) for seismic reinforcement of the piers according to the present invention organically coupled to the pressure plate 30, H beam 50, steel rod 60, bracket 70, mortar (80) and concrete (90) It is a structure made up of.

Here, the acupressure plate 30 is formed with a saw blade 34 having a predetermined length and pitch on the iron plate 32 on one side and the iron plate 32 on the other side, the saw blade 34 on the one side and the saw blade 34 on the other side. This is the structure combined with each other.

Since the pressure plate 30 is a structure in which the saw blades 34 are formed on the iron plate 32 and the iron plate 32 on the other side and are coupled to each other, the pressure plate 30 is not directly welded to the piers 20 without welding in the field. This is to allow construction.

In addition, the pressure plate 30 is to ensure that the quality of the steel plate 32 of one side and the iron plate 32 of the other side is not affected by the weather or on-site conditions.

On the other hand, the H-beam 50 is installed on the upper portion of the base 40 and the lower portion of the piers 20 using the H-beam 50, which is specially manufactured, serves to reinforce the lower portion of the piers 20.

In addition, the steel bar 60 and the bracket 70 to install the bracket 70 on the upper surface of the H beam 50 to fix the H beam 50 is installed on the base 40, the bracket ( 70 is a member connecting the base 40 by inserting the center of the steel rod 60 through the center.

Therefore, the H beam 50, the steel bar 60 and the bracket 70 do not need to use the reinforcing bar assembly or anchor bolts required for the seismic reinforcement of the conventional piers 20.

On the other hand, the mortar 80 is used for the general piers 20 and the underwater piers 20, in the general piers 20 is constructed using a common mortar between the piers 20 and the pressure plate 30 In the underwater piers 20, mortar 80 is used which is separated from water.

Structure construction method for seismic reinforcement of piers according to the present invention made of a configuration as described above is the step of excavating a predetermined portion of the base 40 located on the lower portion of the piers (20); Installing the H beam 50 on the base 40 using the steel rod 60 and the bracket 70; Integrally fixing and connecting the acupressure plate 30 assembled to the bracket 70; Placing and curing the mortar 80 between the pier 20 and the pressure plate 30; Seismic general piers (20) by sequentially performing the curing step by pouring concrete 90 to a predetermined height on the H beam 50, steel rod 60 and bracket 70 installed on the base 40 To reinforce.

That is, in the construction method for the seismic reinforcement structure of the piers according to the present invention after excavating a predetermined portion to the upper portion of the base 40 to remove the soil of the existing piers 20, the special H beam on the base 40 50 is installed using the steel rod 60 and the bracket 70, and the pressure plate 30 is connected to the bracket (70).

At this time, when the piers 20 do not have water, the rod 40 and the brackets are formed on the upper surface of the H beam 50 after reinforcing the portion of the base 40 with the H beam 50 to ensure the seismic reinforcement. After the 70 is installed, the bracket 70 is integrated with the acupressure plate 30, and thereafter, when a single mortar 80 is integrated with the existing piers 20, the seismic reinforcement is completed. do.

After this process is completed, the foundation 40, the H beam 50 and the steel rod 60 and the mounting portion of the concrete 90 by placing the concrete 90 to the height of about 2 to 3m to pier 20 The foundation 40 is made of perfect reinforcement.

Hereinafter, the reinforcement of the underwater bridge piers 20 will be described.

Figure 7a to 7f is a process diagram showing a state of installing the seismic reinforcement structure of the piers in the underwater piers according to the present invention.

As shown in these figures, the construction method for the seismic reinforcement structure of the piers according to the present invention after excavating a predetermined portion of the foundation 40 located in the lower portion of the piers 20, the upper portion of the foundation 40 Assembling and installing the acupressure plate 30 on the outer side of the pier 20 connected, and placing and curing the non-separable mortar 80 between the pier 20 and the acupressure plate 30 sequentially Seismic reinforcement of the underwater piers 20.

Therefore, the present invention does not require additional facilities to block the water piers 20 when reinforcing, the plate 32 and the chisel plate 34 of the iron plate 32 in the water firmly bite each other in the field The construction can be performed without welding, the quality of the steel plate 32 of the pressure plate 30 is not affected by the weather or on-site conditions, and easily pier (20) by using a mortar (80) that is separated from the water. ) Has the effect of reinforcing.

In addition, the present invention is excellent in the seismic effect, there is little excessive assembly or damage to the existing piers 20 and the base 40, by installing the pressure plate 30 on the piers 20 and the base 40 without difficulty , Reinforcement of the piers 20 is possible, the construction has a simple action effect.

As described above, the seismic reinforcing structure of the piers according to the present invention has the following effects.

First, the present invention has the advantage that it can be installed without welding in the field acupressure plate meshed with the saw blade in the water without the need of additional facilities in the water.

Second, the present invention has the advantage that the quality of the steel plate seam of the shiatsu plate is not affected by the climate or field conditions.

Third, the present design has the advantages of the conventional anchor pier or less damage to the pier as the pier is less possible to reinforce the pressure plate without difficulty in the pier, there is an advantage that the construction is easy.

1 is an exemplary view showing a conventional iron plate lining reinforcement structure,

Figure 2 is a perspective view showing a conventional pier seismic reinforcement structure,

3 is a cross-sectional view showing a conventional pier seismic reinforcement structure,

4 is a cross-sectional view taken along the line A-A of FIG.

5a to 5e is a process diagram showing a state of installing a structure for the seismic reinforcement of the piers in accordance with the present invention,

Figure 6 is a perspective view showing acupressure plate of the seismic reinforcement structure of the piers according to the present invention,

Figure 7a to 7f is a process diagram showing a state of installing the seismic reinforcement structure of the piers in the underwater piers according to the present invention.

Explanation of symbols on the main parts of the drawing

1: support plate 2: foundation

3: pier 4: constrained ring

5: rebar 6: iron plate

7: expanded concrete 8: L-shaped plate

9: Anchor Bolt 10: Band Reinforcing Bar

20: pier 30: pressure plate

32: iron plate 34: saw blade

40: base 50: H beam

60: steel bar 70: bracket

80: mortar 90: concrete

S: Structure for seismic reinforcement of piers

Claims (2)

A pressure plate 30 positioned on the lower outer surface of the piers 20 and attached to surround the piers 20; An H beam 50 fixedly installed on an upper portion of the foundation 40 of the piers 20 while supporting the lower end of the pressure plate 30; A steel bar (60) for fixing the H beam (50) on the base (40); A bracket 70 fixedly installed between the H beam 50 and the steel bar 60; Mortar (80) to be cured between the pier 20 and the pressure plate (30); Characterized in that it consists of a concrete 90 is placed on the upper portion of the base 40 and the outer side of the pier 20, the pressure plate 30 and the steel rod 60 and the bracket 70 is embedded in a certain portion to be buried. Structure for seismic reinforcement of piers. The method of claim 1, The pressure plate 30 is formed with a saw blade 34 having a predetermined length and pitch on the iron plate 32 on one side and the iron plate 32 on the other side, the saw blade 34 on the one side and the saw blade 34 on the other side mutually Structure for seismic reinforcement of piers, characterized in that the engagement.