KR20080065571A - Psc bridge pier assembled with precast concrete segments having steel duct and steel pipe, and constructing method thereof - Google Patents

Abstract

A construction method of a PSC bridge assembled with precast concrete segments having a steel duct and a steel pipe is provided to prevent a rise in construction expenses by installing shear connectors to a pier foundation and a segment using a partially short steel duct and installing connecting sockets to a segment and a coping part using a partially short steel duct, to connect a segment and a pier foundation easily, to prevent shear failure of a joint, and to improve constructability by inserting a steel pipe for supporting a steel wire between a steel wire and a sheath pipe and keeping a steel wire upright by a steel pipe for supporting a steel wire. A construction method of a PSC bridge assembled with precast concrete segments having a steel duct and a steel pipe comprises the steps of: constructing a pier foundation(110) on the surface of the earth to make plural sheath pipes for foundation, steel wires extended as much as the length of a pier and inserted to the sheath pipes for foundation, and plural shear connectors for shear connection penetrated with the steel wires to be projected to the top; inserting a steel pipe for supporting a steel wire between the sheath pipe for foundation and the steel wire inserted to the pier foundation; piling the pre-manufactured segment(120) on the top of the pier foundation, putting a rubber pad for balance on a retreated groove for a segment of the pier foundation and coupling a connecting socket of the segment with the shear connector of the pier foundation; piling the pre-manufactured segment on the top of the segment piled on the pier foundation in order to the planned height, and coupling a connecting socket with a shear connector; placing a coping part(130) on the top of the uppermost segment or piling the precast product on the top of the uppermost segment, and coupling a shear connector with a connecting socket; and pulling out the steel pipe for supporting a steel wire, and tensing and anchoring the steel wire.

Description

PSC bridge piers assembled with precast concrete segments with steel ducts and steel pipes and construction methods thereof

The present invention relates to a PSC pier and a construction method thereof assembled from a precast concrete segment having a steel duct and a steel pipe, and in particular, a shear connecting member using a steel duct of a short length is installed in a pier foundation and a segment. Connection sockets using steel ducts with short lengths are installed in the segments and copings, and assembled into precast concrete segments with steel ducts and steel pipes for inserting steel pipes between sheath pipes and steel wires for the independence of steel wires. It relates to a PSC pier and its construction method.

In general, the construction of bridges due to concrete pouring on site increases the construction period, and due to the occurrence of environmental problems and civil complaints, such a construction method is reduced in recent years, and instead, preformed segments are prefabricated on site. The rapid construction method to use is used a lot.

The rapid construction method not only shortens the overall construction period of the bridge but also minimizes environmental problems and civil complaints. The rapid construction method requires the use of large equipment to mechanize the construction environment. It is true that it helps.

In assembling these segments, the shear key is to be provided for the shear connection in the discontinuous surface existing between the segments so that the shear resistance by mechanical engagement is exerted. In the case of precast concrete segments, these shear keys are generally formed as protrusions on one side of the segment when fabricating the segment. However, in the case of manufacturing a shear key protruding to one side of the segment as described above, when demolding the formwork, the shear key is easily broken due to minor carelessness. In particular, the smaller the shear key size and the larger the protruding length, the more likely the breakage of the shear key is to occur during the segment manufacturing process. Not only that, when concrete is not properly filled in the shear key forming part of the formwork, when the mold is demolded, the shear key is often not formed in the desired shape.

On the other hand, in arranging tension members continuously in neighboring segments, there is a possibility that water leakage occurs through discontinuous surfaces between the segments. Leakage in the tension member installation hole that occurs at the discontinuous surface between the segments, that is, the joint surface of the segment causes corrosion of the tension member, which may cause damage of the tension member and cause serious problems for the entire structure such as collapse of the structure. Therefore, in order to continuously assemble the segment, special special measures are required to prevent corrosion of the tension member disposed continuously in the segment.

In order to solve this problem, the applicant has developed a patent registration No. 10-0738999 (precast concrete segment having an assembly structure using a steel duct and its connection assembly structure).

As shown in FIG. 1, a steel duct for shear connection in a prefabricated concrete segment 10 (hereinafter, abbreviated as “segment”) having an assembly structure using the steel duct in the assembling direction of the segment 10. Is embedded in the penetrated state. The steel duct is made of a cylindrical steel wire support steel pipe and a tension material that is to introduce a tension force to the segment 10 is disposed through the interior of the steel duct 20.

As shown in the figure, the lower end of the steel duct 20 is located in accordance with the lower surface of the segment 10 does not protrude to the outside, the upper end of the steel duct 20 of the segment 10 It protrudes out of the top surface. As described later, the upper end of the steel duct 20 protruding to the outside, when assembling the adjacent segments 10, the lower surface of the neighboring segment 10, that is, of the steel duct 20 embedded in the neighboring segment 10 It is inserted at the bottom. For easy insertion and coupling of the steel duct 20 between these neighboring segments 10, the lower end of the steel duct 20 is made up of an enlarged pipe portion 21 having an enlarged diameter thereof. In addition to the formation of the pipe portion 21, the upper end of the steel duct 20 is formed as a tapered shaft pipe portion 23 so that the diameter thereof gradually decreases.

However, since the shaft portion is formed at one end of the steel duct, and the expansion tube is formed at the other end, when the length of the segment is longer, the length of the steel duct is also increased, resulting in an increase in the cost of air.

In addition, when the sheath pipe with the same steel wire length is inserted into the piling base, bending occurs in the steel wire when the segments are stacked, which causes another problem that is difficult to stack the segments.

In addition, when the segment used in the pier sphere is connected to the pier foundation, since the shear section is not formed on the pier foundation separately, the connection between the segment and the pier foundation is not easy, which may cause shear failure of the joint. There is a problem with.

The present invention is to solve the above problems, and to install a connecting connector using a steel duct of a short length part in the pier foundation and the segment, the connection socket using a steel duct of a short length part in the segment and the coping part PSC piers assembled from precast concrete segments with steel ducts and steel pipes that prevent cost increases, facilitate connection between segments and piers, and prevent shear failure of joints. The purpose is to provide a construction method.

In addition, the present invention is provided with a steel duct and a steel pipe to improve the workability by allowing the steel wire to stand up by the steel wire support steel pipe at the time of segment stacking by inserting the steel wire support steel pipe for the independence of the steel wire between the steel wire and the sheath pipe. Another object is to provide a PSC piers and a construction method thereof assembled from precast concrete segments.

In addition, the present invention is to chamfer the corners of the pier foundation and the segment, and by attaching a sealing material to the waterproofing between the segments and at the same time to add a color to the sealing material to give the aesthetic, precast concrete having a steel duct and steel pipe Another object is to provide a PSC piers assembled into segments and construction methods thereof.

Features of the present invention for achieving the above object,

In the PSC bridge construction method, a plurality of foundation sheath pipe, a steel wire extending by the length of the pier is inserted into the foundation sheath pipe, and the steel wire is penetrated, a plurality of shear connecting members for the shear connection protrudes to the upper surface A pier foundation construction step of constructing a pier foundation to be formed; A steel wire supporting steel pipe insertion step of inserting a steel wire supporting steel pipe having the same length as the steel wire between the foundation sheath pipe and the steel wire inserted into the piling foundation; Each of the connecting sockets of the precast concrete segment prefabricated to have a plurality of shear connecting members on the upper surface and a plurality of connecting sockets on the bottom thereof is 1: 1 interconnected with each of the shear connecting members provided on the upper surface of the pier foundation. A first lamination step of joining and laminating the segment on the upper surface of the pier foundation; A second lamination process of laminating segments in multiple stages by mutually coupling each connecting socket of a segment neighboring each shear connecting member of the segment to each other; A coping portion forming step of forming a coping portion on an upper surface of the uppermost segment; And a fixing step of tensioning and fixing the steel wire after removing the steel wire supporting steel pipe.

Here, the pier base is formed with a segment groove on the upper surface, the rubber pad for horizontal maintenance and non-shrink mortar filling is further inserted into the groove.

Here, the groove is also chipped to facilitate attachment of the non-shrink mortar.

Here, the segment is further provided with a segment sheath tube for a one-to-one correspondence with the base sheath tube so that the steel wire and the steel support steel pipe penetrates, and extends from the lower end of the shear connecting member to the upper end of the connecting socket. do.

Here, the segment is formed with a chamfer at the bottom edge of the uppermost segment, and the upper and lower edges of the segment adjacent to the lowermost segment and the uppermost segment, and the sealing material is bonded to the chamfer.

Here, the segment is spaced apart from the outer surface of the shear connector by a predetermined distance to form a sealing groove in the form of a ring, the sealing rubber pad is provided in the sealing groove.

Here, the bottom surface of the connection socket is interviewed on the upper surface of the sealing rubber pad.

Here, the steel wire support steel pipe is fixed by the steel pipe support reinforcement at the pier foundation, and is removed during the stacking of the segments.

Herein, the coping portion is cast in situ on the uppermost segment upper surface or precast and laminated on the uppermost segment.

Here, the coping portion is formed by inserting a connection socket on the bottom surface of the corresponding position 1: 1 with the shear connector of the segment.

Here, the coping portion is further provided with a coping sheath pipe that corresponds 1: 1 with the sheath pipe for the segment so that the steel wire and the steel wire for supporting the steel line passes, and extends from the lower end of the shear connector and to the upper end of the connection socket. do.

Here, the shear connection member is formed in a cylindrical shape having an upper and lower surfaces opened or a tapered shape in which the upper and lower surfaces are opened but the upper end is narrower and wider toward the lower end.

Here, the connection socket is formed in a cylindrical shape of the upper surface is closed, the lower surface is open, the upper surface has a through hole through which the base sheath pipe or the segment sheath pipe through.

Here, the shear connector and the connection socket maintain a gap when mutually coupled, and the non-shrink mortar is filled in the gap and the shear connector and the connection socket.

Here, in the second lamination step, the adhesive is applied to the upper surface of the segment, and then the neighboring segments are laminated.

Another feature of the invention,

It is characterized in that the PSC pier assembled from the precast concrete segment having the steel duct and the steel pipe constructed by the construction method of the PSC pier assembled from the precast concrete segment provided with the steel duct and the steel pipe.

According to the PSC pier and the construction method thereof assembled from the precast concrete segment having the steel duct and the steel pipe of the present invention configured as described above, the construction cost by installing a shear connection material using a steel duct of short length in the pier foundation and segment The rise can be prevented in advance, the connection between the segment and the pier foundation can be facilitated, and the shear failure of the joint can be prevented.

In addition, according to the present invention by inserting a steel support steel pipe for the independence of the steel wire between the steel wire and the sheath pipe to allow the steel wire to be upright by the steel wire support steel pipe at the time of stacking the segment to improve the workability to shorten the construction period. .

In addition, according to the present invention, by chamfering the corners of the pier foundation and the segment, and attaching a sealing material thereto, it is possible to provide aesthetics by waterproofing the segments and adding color to the sealing material.

Hereinafter, with reference to the accompanying drawings the configuration of the PSC piers assembled with precast concrete segments having a steel duct and a steel pipe according to the present invention will be described in detail.

In the following description of the present invention, if it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted. Terms to be described later are terms defined in consideration of functions in the present invention, and may be changed according to intentions or customs of users or operators. Therefore, the definition should be made based on the contents throughout the specification.

Figure 2 is a perspective view showing the configuration of the pier foundation of the PSC pier assembled with precast concrete segment having a steel duct and steel pipe according to the present invention, Figure 3 is a cross-sectional view of Figure 2 AA, Figure 4 is a plan view of Figure 2 5 is a perspective view showing the configuration of the segment of the PSC pier assembled with precast concrete segments having the steel duct and steel pipe according to the present invention, Figure 6 is a steel duct and steel pipe according to the present invention Fig. 7 is a sectional view taken along the line BB of Fig. 6, and Fig. 8 is a precast concrete segment having a steel duct and a steel pipe according to the present invention. Side cross-sectional view showing the configuration of the coping portion of the assembled PSC bridge piers, Figures 9a and 9b 10 is a perspective view showing the configuration of a shear connection member in a PSC pier assembled with recast concrete segments, and FIG. 10 is a perspective view showing a configuration of a connection socket in a PSC pier assembled from a precast concrete segment having a steel duct and a steel pipe according to the present invention. 11 is a cross-sectional view showing a PSC pier assembled from precast concrete segments having a steel duct and a steel pipe according to the present invention.

As shown in FIGS. 2 to 11, the pier foundation 110 is placed in the field, and a plurality of shear connecting members 203 for shear connection are inserted into the upper end, so that the shear connecting members 203 protrude upward.

The pier foundation 110 includes a plurality of foundation sheath pipes 111 and steel wires 201 extending along the length of the pier to be inserted into the foundation sheath pipes 111. Segment grooves 113 are formed on the upper side to the side, and grooves 113 are chipped to facilitate the attachment of the non-shrink mortar, and the grooves 113 are horizontally maintained and leaks of non-shrink mortar filling. Rubber pad 115 for prevention is further inserted. At this time, at one end of the base sheath pipe 111 is provided with a fixing fixture 202 for fixing the steel wire 201.

In addition, the upper edge of the pier foundation 110 is preferably formed with a chamfer 117 in order to block the damage caused by the compaction equipment.

On the other hand, when the pier foundation 110 is completed, the steel wire support steel pipe 207 having the same length as the steel wire 201 between the sheath pipe 111 and the steel wire 201 for the foundation, the steel wire support steel pipe 207 is fixed by the supporting rebar 119.

As shown in FIGS. 5 to 7, the segment 120 is formed in a solid or hollow shape in the form of a rectangular parallelepiped or a cylindrical shape, so that a plurality of shear connecting members 203 are formed on an upper surface thereof, and a plurality of connections are formed on a corresponding bottom surface thereof. And a socket 205.

In addition, the segment 120 corresponds to the sheath pipe 111 for the foundation so that the steel wire 201 and the steel wire supporting steel pipe 207 penetrate 1: 1, and at the lower end of the shear connector 203 and the connection socket 205. It further includes a sheath tube 121 for the segment extending to the top of the.

In addition, the segment 120 has a chamfer 123 is formed in the corner, the sealing member 125 is coupled to the chamfer 123, spaced apart from the outer surface of the shear connector 203 by a predetermined distance from the ring-shaped sealing groove A 127 is formed and a sealing rubber pad 129 is installed in the sealing groove 127. The sealing rubber pad 129 is interviewed with the bottom surface of the connecting socket 205 on its upper surface. In this case, mortar may be poured in place of the sealing material 125.

As illustrated in FIGS. 8 and 11, the coping part 130 may be cast in-situ on the uppermost segment top surface or may be precast and stacked on the uppermost segment top segment.

In addition, the coping part 130 is formed by inserting the connection socket 205 into the bottom surface which is a position corresponding to 1: 1 with the shear connector 203 of the segment 120, the steel wire 201 and the steel wire supporting steel pipe 207 1) correspond to the sheath tube 121 for the segment so as to penetrate, and has a coping sheath tube 131 extending from the lower end of the shear connector 203 and to the upper end of the connection socket 205.

Meanwhile, the shear connecting member 203 formed on the pier foundation 110 and the segment 120 of the present invention is formed in a cylindrical shape having a top and bottom open with steel as shown in FIG. 9A. Here, the shear connector 203 may be formed in a tapered shape in which the upper and lower surfaces are opened but the upper end is narrower and wider toward the lower end as shown in FIG. 9B.

In addition, the connecting socket 205 formed in the segment 120 and the coping part 130 is formed in a cylindrical shape in which the upper surface is closed and the lower surface is open as shown in FIG. Or a through hole 206 through which the sheath tube 121 for the segment passes.

Meanwhile, the shear connector 203 and the connection socket 205 maintain a gap G at mutual coupling, and the non-shrink mortar is filled in the gap G and the shear connector 203 and the connection socket 205. .

In addition, the inner sheath tube 111 and the segment sheath tube 121 and the coping sheath tube 131 are filled with non-contraction mortar to maintain the tension of the steel wire 201 located therein.

Hereinafter, a construction method of a PSC piers assembled with precast concrete segments having steel ducts and steel pipes according to the present invention will be described in detail with reference to the accompanying drawings.

12 is a simplified process diagram of a construction method of a PSC pier assembled from precast concrete segments having steel ducts and steel pipes according to the present invention, and FIGS. 13A to 13G are free having steel ducts and steel pipes according to the present invention. It is a process chart for demonstrating the construction method of the PSC piers assembled by the cast concrete segment.

First, as shown in FIG. 13A, a plurality of foundation sheath pipes 111, steel wires 201 and a steel wire 201 which are formed extending by the length of the pier and inserted into the foundation sheath pipes 111 and penetrate therethrough, The pier foundation 110 is constructed on the ground surface such that the plurality of shear connecting members 203 for shear connection protrude upward. At this time, the piers foundation 110 performs a compaction process on the ground surface by the compaction equipment.

And, as shown in Figure 13b is inserted between the steel sheath pipe 111 and the steel wire 201 for the base inserted into the piers foundation 110, the steel wire supporting steel pipe 207 having the same length as the steel wire 201 is inserted. (S120). At this time, it is preferable to fix the steel wire supporting steel pipe 207 by the supporting rebar 119.

Then, as shown in FIG. 13C, the prefabricated segment 120 is stacked on the upper surface of the pier foundation 110. In a state where the 115 is placed, the connection socket 205 of the segment 120 is 1: 1 mutually coupled to the front end connecting member 203 of the pier foundation 110 (S130). At this time, the steel wire 201 and the steel wire support steel pipe 207 penetrates the segment 120 through the segment sheath pipe 121 of the segment 120. In addition, the shrinkage mortar is filled in the grooves 113 for the segment through the space between the rubber pads 115.

In this state, as shown in FIG. 13D, the pre-fabricated segment 120 is sequentially stacked on the top surface of the segment 120 stacked on the top surface of the pier foundation 110. And the shear connector 203 1: 1 to each other (S140). At this time, the supporting steel 119 is removed from the steel wire supporting steel pipe 207 to stack the segments 120. In addition, epoxy is applied to the top surface of the segment 120 and the bottom surface of the neighboring segment 120 to bond them together.

And, as shown in FIG. 13E, the coping part 130 is cast in the field on the top of the uppermost segment, or the precast prefabricated layer is laminated on the upper surface of the uppermost segment. 205) to each other (S150). At this time, the steel wire 201 and the steel wire support steel pipe 207 is discharged through the coping sheath pipe 131.

Then, the steel wire support steel pipe 207 is pulled out as shown in FIG. 13F, and the steel wire 201 is tensioned and fixed (S160). The fixing of the steel wire 201 is tensioned by coupling the anchorage 202 to the upper end in a conventional manner, and filling the mortar into the foundation sheath pipe 111 through the anchorage 202 of the piling foundation 110. The mortar is filled in the full length direction of the sheath tube 121 for coping and the sheath tube 131 for coping.

In addition, the shear connector 203 and the connection socket 205 are filled with non-shrink mortar. At this time, the non-shrink mortar is discharged to the outside by the sealing rubber pad 129 which the bottom surface of the connection socket 205 has interviewed.

Meanwhile, as shown in FIG. 13G, when the pier construction is completed, the sealing material 125 provided with a different color from concrete is adhered between the segment 120 and the neighboring segment 120, that is, the chamfer 123. Seal it. In this case, mortar may be poured in place of the sealing material 125, and the sealing material 125 may be attached during the lamination process of the segment 120.

As those skilled in the art would realize, the described embodiments may be modified in various ways, all without departing from the spirit or scope of the present invention. It is to be understood, however, that the present invention is not limited to the specific forms referred to in the description, but rather includes all modifications, equivalents, and substitutions within the spirit and scope of the invention as defined by the appended claims. Should be.

1 is a perspective view showing the configuration of a segment having an assembly structure using a conventional steel duct,

Figure 2 is a perspective view showing the configuration of the pier foundation of the PSC pier assembled with precast concrete segment having a steel duct and steel pipe according to the present invention,

3 is a cross-sectional view taken along line A-A of FIG. 2, and FIG. 4 is a plan view of FIG. 2;

Figure 5 is a perspective view showing the configuration of the segment of the PSC piers assembled with precast concrete segment having a steel duct and steel pipe according to the present invention,

Figure 6 is a bottom perspective view showing the configuration of the segment of the PSC piers assembled with precast concrete segment having a steel duct and steel pipe according to the present invention,

7 is a cross-sectional view taken along line B-B of FIG.

Figure 8 is a side cross-sectional view showing the configuration of the coping portion of the PSC pier assembled with precast concrete segment having a steel duct and steel pipe according to the present invention,

9a and 9b are perspective views showing the configuration of the shear connector in the PSC piers assembled with precast concrete segments having a steel duct and steel pipe according to the present invention,

10 is a perspective view showing the configuration of the connection socket of the PSC piers assembled with precast concrete segments having a steel duct and a steel pipe according to the present invention,

11 is a cross-sectional view showing a PSC pier assembled from precast concrete segments having steel ducts and steel pipes according to the present invention;

12 is a process diagram simplifying the construction method of PSC piers assembled from precast concrete segments having steel ducts and steel pipes according to the present invention;

13A to 13G are process drawings for explaining a construction method of PSC piers assembled from precast concrete segments having steel ducts and steel pipes according to the present invention.

<Explanation of symbols on main parts of the drawings>

110: pier foundation 120: segment

130: coping part 201: steel wire

203: shear connector 205: connection socket

207: steel pipe for supporting steel wire

Claims (16)

In the PSC pier construction method, A plurality of foundation sheath pipes and steel wires extending by the length of the bridge and inserted into the foundation sheath pipes, and the steel wires are penetrated, and the piling foundations are constructed so that a plurality of shear connecting members for shear connection protrude to the upper surface. Pier foundation construction process; A steel wire supporting steel pipe insertion step of inserting a steel wire supporting steel pipe having the same length as the steel wire between the foundation sheath pipe and the steel wire inserted into the piling foundation; Each of the connecting sockets of the segment pre-fabricated to have a plurality of shear connecting members on the upper surface and a plurality of connecting sockets on the corresponding lower surface thereof is 1: 1 mutually coupled to each of the shear connecting members provided on the upper surface of the pier foundation. A first lamination step of laminating segments on the upper surface of the pier foundation; A second lamination process of laminating segments in multiple stages by mutually coupling each connecting socket of a segment neighboring each shear connecting member of the segment to each other; A coping portion forming step of forming a coping portion on an upper surface of the uppermost segment; And And a fixing step of tensioning and fixing the steel wire after removing the steel wire supporting steel pipe, and a method of constructing a PSC piers assembled from precast concrete segments having steel ducts and steel pipes. The method of claim 1, The pier foundation, The groove for the segment is formed on the upper surface, The construction method of the PSC piers assembled with precast concrete segment having a steel duct and a steel pipe, characterized in that the rubber pad for horizontal maintenance and non-shrink mortar filling is further inserted into the groove. The method of claim 2, The groove is, A construction method of a PSC piers assembled from precast concrete segments having steel ducts and steel pipes, which are chipped to facilitate attachment of non-shrink mortar. The method of claim 1, The segment is A steel duct further comprising a sheath tube for a segment that corresponds to the foundation sheath pipe so that the steel wire and the steel support steel pipe pass therethrough, and extend from a lower end of the shear connection member to an upper end of the connection socket. And a construction method of PSC piers assembled from precast concrete segments having steel pipes. The method of claim 1, The segment is Precast having a steel duct and a steel pipe, characterized in that a chamfer is formed at the bottom edge of the uppermost segment and the upper and lower edges of the segment adjacent to the lowermost segment and the uppermost segment, and the sealing material is coupled to the chamfer. Construction method of PSC piers assembled from concrete segments. The method of claim 1, The segment is PSC assembled with a precast concrete segment having a steel duct and a steel pipe, characterized in that a ring-shaped sealing groove is formed at a predetermined distance from the outer surface of the shear connecting member, and a sealing rubber pad is installed in the sealing groove. Construction method of the pier. The method of claim 6, The sealing rubber pad, A construction method of a PSC piers assembled from precast concrete segments having steel ducts and steel pipes, wherein a bottom surface of the connection socket is interviewed on an upper surface thereof. The method of claim 1, The steel wire supporting steel pipe, A method for constructing a PSC piers assembled with precast concrete segments having steel ducts and steel pipes, which are fixed by supporting reinforcement on the piers foundation and removed when the segments are stacked. The method of claim 1, The coping portion, A method of constructing a PSC piers assembled from precast concrete segments having steel ducts and steel pipes, which are cast in situ on the top of the uppermost segment or are precast and laminated on the top of the uppermost segment. The method of claim 1, The coping portion, The construction method of the PSC piers assembled with precast concrete segment having a steel duct and a steel pipe, characterized in that formed by inserting the connecting socket on the bottom surface corresponding to the one-to-one connecting material of the segment. The method of claim 10, The coping portion, A steel duct further comprising a coping sheath tube that corresponds 1: 1 with the sheath sheath pipe for the segment to pass through the steel wire and the steel wire supporting steel pipe, and extends from the lower end of the shear connection member to the upper end of the connection socket. And a construction method of PSC piers assembled from precast concrete segments having steel pipes. The method of claim 1, The shear connector, A method of constructing a PSC piers assembled with precast concrete segments having a steel duct and a steel pipe, characterized in that the upper and lower surfaces are opened or the upper and lower surfaces are opened, but the upper and lower sides are tapered. The method according to claim 1 or 11, wherein The connection socket, Precast concrete segment having a steel duct and a steel pipe, characterized in that the upper surface is closed, the lower surface is formed in an open cylindrical shape, the through-hole through which the base sheath pipe or the segment sheath pipe through the center portion in the upper surface Construction method of PSC piers The method according to claim 12 or 13, The shear connector and the connection socket, A method of constructing a PSC piers assembled of precast concrete segments having steel ducts and steel pipes, characterized by maintaining a gap during mutual coupling and filling the gap and shear connectors and non-shrink mortar inside the connection sockets. The method of claim 1, The second lamination step, A method of constructing a PSC piers assembled from precast concrete segments having steel ducts and steel pipes, wherein the adjacent segments are laminated after applying an adhesive to the upper surface of the segments. A PSC pier assembled from a precast concrete segment comprising a steel duct and a steel pipe constructed by a method of constructing a PSC pier assembled from a precast concrete segment comprising a steel duct and a steel pipe according to claim 1.

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