KR20100102907A - Method for constructing bridge piers by using precast concrete segments - Google Patents

Abstract

PURPOSE: A method for construction a pier using precast segments is provided to secure enough strength in a connection part between segments and to rapidly perform a work. CONSTITUTION: A method for construction a pier using precast segments is as follows. A reinforcing bar(130) for supplying axial force is extended from a pier foundation. Precast pier segments(P) are inserted into the extended reinforcing bar. Axial force 0.3 MPa is applied to the reinforcing bar. The precast pier segments are coupled by injecting and hardening epoxy bond. Multiple precast pier segments are piled up at a desired height.

Description

Pier construction method using precast segment {METHOD FOR CONSTRUCTING BRIDGE PIERS BY USING PRECAST CONCRETE SEGMENTS}

The present invention relates to a method for constructing a pier prefabricated using precast pier segments, more specifically, by stacking the precast pier segments manufactured in the factory on the pier foundation that is cast in the field for rapid construction of downtown bridges The present invention relates to a bridge construction method using precast segments that can secure sufficient working speed and strength at the segment connection.

In general, bridges supporting bridges are constructed mainly as concrete structures as compression members. In recent years, the construction of bridges in urban centers has been increasing, and such bridges in urban centers are increasingly being built in high-altitude bridges as roads become more complex.

As such, in the construction of bridges in urban areas, the bridges supporting the bridges have a lengthening structure. In the conventional method of constructing such bridges, a formwork mainly made of steel slip foam is installed, and reinforcing bars are provided inside. After placing the concrete at a predetermined height interval from the ground surface, the slip foam is moved upward to increase the height of the pier.

However, such a conventional method can be poured after the concrete poured at a certain height is cured, it takes a lot of time for the bridge construction, which is an important cause to increase the construction period of the entire bridge. Therefore, in the art, a situation that requires a great improvement of the construction method for the rapid construction of piers.

The present invention is to solve the above-mentioned conventional problems, the object is to laminate the precast pier segments produced in the factory in multiple stages on the piling foundation to be cast in the field for rapid construction of downtown bridges, between the bridge segments The connection is made through epoxy bonds to provide a bridge construction method using precast segments to ensure fast working speeds and sufficient strength and performance at segment connections.

In order to achieve the above object, the present invention is configured as follows.

Pier construction method using a precast segment according to the present invention is made of a concrete structure with reinforced reinforcement in the inside, the upper part of the column portion corresponding to one segment of the columnar shape integrally projecting, the column portion in the center circular space An additional part is formed, and a plurality of main reinforcing hole holes are formed along the outer circumference thereof, and a piling base part configured to protrude from the upper side of the column part is provided with an axial force-improving reinforcing bar with a threaded part formed at an upper end thereof; A new axial force reinforcing bar is extended to the upper side through a coupler on top of each of the axial force reinforcing bars of the column, and each of the main reinforcing bars is capped to cover the hole, and the cap is inserted into the main reinforcing hole and the cylinder. A disc portion having a diameter larger than that of the portion to block each of the reinforcing bar holes, and applying an epoxy bond to an upper surface of the pillar portion; Remove the caps from the pillars, and then insert a new first precast pier segment into the upper side of the axially extending reinforcing bar, insert the supporting plate into the axially reinforcing bar, and then screw the nut. Tighten the nuts for sufficient attachment between the segments using a torque wrench and pull the axial reinforcing bars to introduce an axial force of at least 0.3 MPa (3 kg / cm ² ), the epoxy between the column and the first precast pier segment. Left to cure for at least 1 hour; A new axial force reinforcing bar is extended to the upper side through a coupler on each of the first precast pier segments, and each main bar hole is capped to cover the hole, and an epoxy bond is applied to the upper surface of the first precast pier segment. Then remove the caps respectively, insert a new second precast pier segment into the upper side of the extended axial reinforcing bar, introduce axial force into the axial reinforcing bar, and over the first precast pier segment. Installing a second precast pier segment; On the second precast pier segment, a plurality of precast pier segments are sequentially stacked and installed at the desired height in the same process as the installation process of the second precast pier segment. Inserting them and then fixing them with mortar, and filling the circular space with concrete including reinforcing bars; And installing and fixing a coping portion on the cast iron protruding over the final precast pier segment. When constructing a downtown bridge through such a process, it is possible to secure a fast working speed and sufficient strength and performance at the segment connection.

And the bridge construction method using the precast segment according to the present invention, the interior of the reinforcement is made of a reinforced concrete structure, the upper part of the plurality of cast steel to maintain a constant interval in a circular shape is formed, the circular Constructing a pier foundation part in which an axial force reinforcing steel bar is formed at an upper end of the main reinforcing bar; Epoxy bond is applied to the upper surface of the pier foundation, and a new first precast pier segment is inserted into the upper side of the reinforcing bar and the axial force reinforcing bar, wherein the first precast pier segment has a circular space portion in the center thereof, An axial force-bearing hole and a plurality of main-steel reinforcing holes are formed on the outside thereof, and are coupled to the main reinforcing steel and the axial force-reinforcing bars. Tighten the nut for sufficient attachment and pull the axial reinforcing bar to introduce an axial force of at least 0.3 MPa (3 kg / cm ² ) and allow it to stand for at least 1 hour for epoxy curing between the column and the first precast pier segment. step; A new axial force reinforcing bar is extended to the upper side through a coupler on the first precast pier segment, and an epoxy bond is applied to the upper surface of the first precast pier segment, and then the upper part of the main steel and the axial force reinforcing bar. Inserting a new second precast pier segment into the side, and installing a second precast pier segment in the same process as the first precast pier segment; On the second precast pier segment, a plurality of precast pier segments are stacked and installed at a desired height in the same process as the installation process of the second precast pier segment, and when the desired height is reached, the respective precast pier segments Filling and fixing mortar in the main reinforcing hole, and filling the circular space with concrete including reinforcing bars; And installing and fixing a coping portion on the cast iron protruding over the final precast pier segment.

Therefore, when constructing downtown bridges, it is possible to secure fast working speed and sufficient strength and performance at the segment connection.

According to the pier construction method using the precast segment according to the present invention, the precast pier segments manufactured in the factory are laminated in multiple stages at the foundation of the pier to be installed in the field for rapid construction of downtown bridges, but the connection between the pier segments is applied with axial force. This is achieved through epoxy bonds in the state, and through cast reinforcing bars and concrete-filled layers to ensure fast working speeds and sufficient strength and piercing performance at segment connections.

Therefore, according to the present invention can reduce a lot of work time for the bridge construction work it is possible to achieve a significant reduction in construction cost through shortening the air of the bridge construction work.

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

Pier construction method 100 using the precast segment according to the present invention, as shown in Figure 1a, first is the step of constructing the bridge foundation 110.

In the step of constructing the pier foundation 110, the pier foundation 110 is made of a concrete structure in which reinforcing bars 112 are arranged inside, and the column 120 having a columnar shape protrudes from the upper portion thereof. This pillar portion 120 has a size corresponding to one precast pier segment P of the precast concrete segment, as described later.

The pillar portion 120 has a circular space portion 122 is formed in the center, a plurality of the main reinforcing hole 126 is formed along the outer circumference, the upper side of the pillar portion 120 in the upper male thread portion The axial force-improving rebar 130 having the 130a formed therein is formed to protrude.

Meanwhile, in the step of constructing the pier foundation 110 as described above, the pier foundation 110 and the pillar 120 may be separately separated and constructed to form a single structure.

That is, as shown in Figure 1b, by inserting the pillar portion 120 on the axial force-improving reinforcement 130 of the bridge foundation 110 made of a reinforced concrete structure, the pillar portion 120 is A circular space portion 122 is formed in the center, and a plurality of main reinforcing bar holes 126 are formed along the outer circumference thereof, and the axial force applying holes of the pillar part 120 formed to coincide with the axial force applying bars 130. Insert (132) to combine.

In the case of such a coupling structure, the non-condensed concrete 134 is applied between the pier foundation 110 and the pillar 120 to be bonded to each other.

That is, the axial force imparting holes 132 of the column part 120 are fitted on the axial force imparting reinforcement bars 130 of the pier foundation 110 to be coupled to each other, and between the pier foundation 110 and the column part 120. There is to bond through the non-contraction concrete (134).

In addition, the present invention may be a step of constructing the pier foundation 110 differently from the above, as shown in Figure 1c, which is on the upper surface of the pier foundation 110 made of a reinforced concrete structure A cylindrical groove 138 is formed, and the axial force applying reinforcement 130 is positioned in the cylindrical groove 138. In addition, a circular space 122 is formed at the center on the axial force applying reinforcement 130, and a pillar portion 120 having a plurality of main reinforcing hole holes 126 formed along an outer circumference thereof is coupled to the pillar portion 120. ) Is provided with a axial force imparting hole 132 corresponding to the axial force reinforcing bar 130 and is fitted to the axial force reinforcing bar 130.

In addition, non-condensed concrete 134 is applied between the cylindrical groove 138 and the pillar portion 120 of the pier foundation 110 to bond these coupling surfaces integrally with each other.

In the structure of the pier foundation 110 as described above, the axial force imparting reinforcement 130 may be formed in a structure arranged at equal intervals in four directions on all four sides of the upper surface of the pier foundation 110. In this way, if the circumferentially equal intervals are arranged at four places on the upper surface of the pier foundation 110, as described later, a plurality of precast pier segment (P) on the upper side of the pier foundation 110 In the case of stacking one by one and applying an axial force for each precast pier segment P installation, the axial force can be uniformly applied over the entire surface of the precast pier segment P.

And the pier construction method 100 using the precast segment according to the present invention, as shown in Figure 2a to the upper pillar portion 120 of the pier foundation 110, as a prefabricated new precast pier segment (P) To this end, for this purpose, the new axial force reinforcing bars 130 are extended to the upper side through the couplers 150 on the upper ends of the axial force reinforcing bars 130 of the pillar 120, respectively.

In such a process, the coupler 150 may use a commonly used rebar coupler. For example, an internal thread part 152 may be formed therein, and an axial force reinforcing bar may be respectively provided on the internal thread part 152. The male screw portion 130a of the 130 may be coupled to extend in the vertical direction. Alternatively, both ends of the reinforcing bar having an enlarged diameter may be inserted into the sleeve (not shown), and the non-contraction mortar (not shown) may be filled and cured, and may be integrally connected to each other. The present invention includes a coupler 150 of such various structures and is not limited to a specific structure.

Then, after extending the axial force applying reinforcement 130, each of the main reinforcing hole 126 of the column portion 120 is capped by covering the hole with a cap 160, the cap 160 is shown in Figure 2b As described above, a cylindrical portion 162 inserted into the main reinforcing hole 126 and a disc portion 164 having a larger diameter than the cylindrical portion 162 are provided to block each of the main reinforcing hole 126.

In this state, the epoxy bond 170 is applied to the upper surface of the pillar part 120, and then the caps 160 are removed from the pillar part 120, respectively. Insert a new first precast pier segment P1 into the upper side of 130).

In this process, the cap 160 prevents the epoxy bond 170 from flowing into the cast iron hole 126 so that an operator can easily and quickly apply the epoxy bond 170 to the upper surface of the pillar 120. By preventing the main reinforcing bar holes 126 from being blocked by the epoxy bond 170, the main reinforcing bar 200 can be smoothly inserted into the main reinforcing hole 126 afterwards.

The first precast pier segment P1 coupled to the pillar 120 to which the epoxy bond 170 is applied as described above, and the second precast pier segment P2 positioned at an upper side thereof and positioned at a lower portion thereof. The pillars 120 are fabricated by a match cast method in the factory to ensure accurate positioning between the segments and mating at the matched positions. Thus, these precast pier segments P fit precisely into each other on the job site.

In addition, these precast pier segments (P) as shown in Figure 2c, to form a connection groove 182 to the segment (P) in the upper corner, and to form a connection projection 184 in the lower corner In the stacking construction, the connecting projection 184 of the upper precast pier segment P is coupled to the connecting groove 182 of the lower side precast pier segment P so that accurate and rapid positioning of the segment P is achieved. It is possible.

Here, the position of the connection groove 182 and the connection protrusion 184 may be differently positioned up and down. That is, the connection protrusion 184 is formed at the upper edges of the precast pier segments P, and the connection grooves 182 are formed at the lower edges of the precast pier segments P, so that they can be easily combined at a predetermined position. It is all inclusive.

Then, after the first precast pier segment P1 is inserted into the upper portion of the pillar 120, the axial force is applied through the reinforcing rod 130 for axial force, and the pillar 120 and the first precast pier segment are provided. (P1) will be firmly combined with each other.

In this case, the support plate 186 is inserted into the reinforcement rod 130 for axial force, and then the nut 190 is screwed to the male screw portion 130a formed at the end of the reinforcement rod 130 for axial force applying on the support plate 186. Combine. In this state, when the nut 190 is tightened using a torque wrench (not shown), a tension force is applied to the reinforcing bar 130 for the axial force through the nut 190 which is rotated by the torque wrench, and the pillar part 120. And the first precast pier segments P1 are pulled together and pressed together.

In this case, the axial force applying reinforcement 130 is preferably introduced to the axial force of 0.3 MPa (3 kg / cm ² ), in this state the column portion 120 and the first precast pier segment (P1) Allow at least 1 hour to cure the epoxy between

When the torque wrench is removed from the reinforcing bar 130 by releasing the torque wrench after being left for a predetermined time as described above, the pillar part 120 and the first precast pier segment P1 are firmly connected to each other.

Next, second precast pier segments P2 are stacked and connected to an upper portion of the first precast pier segment P1. This method is similar to the method of connecting the pillar portion 120 and the first precast pier segment (P1).

That is, the new axial force reinforcing bars 130 extend upward through the couplers 150 on the first precast pier segment P1.

Each main reinforcing hole 126 is covered with a cap 160 to cover the hole, and an epoxy bond 170 is applied to the upper surface of the first precast pier segment P1. In this case, the epoxy bond 170 is not introduced into the axial force applying hole 132.

In addition, after the application of the epoxy bond 170 is completed as described above, the cap 160 is removed from the main reinforcing hole 126, respectively, and a new second precast pier to the upper side of the axial force reinforcing bar 130 extended in length. Insert segment P2.

The second precast pier segment P2 is also manufactured in a match cast method at the factory, and thus fits well in the first precast pier segment P1.

In addition, the axial force is introduced through the axial force applying reinforcing bars 130 protruding to the upper portion of the second precast pier segment P2. In this process, the axial force applying reinforcing bars 130 are supported as shown in FIG. 2A. 186 and nut 190 are assembled, and the nut 190 is rotated through a torque wrench (not shown) to impart a predetermined axial force to the axial force reinforcing bar 130, and then onto the first precast pier segment P1. The second precast pier segment P2 is coupled to each other.

Even in such a case, the first precast pier segment P1 and the second precast pier segment P2 are firmly bonded to each other through the epoxy bond 170.

The second precast pier segment P2 of the same size and size is sequentially stacked on the upper side of the second precast pier segment P2.

As described above, the installation process of the second precast pier segment P2 is the same as the installation of the second precast pier segment P2 on the first precast pier segment P1. The precast pier segments (P) are laminated to the desired height.

In addition, when the precast pier segments P are stacked in this manner to reach a desired height, as shown in FIG. 3, the main reinforcing bars 200 are inserted into the main reinforcing bar holes 126, and then the main reinforcing bar holes 126. Fixed in the mortar 210, the circular space portion 122 is filled with concrete 220 including a reinforcing bar (not shown).

That is, since the stacked precast pier segments (P) and the column portion 120 are in a state where the main reinforcing bar holes 126 are in communication with each other, the main reinforcing bars 126 are inserted into the main reinforcing bars 126, respectively, and mortar When filling the 210, the precast pier segments (P) and the pillar portion 120 are integrally connected to each other through the main reinforcing bars (200).

As shown in FIG. 4, the central circular space 122 of the stacked precast pier segments P is filled with concrete 220 including reinforcing bars as well as the main reinforcing bars 200. It is firmly fixed. Therefore, the stacked plurality of precast pier segments (P) and the pillar portion 120 are integrally coupled to each other to form a single pier.

In addition, the mortar 210 is also filled with the axial force applying hole 132 to fix the axial force reinforcing bar 130. In this way, the step of installing and fixing the pier coping part 230 on the main reinforcing bar 200 protruding over the final precast pier segment P installed in a plurality of stacks is performed as shown in FIG. 4.

Meanwhile, in the present invention, as shown in FIGS. 5A and 5B, the axial force applying reinforcing bars 130 ′ are disposed at the center of the upper surface of the pier foundation 110 and on the upper side of the pier foundation 110. The circular space portion 122 of the plurality of precast pier segments (P) to be positioned may extend through the upper portion in turn, and the axial force may be applied to each precast pier segment (P).

In this case, the pillar portion 120 and the plurality of precast pier segments (P) are centered instead of the axial force reinforcing bars 130 disposed at four circumferential equal intervals as shown in FIGS. 1 to 4. It can be replaced with a single axial force reinforcing bar 130 'located in the circular space 122 of.

Through this structure, as shown in FIG. 6, a plurality of precast pier segments P may be stacked up and down, and an epoxy bond 170 may be disposed between the respective precast pier segments P. They are integrally coupled to each other with axial force applied.

In addition, the main reinforcing bars 200 are inserted into the main reinforcing hole 126 in the state in which the plurality of precast pier segments P are stacked as described above, and are fixed integrally through the mortar 210. After fixing the main reinforcing bar 200, the concrete 220 including the reinforcing bars (not shown) is filled in the central circular space 122 of the stacked precast pier segments P, as shown in FIG. 7. In this way, on the main reinforcing bar 200 protruding over the final precast pier segment (P) installed in a plurality of stacked manner is to install and fix the coping portion 230 of the piers to complete the piers.

In this coupling process, when the axial force is to be applied to the precast pier segments (P) by using the reinforcing rod 130 ', a separate support plate (not shown) is provided to provide a central circular space portion. After covering the 122, the nut 190 is installed thereon, and tightened through a torque wrench (not shown). The other construction process is basically the same as the method using the four axial force reinforcing bars 130 described above with respect to Figures 1 to 4, further detailed description will be omitted.

Meanwhile, in the pier construction method 100 using the precast segment according to the present invention, as shown in FIG. 8A, the pier foundation 110 is constructed, and axial force reinforcing bars 130 and the main reinforcing bars 200 are upper. The step of installing the pier foundation 110 is formed.

That is, the pier foundation 110 is made of a concrete structure in which reinforcing bars 112 are disposed inside, and a plurality of cast iron bars 200 maintaining a predetermined interval in a circular shape is protruded and disposed in the circular shape. The pier foundation 110 is constructed with a structure in which the axial force-improving reinforcing bar 130 having a male screw portion 130a formed at an upper end thereof protrudes inside the main rebar 200.

In this case, the main reinforcing bar 200 protruding to the upper side of the pier foundation 110 is extended to the upper side as long as the length of the pier, such a main reinforcing bar 200 is a reinforcing bar fixed spacer for maintaining a constant gap therebetween ( 250) is installed at regular intervals.

The reinforcing bar fixed spacer 250 has a structure in which a plurality of arc-shaped grooves 252 are formed in the semicircular support discs 254a and 254b, respectively. The semi-circular support discs 254a and 254b are cast reinforcing bars 200. ) Are positioned in the arc-shaped grooves 252 to fix the cast steel 200 to maintain a predetermined interval.

In this way, the epoxy bond 170 is applied to the upper surface of the pier foundation 110 in a state in which the position and spacing of the main reinforcing bars 200 are accurately maintained through the reinforcing bar fixing spacers 250, and the main reinforcing bars 200 are provided. And a new first precast pier segment (P1) as shown in Figure 8b to the upper side of the axial force reinforcing bars 130, the first precast pier segment (P1) is shown in Figures 2b and 2c As shown in FIG. 1, the circular space portion 122 is formed at the center thereof, and the axial force applying hole 132 and the plurality of main reinforcing bar holes 126 are formed on the outside thereof. It is coupled to the rebar 130 and the main reinforcing bars 200, respectively.

When the first precast pier segment P1 is fitted from the upper part of the main reinforcing bar 200 in the coupling process as described above, the rebar fixing spacers 250 inserted into the main rebar 200 are removed to remove the first precast pier segment P1. ) Is in direct contact with the epoxy bond 170, the bottom surface of which is applied to the top surface of the pier foundation 110.

In such a state, the axial force is applied to the reinforcing bar 130, and in this case, the support plate 186 is inserted into the axial force reinforcing bar 130 as described with reference to FIG. 2A, and then the nut 190 Screw) and tighten the nut 190 using a torque wrench (not shown), respectively.

Therefore, the nut 190 that is rotated by the torque wrench introduces an axial force of at least 0.3 MPa (3 kg / cm ² ) by pulling the reinforcing force 130 for axial force, and in this state, the pillar part 120 and the first It is left for at least 1 hour for epoxy curing between the precast pier segments P1.

In this way, in the state in which the first precast pier segment P1 is stacked on the pillar part 120, the new axial force reinforcing bars 130 are extended to the upper side through the coupler 150, respectively. The coupler 150 may also use a conventional coupler for rebar connection used in the art.

In addition, the epoxy bond 170 is coated on the upper surface of the first precast pier segment P1, and the rebar fixing spacers 250 are mounted on the main rebar 200 to accurately space and position the main rebar 200. 9, the new second precast pier segment P2 is inserted into the upper side of the main reinforcing bar 200 and the axial force reinforcing bar 130, and the first precast pier segment ( A step of installing the second precast pier segment P2 is performed in the same process as P1).

Then, a plurality of precast pier segments P are stacked and installed at a desired height in the same process as the installation process of the second precast pier segment P2 in turn on the second precast pier segment P2 that is stacked in this manner. do.

In addition, when the desired height is reached through the lamination process, the mortar 210 is filled and fixed in the main reinforcing holes 126 and the axial force applying holes 132 of the respective precast pier segments P, respectively, and the circular space As shown in FIG. 10, the portion 122 is filled with concrete 220 including reinforcing bars.

And the step is completed by installing and fixing the coping portion 230 on the main reinforcing bar 200 protruding over the final precast pier segment (P) erected to the desired height as described above.

Through such steps, the present invention stacks the precast pier segments (P) fabricated at the factory in multiple stages on the pier foundation 110 to be placed in the field for rapid construction of downtown bridges. It is made through the epoxy bond 170 in the applied state, it is possible to ensure a fast working speed and sufficient strength at the segment (P) connection by integrating through the cast bar 200 and the concrete 220 filling layer, pier Performance can be limited.

Therefore, the present invention can greatly contribute to the reduction of construction cost through shortening the air of the bridge construction work.

An embodiment of the present invention described above and shown in the drawings should not be construed as limiting the technical idea of the present invention. The protection scope of the present invention is limited only by the matters described in the claims, and those skilled in the art can change and change the technical idea of the present invention in various forms. Accordingly, such improvements and modifications are within the scope of the present invention as long as they are obvious to those skilled in the art.

1 is an explanatory diagram for constructing a pier foundation in a pier construction method using a precast segment according to the present invention,

a) is a structure in which the bridge foundation and the pillar portion integrally formed,

b) the structure to build the pier foundation and pillar separately;

c) is a structure which forms a recessed part in a pier base part, and builds a pillar part.

2 is a structural diagram connecting the precast pier segment to the pillar in the bridge construction method using the precast segment according to the present invention,

a) a perspective view of the drawing, b) a plan view of the precast pier segment to which the drawing cap is fixed,

c) is a perspective view of a precast pier segment.

3 is a perspective view illustrating a structure in which a plurality of precast pier segments are stacked in a pillar part in a pier construction method using precast segments according to the present invention.

4 is a cross-sectional view of the piers constructed by the piers construction method using the precast segment according to the present invention.

5 is an explanatory diagram for constructing a pier foundation part in a pier construction method using a precast segment according to the present invention;

Figure a) is a perspective view showing a single axial force reinforcing bar is disposed in the center of the pier foundation and the pillar portion, b) is a perspective view showing a structure in which precast pier segments are laminated on the pier foundation and the pillar portion.

FIG. 6 is a perspective view illustrating a structure in which a plurality of precast pier segments are stacked on a column part in which one axial force applying reinforcing bar is disposed in a center in a pier construction method using precast segments according to the present invention.

FIG. 7 is a cross-sectional view illustrating a structure in which a plurality of precast pier segments are stacked on a column part in which one axial force applying reinforcing bar is disposed in the center in a pier construction method using precast segments according to the present invention.

8 is a view illustrating a structure in which a main reinforcing bar is first constructed in a pier foundation in a pier construction method using precast segments according to the present invention.

a) is a sectional view, b) is a perspective view.

FIG. 9 is a cross-sectional view illustrating a structure in which precast pier segments are stacked on the main reinforcing bars of a pier foundation in a pier construction method using precast segments according to the present invention.

FIG. 10 is a structural diagram of a pier constructed using a pier construction method using a precast segment of the present invention shown in FIG. 9.

Description of the Related Art

100 ..... Pier construction method using precast segment

110 ..... Pier foundation 112 ..... Rebar

120 ..... Pillar 122 ..... Circular Space

126 ..... Cast iron hole 130.130 '..... Axial reinforcing bars

130a .... Male thread 132 ..... Axial hole

134 ..... Non-contraction concrete 138 ..... Cylindrical groove

150 ..... coupler 152 ..... female thread

160 ..... Cap 162 ..... Cylindrical section

164 ..... disc 170 ..... epoxy bond

182 .... Connecting groove 184 ..... Connecting projection

186 .... support plate 190 ..... nut

200 .... Cast iron 210 ..... Maltar

220 .... concrete 230 ..... coping

250 .... Rebar fixing spacer 252 ..... Arc groove

254a, 254b .... Semicircular support disc

P ..... Precast Pier Segment

P1 ..... First Precast Pier Segment

P2 ..... 2nd precast pier segment

Claims (8)

In pier construction method to build bridge, The interior of the reinforcement is made of a reinforced concrete structure, the upper portion of the column 120 corresponding to a precast pier segment (P) of a cylindrical shape integrally protruding, the pillar portion 120 is circular in the center A space 122 is formed, and a plurality of main reinforcing holes 126 are formed along the outer circumference thereof, and the upper side of the pillar part 120 is provided with an axial force applying reinforcing bar 130 having a male screw portion 130a formed at an upper end thereof. Constructing the pier foundation 110 such that the protrusion protrudes; A new axial force reinforcing bar 130 extends upward through the coupler 150 at the upper end of the axial force reinforcing bar 130 of the pillar part 120, and a cap 160 in each main reinforcing hole 126. The cap 160 has a cylindrical portion 162 inserted into the main reinforcing hole 126 and a disc portion 164 having a larger diameter than the cylindrical portion 162. Blocking each of the two and applying an epoxy bond (170) to an upper surface of the pillar (120); After removing the caps 160 from the pillars 120, respectively, a new first precast pier segment P1 is inserted into the upper side of the axial force reinforcing bar 130 extending in length, and the axial force reinforcing bars Insert the support plate 186 into the 130, then screw the nut 190 and tighten the nut 190 and pull the axial force reinforcing bar 130 at least 0.3 MPa for sufficient attachment between the segments using a torque wrench respectively. Introducing an axial force of (3 kg / cm ² ), and leaving it to stand for at least one hour for epoxy curing between the pillar portion 120 and the first precast pier segment (P1); On the first precast pier segment (P1) through the coupler 150, respectively, the new axial force reinforcing bars 130 are extended to the upper side, and each of the main reinforcing holes 126 is capped by covering the cap 160, After applying the epoxy bond 170 on the upper surface of the first precast pier segment (P1), the cap 160 is removed, respectively, and a new second to the upper side of the axial force reinforcing bar 130 is extended Inserting a precast pier segment (P2), introducing an axial force into the reinforcement rod (130), and installing a second precast pier segment (P2) on the first precast pier segment (P1);  In the same process as the installation process of the second precast pier segment (P2) in turn on the second precast pier segment (P2), a plurality of precast pier segments (P) are laminated and installed at a desired height, and the desired height Inserting the main reinforcing bars 200 into the main reinforcing hole holes 126 and then fixing them with the mortar 210 and filling the circular space 122 with concrete 220 including the reinforcing bars; And And installing and fixing a coping part 230 on the main reinforcing bar 200 protruding above the final precast pier segment (P). The method of claim 1, wherein the step of constructing the pier foundation 110 is a circular space in the center on the axial force reinforcing bars 130 of the pier foundation 110 made of a concrete structure reinforcement 112 A 122 is formed, and the piercing base portion 110 and the pillar portion 120 are fitted to each other by inserting the axial force-imposing holes 132 of the pillar portion 120 in which a plurality of cast iron holes 126 are formed along the outer circumference. Bridge construction method using a precast segment, characterized in that the non-contraction concrete 134 is applied to each other between). The method of claim 2, wherein the step of constructing the pier foundation 110 is a cylindrical groove 138 is formed on the upper surface of the pier foundation 110 made of a concrete structure in which reinforcing bars 112 are arranged, the cylindrical In the groove 138, an axial force reinforcing bar 130 is located, and a circular space 122 is formed at the center on the axial force reinforcing bar 130, and a plurality of main reinforcing holes 126 are formed along the outer circumference. The axial force imparting hole 132 of the formed pillar part 120 is inserted and coupled, and the non-contraction concrete 134 is coated between the cylindrical groove 138 of the pier foundation part 110 and the pillar part 120. Pier construction method using a precast segment, characterized in that coupled to each other. According to any one of claims 1 to 3, wherein the axial force-improving reinforcement 130 is disposed at four circumferential intervals in four directions on the upper surface of the pier foundation 110, the pier foundation ( A plurality of precast pier segments (P) located in the upper side of the 110 is sequentially extended through the upper, precast segment characterized in that the axial force is applied to each precast pier segment (P) installation Pier construction method using According to any one of claims 1 to 3, wherein the axial force-improving reinforcement 130 is disposed in the center of the upper surface of the pier foundation 110, located on the upper side of the pier foundation 110 Using a precast segment, characterized in that extending through the circular space portion 122 of the plurality of precast pier segments (P) in turn to the top, and the axial force is applied to each precast pier segment (P) installation Pier construction method. The method of claim 1, wherein the precast pier segment (P) is factory manufactured by a match cast method for the exact matching of the segment connection, the upper edge of the connection groove to the precast pier segment (P) 182 is formed, and at the bottom edge thereof, a connection protrusion 184 is formed to connect the connection protrusion of the upper side precast pier segment P to the connection groove 182 of the lower side precast pier segment P during the stacking construction. Pier construction method using a precast segment, characterized in that 184 is coupled to enable accurate and fast positioning of the segment (P). In pier construction method to build bridge, The interior of the reinforcing bar 112 is made of a reinforced concrete structure, the upper part of the plurality of cast iron reinforcement 200 to maintain a predetermined interval in a circular form is formed, the inner side of the cast iron reinforcement 200 arranged in a circle Constructing a pier foundation part 110 in which an axial force reinforcing bar 130 having a male screw portion 130a formed on an upper side thereof protrudes; Applying an epoxy bond 170 on the upper surface of the pier foundation 110, and inserting a new first precast pier segment (P1) to the upper side of the main reinforcing bar 200 and the axial force reinforcing bar 130, The first precast pier segment (P1) has a circular space portion 122 is formed in the center, the axial force imparting hole 132 and a plurality of the main reinforcing hole 126 is formed on the outer side of the main reinforcement 200 and It is coupled to the axial force reinforcing bar 130, the support plate 186 is fitted to the axial force reinforcing bar 130, then screw the nut 190 and using a torque wrench, respectively, for a sufficient attachment between the segments ( 190) and pull the axial force reinforcement 130 to introduce an axial force of at least 0.3 MPa (3 kg / cm ² ), and to cure the epoxy between the column portion 120 and the first precast pier segment P1. For at least 1 hour; The new axial force reinforcing bars 130 extend upward through the coupler 150 on the first precast pier segment P1, respectively, and an epoxy bond 170 on the upper surface of the first precast pier segment P1. ), And then inserting a new second precast pier segment (P2) into the upper side of the main reinforcing bar 200 and the axial force reinforcing bar 130, in the same process as the first precast pier segment (P1) Installing a second precast pier segment (P2);  On the second precast pier segment P2, a plurality of precast pier segments P are laminated and installed at a desired height in the same process as the installation process of the second precast pier segment P2. When it reaches to the filling of the mortar 210 in the main reinforcing holes 126 of each precast pier segment (P), and filling the circular space portion 122 with concrete 220 including the reinforcing bars; And And installing and fixing a coping part 230 on the main reinforcing bar 200 protruding above the final precast pier segment (P). The rebar fixing spacer 250 of claim 7, wherein the cast steel bars 200 each have a plurality of arc-shaped grooves 252 formed on the semicircular support discs 254a and 254b to maintain a constant spacing of the cast steel bars 200. ) Are installed a large number, precast pier segments (P) are fitted to the main reinforcing bars 200 in the state of maintaining the position of the cast steel (200) accurately during construction, and after the combination of the precast pier segments (P) Pier construction method using a precast segment, characterized in that the reinforcing bar fixed spacer 250 is removed.

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