KR102200400B1 - Precast segment, pillar structure including the same and construction method of pillar structure usinging the same - Google Patents

Abstract

A precast segment is disclosed, and the precast segment includes: a concrete body portion in which a trench groove recessed downward from an upper surface of an edge portion corresponding to an axial main reinforcement extends along a circumferential direction; An anchor trench that is provided in a ring shape with an upwardly opened hollow portion extending along a circumferential direction, and positioned in the trench groove to be coupled with the concrete body portion; A plurality of axial main reinforcement bars positioned at intervals along the circumferential direction with each upper end connected to the lower surface of the anchor trench and each lower end extending downwardly protruding toward the lower surface of the concrete body portion; And a ring member connected to a lower end of each of the plurality of axial main reinforcing bars, wherein when the precast segment is disposed on a lower precast segment adjacent to the lower side thereof, the plurality of axial main reinforcing bars is the ring member It is provided to be located inside the hollow portion of the anchor trench of the lower precast segment, and the hollow portion of the anchor trench may be filled with mortar.

Description

Precast segment, pillar structure including the same, and construction method of pillar structure using the same {PRECAST SEGMENT, PILLAR STRUCTURE INCLUDING THE SAME AND CONSTRUCTION METHOD OF PILLAR STRUCTURE USINGING THE SAME}

The present application relates to a precast segment, a column structure including the same, and a construction method of a column structure using the same.

A pier is a structure that supports the bridge deck and is installed when the upper structure is more than 2 spans, and is a structure that transmits the load of the superstructure to the foundation ground. The construction of piers includes copings, columns, and foundations, and is classified into T-type piers, wall-type piers, ramen-type piers, and inverted A-type piers according to their shape.

When constructing such a pier by concrete on-site casting, it is important to note that the quality of the concrete is maintained and the concrete structure is secured without defects by pouring it tightly into the formwork. Accordingly, pouring and compacting may be repeated. In the case of column concrete, excessive side pressure and deformation of the formwork occur due to this, and continuous pouring is prohibited. This may naturally lead to longer air.

In addition, the pier can be constructed by the precast concrete method. The precast concrete method is a method of producing each member at a factory and combining each member at the site to complete. High-difficulty work is mainly performed at the factory, and the site is completed with minimal work, resulting in homogeneity of quality. It is a construction method that has the advantage of reducing field manpower to a minimum.

By the way, the performance and characteristics of precast concrete columns appear large according to the connection part for each segment. In the conventional precast method, as a coupling method of the connection part, there is a method of connecting a steel rod, etc. to the foundation, inserting a precast segment into the steel rod, and then fastening a bolt or the like at the end, or inserting a stranded wire and then tightening it. . In the case of using steel bars like this, after connecting the steel bars with a coupler, the segments are inserted into the steel bars and laminated. In this case, prestress is not mainly introduced. On the other hand, in the case of using a stranded wire as the coupling method of the connection, the precast with the sheath tube embedded in it is continued and then the strand is inserted to introduce the prestress. In this case, the compressive force may be somewhat advantageous against bending tension, but compression resistance decreases. There is a drawback.

The technology behind the present application is disclosed in Korean Patent Publication No. 10-2009-0118711.

The present application is intended to solve the problems of the prior art described above, excluding the method of tensioning the steel wire of a column structure such as the existing precast piers, promoting higher construction convenience, and minimizing the construction cost. An object of the present invention is to provide a precast segment, a column structure including the same, and a construction method of a column structure using the same.

However, the technical problems to be achieved by the embodiments of the present application are not limited to the technical problems as described above, and other technical problems may exist.

As a technical means for achieving the above technical problem, the precast segment according to an aspect of the present application includes: a concrete body portion in which a trench groove recessed downward from an upper surface of an rim portion corresponding to an axial main reinforcement extends along a circumferential direction; An anchor trench that is provided in a ring shape with an upwardly opened hollow portion extending along a circumferential direction, and positioned in the trench groove to be coupled with the concrete body portion; A plurality of axial main reinforcement bars positioned at intervals along the circumferential direction with each upper end connected to the lower surface of the anchor trench and each lower end extending downwardly protruding toward the lower surface of the concrete body portion; And a ring member connected to a lower end of each of the plurality of axial main reinforcing bars, wherein when the precast segment is disposed on a lower precast segment adjacent to the lower side thereof, the plurality of axial main reinforcing bars is the ring member It is provided to be located inside the hollow portion of the anchor trench of the lower precast segment, and the hollow portion of the anchor trench is filled with mortar.

In addition, the pillar structure according to one aspect of the present application includes a precast segment according to one aspect of the present application.

In addition, a method of constructing a pillar structure using a precast segment according to an aspect of the present application includes stacking the precast segment on the lower precast segment.

In addition, a method of constructing a pillar structure using a precast segment according to an aspect of the present application includes the steps of: (a) forming at least a part of a lower concrete foundation so that the upper surface of the first steel plate is exposed; (b) connecting the first steel plate and the second steel plate to connect the lowermost precast segment to the lower concrete foundation; And (c) stacking one or more of the precast segments on the lowermost precast segment, wherein the mortar is filled in the step (c).

The above-described problem solving means are merely exemplary and should not be construed as limiting the present application. In addition to the above-described exemplary embodiments, additional embodiments may exist in the drawings and detailed description of the invention.

According to the above-described problem solving means of the present application, the precast segment and the lower precast segment are formed by the anchoring force generated by embedding and fixing the axial main reinforcing bar and the ring member of the precast segment into the mortar of the anchor trench of the lower precast segment. It can be continuous, and the tensile resistance can be increased by the ring member, so it is possible to construct a precast column only by continuing the reinforcing bar, excluding the conventional steel wire tension method (the traditional method of connecting steel wires or steel bars). Compared to the on-site method, a construction method can be implemented that can reduce air and construction costs, reduce environmental pollution, and secure construction convenience.

1 is a schematic conceptual perspective view of a precast segment according to an exemplary embodiment of the present disclosure viewed obliquely from above.
2 is a schematic conceptual cross-sectional view of a precast segment according to an embodiment of the present application.
3 is a schematic conceptual cross-sectional view of a precast segment according to an embodiment of the present disclosure connected to a lower precast segment.
4 is a schematic conceptual cross-sectional view of a precast segment according to an embodiment of the present disclosure in which a mortar inlet and a mortar outlet are shown to explain a mortar inlet and a mortar outlet. In addition, FIG. 4 is a schematic conceptual cross-sectional view of a precast segment according to an embodiment connected by a coupler or welding in order to illustrate a mortar inlet and a mortar outlet in which a mortar inlet and a mortar outlet are shown, and in order to shift and arrange the main reinforcing bar outward to be.
FIG. 5 is a schematic conceptual cross-sectional view of a reinforcing bar of a precast segment according to an embodiment of the present disclosure connected to a lower precast segment.
6A is a schematic conceptual perspective view of a precast segment according to an embodiment of the present application as viewed obliquely from the lower side.
6B is a conceptual perspective view and a conceptual bottom view for explaining another embodiment of a precast segment according to an embodiment of the present application in which a groove for preventing the overflow of mortar is formed in a ring member.
7 is a schematic conceptual diagram of a portion connected by a double coupler of a lower main reinforcing bar and an upper main reinforcing bar to explain a double coupler of a precast segment according to an embodiment of the present application.
8 is a schematic cross-sectional view of a portion connected by a double coupler of a lower main reinforcing bar and an upper main reinforcing bar to explain a double coupler of a precast segment according to an embodiment of the present application.
9 is a schematic conceptual perspective view of a pillar structure according to an embodiment of the present application.
10 is a schematic conceptual perspective view showing the interior to explain the connection between the lower concrete foundation and the lowermost precast segment of the column structure according to an embodiment of the present application.
11 is a schematic conceptual perspective view for explaining a first step of a method of constructing a pillar structure according to an embodiment of the present application.
12 and 13 are schematic conceptual perspective views for explaining a second step of a method for constructing a pillar structure according to an embodiment of the present application.
14 is a schematic conceptual perspective view for explaining a third step of the construction method of the pillar structure according to an embodiment of the present application.
15 is a schematic conceptual perspective view of a pillar structure constructed by a method of constructing a pillar structure according to an embodiment of the present application.

Hereinafter, exemplary embodiments of the present application will be described in detail with reference to the accompanying drawings so that those of ordinary skill in the art may easily implement the present application. However, the present application may be implemented in various different forms and is not limited to the embodiments described herein. In addition, in the drawings, parts not related to the description are omitted in order to clearly describe the present application, and similar reference numerals are attached to similar parts throughout the specification.

Throughout this specification, when a part is said to be "connected" with another part, it is not only the case that it is "directly connected", but also "indirectly connected" or "electrically connected" with another element interposed therebetween. "Including the case.

Throughout this specification, when a member is positioned "on", "upper", "upper", "under", "lower", and "lower" of another member, this means that a member is located on another member. It includes not only the case where they are in contact but also the case where another member exists between the two members.

Throughout the specification of the present application, when a certain part "includes" a certain component, it means that other components may be further included rather than excluding other components unless specifically stated to the contrary.

In addition, in the description of the embodiments of the present application, terms related to direction or position (upper, upper, upper, lower, lower, lower, etc.) are set based on the arrangement state of each component shown in the drawings. For example, when looking at FIGS. 1 to 7 and 9 to 15, the 12 o'clock direction is the upper side, the portion facing the 12 o'clock direction is the top, the end facing the 12 o'clock direction is the top, and the overall The 6 o'clock direction may be a lower side, a portion generally facing the 6 o'clock direction may be a lower side, and an end portion generally facing the 6 o'clock direction may be a lower side.

The present application relates to a precast segment, a column structure including the same, and a construction method of a column structure using the same.

This application is used in the construction of the pillar structure. Here, the pillar may be a pier pillar. However, the pillar of the present application is not limited thereto, and of course, it can be widely applied to the construction field (a pillar type used in various fields in the civil engineering/architectural field. That is, the present application is of a civil or architectural structure having a skeleton structure) It is applicable to the construction of pillars and such pillars. In addition, this application is applicable to the field of precast pillars, and not only pillars with a circular cross section, but also pillars with a polygonal cross section (for example, a square), and pillars with a track shape, etc. It can be applied to columns having a cross section of various shapes.

First, a precast segment (hereinafter referred to as'this precast segment') 1 according to an embodiment of the present application will be described.

1 is a schematic conceptual perspective view of a precast segment obliquely down from the top according to an embodiment of the present application, FIG. 2 is a schematic conceptual cross-sectional view of a precast segment according to an embodiment of the present application, and FIG. 3 is a lower part A schematic conceptual cross-sectional view of a precast segment according to an embodiment of the present application connected to the precast segment, and FIG. 4 is a mortar inlet and a mortar outlet according to an embodiment of the present application shown in order to explain a mortar inlet and a mortar outlet. A schematic conceptual cross-sectional view of a precast segment, and FIG. 5 is a schematic conceptual cross-sectional view of a reinforcing bar of a precast segment according to an embodiment of the present application connected to a lower precast segment, omitted, and FIG. 6A is an embodiment of the present application It is a schematic conceptual perspective view of the precast segment according to the example viewed obliquely from the lower side, and FIG. 6B shows another embodiment of the precast segment according to an embodiment of the present application in which a groove is formed in a ring member for preventing the overflow of mortar. It is a conceptual perspective view and a conceptual bottom view for explaining. 7 is a schematic conceptual diagram of a portion connected by a double coupler of a lower main reinforcing bar and an upper main reinforcing bar to describe a double coupler of a precast segment according to an embodiment of the present application, and FIG. 8 is a precast according to an embodiment of the present application It is a schematic cross-sectional view of the part connected by the double coupler of the lower main reinforcing bar and the upper main reinforcing bar to explain the double coupler of the segment.

1 and 2, the present precast segment 1 is a concrete body portion 11 in which a trench groove recessed downward from the upper surface of the rim corresponding to the axial main reinforcement 13 to be described later extends along the circumferential direction. ).

Referring to FIG. 1, the concrete body part 11 may have a circular cross section. In this case, the circumferential direction of the concrete body portion 11 may mean a circumferential direction of the concrete body portion 11. However, in the present application, the cross section of the concrete body part 11 is not limited to a circular shape, and the concrete body part 11 has a cross section of various shapes according to the shape of the pillar to which the present precast segment 1 is applied (for example, , Oval cross-section, polygonal cross-section, track-shaped cross-section, etc.).

In addition, referring to FIGS. 1 and 2, the precast segment 1 is provided in a ring shape in which an upwardly opened hollow part extends along the circumferential direction, and is positioned in the trench groove to be bound with the concrete body part 11. It includes an anchor trench (12). For example, the precast segment 1 may include an anchor trench 12 in a ring shape in which a hollow portion opened upward in a U-shape extends along the circumferential direction. For example, when the cross section of the precast segment 1 cut in the horizontal direction is circular, the ring shape may be circular. As such, the ring shape of the anchor trench 12 may be set to a shape corresponding to the cross-sectional shape of the present precast segment. As a ring shape, not only a circular shape but also various ring shapes (eg, oval, square, track type, etc.) forming a closed loop may be applied.

In addition, the concrete body portion 11 may be formed integrally with the anchor trench 12 by pouring or curing concrete in a state in which the anchor trench 12 is disposed during its manufacture. However, the arrangement method of the anchor trench 12 is not limited thereto.

Further, for example, referring to FIGS. 1 and 2, the anchor trench 12 may have a wrinkle formed on its outer circumferential surface (outer surface). The bonding force between the anchor trench 12 and the concrete body 11 may be improved by the corrugation of the outer circumferential surface of the anchor trench 12 than when there is no corrugation on the outer circumferential surface. For example, referring to FIGS. 1 and 2, a plurality of corrugations having a shape extending along the circumferential direction may be repeatedly formed along the vertical direction on the outer circumferential surface of the anchor trench 12. Through these corrugations, the binding force between the anchor trench 12 and the concrete body 11 may be increased.

In addition, referring to FIG. 2, the precast segment 1 has its upper end connected to the lower surface of the anchor trench 12, and each lower end extends so as to protrude downward toward the lower surface of the concrete body 11 It includes a plurality of axial main reinforcing bars 13 positioned at intervals along the circumferential direction. For example, the upper end of the axial main reinforcement 13 may be fixed to the lower surface of the anchor trench 12 by welding. In addition, here, the spacing between the plurality of axial main reinforcing bars may be a constant (same) spacing, but is not limited thereto.

Further, referring to FIGS. 2 and 3, the present precast segment 1 includes a ring member 14 connected to the lower end of each of the plurality of axial main reinforcing bars 13. The ring member 14 may be provided in the form of a ring plate. For example, the ring member 14 and the axial main reinforcement 13 may be connected by welding. For example, at the lower end of the axial main reinforcing bar 13, a steel plate of a size that can be inserted into the anchor trench 12 is manufactured in a ring shape, and is welded to the lower end of the axial main reinforcing bar 13, so that a ring member ( 14) can be provided.

In addition, the ring member 14 may be a steel plate.

In addition, a plurality of the precast segments 1 may be stacked in the vertical direction (for example, in the height direction of the pillar).

Referring to FIG. 3, when the present precast segment 1 is disposed on a lower precast segment 1 ′ adjacent to the lower side thereof, the plurality of axial main reinforcing bars 13 have a ring member 14 that is lower free. It is provided to be located inside the hollow part of the anchor trench 12 of the cast segment 1'. In addition, the plurality of axial main reinforcing bars 13 may be provided so that the ring member 14 connected to the lower end thereof may be located at the lower side of the inside of the hollow portion of the anchor trench 12 of the lower precast segment 1'. have. For example, the ring member 14 may be provided to contact the bottom surface of the hollow portion of the anchor trench 12 of the lower precast segment 1 ′. As another example, the ring member 14 may be provided on the lower side of the hollow portion without contacting the bottom surface of the hollow portion of the anchor trench 12 of the lower precast segment 1'.

In addition, as described above, the ring member 14 may have a size that can be inserted into the anchor trench 12. Specifically, the ring member 14 is circumferentially so that it can be inserted into the anchor trench 12. It is preferable that the width in the inner and outer directions perpendicular to the direction (in the case where the concrete body part 11 has a circular cross section, in the radial direction) is smaller than the width in the inner and outer directions of the anchor trench 12. Accordingly, the ring member 14 can be located in the hollow of the anchor trench 12 of the lower precast segment 1 ′.

In addition, the reinforcing reinforcing bars 15 arranged at regular intervals on the outer surface of the anchor trench may act as resistance against the force that destroys concrete along the outer surface of the anchor trench 12 by flexural tension.

In addition, a mortar 121 or an epoxy resin is filled in the hollow portion of the anchor trench 12.

Accordingly, when the present precast segment 1 is disposed on the lower precast segment 1', the axial main reinforcing bar 13 of the present precast segment 1 is the anchor trench of the lower precast segment 1'. (1) It can be inserted into, and mortar 121 can be filled in the anchor trench 1 of the lower precast segment 1', so that the axial main reinforcing bar 13 of the present precast segment 1 and The main reinforcing bars 13 in the axial direction of the lower precast segment 1 ′ may be bound (integrated). In addition, a ring member 14 is provided at the lower end of the axial main reinforcing bar 13 of the precast segment 1, and the ring member 14 is inserted into the anchor trench 12 of the lower precast segment 1'. As much as possible, the axial main reinforcing bar 13 is inserted into the anchor trench 1 of the lower precast segment 1'to fill the mortar 121, so that the axial main reinforcing bar 13 and the ring member 14 The mortar 121 in the anchor trench 12 of the lower precast segment 1'(that is, the axial main reinforcement 13 of the present precast segment 1 and the axial main reinforcement of the lower precast segment 1') (13)) can be improved.

Further, referring to FIG. 6B, in order to prevent the mortar 121 from overflowing by the ring member 14 when the precast segment 1 is stacked, the ring member 14 within a range capable of securing an appropriate cross-sectional area for anchoring. ), it is possible to increase the filling property of the mortar by digging the groove 14a. As shown in FIG. 6B, a plurality of grooves 14a may be formed at intervals along the circumferential direction (circumferential direction) of the ring member 14. In addition, the groove 14a may include an outer groove having a shape recessed from the outer circumferential surface to the inside, and an inner groove having a shape recessed from the inner peripheral surface to the outside. In addition, the groove 14a may be referred to as a groove shape in terms of the inner and outer directions, but may be referred to as a hole shape that penetrates (through holes) in the vertical direction based on the vertical direction.

For reference, the pull-out resistance of the axial main reinforcing bar (head anchor) 13 is in proportion to the area of the ring member (head) 14 and the strength of the mortar 121, and is not theoretically related to the buried depth, but stable fixation is not possible. The axial main reinforcing bar 13 may be inserted deeply enough into the anchor trench 12 of the lower precast segment 1 ′, and for this purpose, the depth of the hollow portion of the anchor trench 12 so as to secure a sufficient buried depth ( The depth in the vertical direction) may be set to have a predetermined depth (a preset depth).

For example, the anchor trench 12 of the lower precast segment 1 ′ is filled with mortar 121 (for example, it may be filled with a high strength mortar of 70 MPa or more) and then the ring member 14 of the precast segment 1 ) Is inserted into the anchor trench 12 of the lower precast segment 1', and the present precast segment 1 may be disposed (stacked) on the lower precast segment 1'. At this time, the precast segment 1 and the lower precast segment 1'viewed so that the upper end of the ring member 14 is completely covered with the mortar 121 may be combined.

Alternatively, as another example, the precast segment 1 viewed so that the ring member 14 of the present precast segment 1 is inserted into the anchor trench 12 of the lower precast segment 1'is a lower precast segment ( After being disposed (stacked) on 1'), the mortar 121 may be filled in the anchor trench 12 of the lower precast segment 1'. In this case, when the mortar 121 is post-filled, the mortar inlet 122 and the mortar outlet 123 to be described later may be used.

In addition, the anchor trench 12 may have wrinkles formed on its inner circumferential surface (inner surface). The binding force between the anchor trench 12 and the mortar 121 filled in the hollow portion of the anchor trench 12 due to the wrinkles on the inner circumferential surface of the anchor trench 12 may be improved than when there is no wrinkle on the inner circumferential surface. For example, referring to FIGS. 1 and 2, a plurality of corrugations having a shape extending along the circumferential direction may be repeatedly formed along the vertical direction on the inner peripheral surface of the anchor trench 12. Through these wrinkles, the binding force of the anchor trench 12 and the mortar 121 in the anchor trench 12 may be increased.

In addition, referring to FIG. 4, at least one mortar injection hole 122 may be formed in the anchor trench 12 to communicate the outer circumferential surface of the hollow portion and the concrete body portion 11 so that mortar can be injected into the hollow portion. The mortar injection hole 122 is preferably formed in the lower portion of the anchor trench 12 so that the mortar filling into the anchor trench 12 can be made in a complete (full or tight) state.

In addition, referring to FIG. 4, at least one mortar outlet 123 communicating the outer circumferential surface of the hollow portion and the concrete body portion 11 may be formed in the anchor trench 12 so that the mortar can be discharged from the hollow portion. . The mortar outlet 123 may be positioned to be spaced apart from the mortar inlet 122 along the circumferential direction by a predetermined distance or more so that the mortar may be discharged after being filled in the hollow portion at least a predetermined distance, and is relative to the mortar inlet 122 It can be located on the upper side. In addition, for example, the mortar injection port 122 and the mortar discharge port 123 may be located on opposite sides of the outer circumferential surface (outer surface) of the concrete body 11.

According to the mortar outlet 123, when the mortar 121 starts to be discharged to the outside of the hollow portion through the mortar outlet 123 in the process of injecting the mortar 121 into the hollow portion, the filling of the mortar 121 to the hollow portion is It may be determined that a predetermined or more has progressed, and it may be easier for the operator to determine whether to stop the mortar 121 injection. That is, when it is desired to visually check the buffered state of the mortar 121 placed in the anchor trench 12, the mortar 121 is injected and discharged through at least one of the mortar inlet 122 and the mortar outlet 123 The reliability of the cross section can be increased by confirming the condition.

In addition, referring to Figures 4 and 5, any one of the plurality of axial main reinforcement 13, the lower main reinforcement 131 to which the ring member 14 is connected to the lower side and the lower side of the outer side of the inner and outer direction than the lower main reinforcement It may include an upper main reinforcing bar 132 connected to the lower main reinforcing bar 131 and having an upper end connected to the lower surface of the anchor trench 12 in a state shifted in a direction. Specifically, referring to Figures 4 and 5, in order to improve the efficiency of the column cross section, the upper main reinforcing bar 132 is shifted outward, and the lower main reinforcing bar 131 and the weld joint 1311 or coupler 1312 are The main reinforcing bar 13 in the axial direction may be formed in the form of a connection treatment.

The moment resistance (tensile resistance) of the axial main reinforcing bar 13 may become more advantageous as the position of the axial main reinforcing bar 13 in the concrete body part 11 is toward the outside of the concrete body part 11. Accordingly, as a method for securing the covering of the axial main reinforcing bar 13 at the level of the cast-in-place construction method, any one of the plurality of axial main reinforcing bars 13 is an upper main reinforcing bar 132 and an upper main reinforcing bar shifted in the outward direction ( It may include a lower main reinforcing bar 131 connecting the upper main reinforcing bar 132 and the ring member 14 inserted into the anchor trench 12 of the lower precast segment 1 ′ from the inside of 132. Accordingly, it is possible to secure an effective cross section by reducing the covering to an effective level, and thus, it is possible to insert a rebar amount similar to that of the cast-in-place method and secure the same level of stiffness.

For example, referring to FIGS. 4 and 5, the upper main reinforcing bar 132 may be provided so that its lower end does not protrude from the lower surface of the concrete body portion 11. In addition, as an example, the lower main reinforcing bar 131 has its upper end located inside the concrete body part 11 and its lower end is positioned to protrude from the lower surface of the concrete body part 11 so that the ring member 14 is connected. I can.

4 and 5, the upper main reinforcing bar 132 is overlapped by a welding joint, a double coupler (see FIGS. 7 and 8) in a state in which a preset section of the lower side overlaps with the lower main reinforcing bar 131. Can be. For reference, Figures 4 and 5, in order to explain the connection by the welding joint (1311) and the double coupler (1312), the lower main reinforcement of the axial main reinforcement 13 of the present precast segment (1) ( 131) and the upper main reinforcing bar 132 are shown to be welded joint 1311, and the lower main reinforcing bar 131 and the upper main reinforcing bar 132 of any one axial main reinforcing bar 13 of the lower precast segment 1' It is shown connected by a Double Coupler (1312).

It is preferable that the length of the preset section that is overlapped and arranged is set to a length corresponding to the criterion that sufficient connection can be made between the upper main reinforcement bar 132 and the lower main reinforcement bar 131 according to the connection method.

In addition, referring to Figs. 2 to 4, at least one of the outer outer circumferential surface of the anchor trench 12 and the inner outer circumferential surface of the anchor trench 12 has a concrete tensile failure of the concrete region adjacent to the anchor trench 12 in the concrete body 11 To prevent, a plurality of reinforcing bars 15 extending in the vertical direction may be disposed at intervals in the circumferential direction.

The reinforcing bar 15 is preferably provided so that its upper end does not protrude upwardly than the upper surface of the concrete body portion. In addition, the reinforcing reinforcing bar 15 may be provided such that its lower end is located below the lower surface of the anchor trench 12. The spacing at which the reinforcing bars are arranged along the circumferential direction may be set to a level at which a safety factor for preventing tensile failure of concrete can be secured.

In other words, the precast segment 1 fixes the anchor trench 12 described above to the upper end of the axial main reinforcing bar 13 and reinforces at least one of the two sides (outer outer peripheral surface and inner outer peripheral surface) of the anchor trench 12 By arranging the reinforcing bar (15) it is possible to prevent the concrete tensile failure.

In addition, referring to Figures 2 to 6, the concrete body portion 11 is formed with a shear resistance protrusion 113 protruding downward from the middle portion of its lower surface, and referring to Figures 1 to 5, the upper surface A shear resistance depression 112 that is depressed downward in correspondence with the shear resistance projection 113 may be formed in an intermediate portion of the shear resistance. The shear resistance protrusion 113 may be inserted into the shear resistance depression 112 of the lower precast segment 1 ′ to serve as a shear key.

In summary, this precast segment (1) is applicable to precast precast column structures (piers), and focuses on completing the column structures (piers) only by continuing reinforcing bars, excluding the existing method of connecting steel bars and strands. I can. The conventional method of continuing steel bars or rebars mainly uses a method of connecting steel bars or rebars using a coupler, then connecting pier segments and filling the voids with mortar, but this precast segment (1) is the precast segment (1). ) Embedded in the high-strength mortar 121 of this precast segment (the lower precast segment (1') described above) neighboring the lower end of the axial main reinforcing bar 13 downward without directly connecting the axial main reinforcing bars 13 between them Thus, it is possible to form a column by using the anchoring force. In addition, the precast segment 1 may increase tensile resistance by attaching a ring member 14, which is a steel plate continuously formed in the circumferential direction, to the lower end of the axial main reinforcing bar 13 in order to secure the maximum support.

The pier, which is a bending/compression member, has a disadvantage in that the compression resistance ability decreases when the conventional method of introducing compression prestress is applied.According to this precast segment (1), this point is supplemented and additional work in the field is minimized. Workability can be improved.

In addition, when the precast segment 1 is connected, regardless of the position of the upper and lower reinforcing bars, the shear resistance protrusion 112 is fitted to the position of the shear resistance depression 113 of the lower precast segment 1'. The main precast segment (1) and the lower precast segment (1') can be easily continuous, and even before the mortar (121) hardens, the next main precast segment (upper Precast segment) (1) can be constructed continuously, so the construction speed is faster than the existing method, so it can meet the original purpose of rapid construction.

That is, the precast segment 1 is configured to process the connection through anchoring of the axial main reinforcing bar 13 (the ring member 14 at the lower end of the axial main reinforcing bar 13 is embedded in the high-strength mortar 121 to (13) and a configuration that connects the main reinforcing bar 13 in the axial direction of the lower precast segment 1 ′). At this time, concrete destruction, pullout failure, reinforcement breakage, etc. due to the tensile force applied to the axial main reinforcing bar 13 can be secured by applying the anchor design piece based on the concrete structure.

Hereinafter, a column structure (hereinafter referred to as a “main column structure”) according to an exemplary embodiment of the present disclosure including the precast segment 1 according to an exemplary embodiment of the present disclosure will be described. However, in relation to the description of the pillar structure, the same reference numerals are used for the configurations that are the same or similar to the configurations described in the precast segment 1 according to the embodiment of the present application, and the overlapping description will be simplified or omitted. To

9 is a schematic conceptual perspective view of a pillar structure according to an embodiment of the present application, and FIG. 10 is an interior view to explain the connection between the lower concrete foundation and the lowermost precast segment of the pillar structure according to an embodiment of the present application. It is a schematic conceptual perspective view.

9, the present pillar structure includes a precast segment 1 according to an embodiment of the present application described above.

In addition, referring to FIG. 9, the main pillar structure may include a lower concrete foundation 2.

In addition, referring to FIG. 9, the main pillar structure may include a lowermost precast segment 1 connected to the lower concrete foundation 2.

Referring to Figure 10, the lower concrete foundation (2) is the L-shaped reinforcement 211 attached to the lower surface of the first steel plate (the cross section may be circular, but not limited thereto) 21 is mounted at a predetermined height. It can be formed in a state. The first steel plate 21 includes the first steel plate 21 (or the lower concrete foundation 2) and the lowermost precast segment (1'') (or the lowermost precast segment (1``) and the main precast segment (1). ) May include an L-shaped reinforcing bar 211 to resist bending of the continuous portion of the column part). In addition, for reference, the L-shaped reinforcing bar 211 may be welded to the first steel plate 21, and as shown in FIG. 10, the L-shaped reinforcing bar 211 has a shape formed to be bent toward the outside. Can have. In addition, a bolt may be provided on an upper portion of the first steel plate 21 so as to be bolted to the second steel plate 16 of the lowermost precast segment 1 ″ to be described later.

In addition, referring to FIG. 10, the lowermost precast segment 1 ″ is a second steel plate (the cross section may be circular, but is not limited thereto) after processing the axial main reinforcing bar 131 in an L shape and then welding. Not) 16, and the lowermost precast segment 1 ″ may be connected to the lower concrete foundation 2 through the connection of the first steel plate 21 and the second steel plate 16. For example, the second steel plate 16 may be disposed on the first steel plate 21 so that its lower surface faces the upper surface of the first steel plate 21 and may be bolted to the first steel plate 21. . For example, a hole through which the bolt of the first steel plate 21 can pass may be formed in the second steel plate 16, and the second steel plate 16 is made so that the bolt of the first steel plate 21 passes through the hole. 1 may be arranged against the steel plate 21, and then by fastening the nut to the bolt, it can be connected to the first steel plate 21. In addition, the lower concrete foundation 2 is formed by surrounding the connected part of the first steel plate 21 and the second steel plate 16 (the connected part of the first steel plate 21 and the second steel plate 16 is the lower concrete foundation ( 2) can be formed to be embedded in).

In addition, one or more precast segments 1 may be stacked and disposed above the lowermost precast segment 1 ″. For example, the present precast segment 1 may be stacked and arranged so that the height formed by the stacking of the lowermost precast segment 1 ″ and the main precast segment 1 corresponds to the required height of the main pillar structure. have.

According to this, the main pillar structure may be based on the lower concrete foundation 2, which is cast in place, and the precast segment 1, and the lower concrete foundation 2 is the first steel plate to which the L-shaped reinforcing bar 211 is welded. The second steel plate (16) attached to the lower end of the lowermost precast segment (first precast segment) (1``) by mounting (21) at a height of 1/2 of the lower concrete foundation (2) And the first steel plate (21) are bolted together, and the connection between the bone precast segment (1) thereafter (the bone precast disposed on the lowermost precast segment (1 ``) and the lower precast segment (1'') The connection of the segments 1 or the connection between the precast segments 1) may be formed by embedding the axial main reinforcement 13 in a high-strength mortar.

In addition, the main pillar structure may be a pier. In this case, referring to FIG. 9, the main pillar structure may include a coping part 3. This main pillar structure can be based on the cast-in-place lower concrete foundation (2), the main precast segment (1), and the coping part (3), and the lower concrete foundation (2) is the first The steel plate 21 is mounted on approximately half the height of the lower concrete foundation 2 (not necessarily limited to half the height) to pre-cast concrete, and the lowermost precast segment (first precast segment) (1 ''), the second steel plate (16) and the first steel plate (21) attached to the lower end are bolted, and the connection between the present precast segment (1) (lowest precast segment (1``) and the lower end free The connection of the precast segment 1 or the connection between the precast segments 1) disposed on the cast segment 1'' is through the axial main reinforcement 13 embedded in the high-strength mortar. It may be formed by being completed, and such a main pillar structure may be referred to as a precast pier.

In summary, this column structure relates to a precast precast column structure (pier), and focuses on completing the column structure (pier) only by continuing reinforcing bars, excluding the existing method of connecting steel bars and strands. The conventional method of continuing steel bars or rebars uses a coupler to connect steel bars or rebars, then connects the pier segments and fills the voids with mortar, but the main column structure is the axial main reinforcement between the main precast segments (1). Without directly connecting (13), the lower end of the axial main reinforcing bar 13 is embedded in the high strength mortar 121 of the lower precast segment 1'to form a column using the anchoring force. In addition, in order to secure the maximum support, the present column structure may increase tensile resistance by attaching a ring member 14, which is a steel plate continuously formed in the circumferential direction, at the lower end of the axial main reinforcement 13. In this case, a groove 14a (a hole in the vertical direction) may be formed in the ring member 14 within a range in which tensile resistance is secured for the purpose of facilitating the filling of the mortar.

The pier, which is a flexural and compressive member, has a disadvantage in that the compression resistance ability decreases when the conventional method of introducing compression prestress is applied, but this column structure supplements this and improves workability by minimizing additional work on site. In addition, when the precast segment 1 is connected, the shear resistance protrusion 113 is matched to the position of the shear resistance depression 112 of the lower precast segment 1'regardless of the position of the upper and lower reinforcing bars. The main precast segment (1) and the lower precast segment (1') can be easily continuous, and even before the mortar (121) of the lower precast segment (1') is hardened, The construction of the next neighboring segment (the upper precast segment) is continuously possible, so the construction speed is faster than the conventional method, so it can meet the original purpose of rapid construction.

That is, this column structure is configured to process the connection through anchoring of the axial main reinforcing bar 13 (the ring member 14 at the lower end of the axial main reinforcing bar 13 is embedded in the high-strength mortar 121, and the axial main reinforcing bar 13 and A configuration connecting the main reinforcing bars 13 in the axial direction of the lower precast segment 1 ′) may be included. At this time, concrete destruction, pullout failure, reinforcement breakage, etc. due to the tensile force applied to the axial main reinforcing bar 13 can be secured by applying the anchor design piece based on the concrete structure.

In addition, the present application may propose a method of constructing a pillar structure according to an exemplary embodiment of the present invention as described above, and a method of constructing a pillar structure according to an exemplary embodiment of the present application. However, in relation to the construction method of the column structure according to the embodiment of the present application, the precast segment 1 according to the embodiment of the present application, the same or similar configuration as the configuration described in the column structure according to the embodiment of the present application The same reference numerals are used for reference numerals, and redundant descriptions will be simplified or omitted.

The construction method of the pillar structure according to an embodiment of the present disclosure includes the step of laminating the present precast segment 1 on the lower precast segment 1 ′.

In addition, the present application may propose a method of constructing a pillar structure according to another embodiment of the present invention described above, and a method of constructing a pillar structure according to an exemplary embodiment of the present application (the main pillar structure construction method). However, in relation to the construction method of the pillar structure according to the embodiment of the present application, the precast segment according to the embodiment of the present application, the same or similar to the configuration described in the precast segment according to the embodiment of the present application, or the same Reference numerals are used, and overlapping descriptions will be simplified or omitted.

11 is a schematic conceptual perspective view for explaining a first step of a method for constructing a pillar structure according to an embodiment of the present application, and FIGS. 12 and 13 are a second perspective view of a method for constructing a pillar structure according to an embodiment of the present application. It is a schematic conceptual perspective view for explaining the steps, and Figure 14 is a schematic conceptual perspective view for explaining the third step of the construction method of the pillar structure according to an embodiment of the present application.

15 is a schematic conceptual perspective view of a pillar structure constructed by a method of constructing a pillar structure according to an embodiment of the present application.

Referring to FIG. 11, the method of constructing a pillar structure includes forming at least a part (2') of the lower concrete foundation so that the upper surface of the first steel plate 21 described above is exposed (first step). For example, the first step is to apply the first steel plate 21 to which the L-shaped reinforcing bar is welded to approximately 1/2 the height of the lower concrete foundation 2 (not necessarily limited to the 1/2 height), and the first It is possible to form at least a part (2') of the lower concrete foundation by placing the steel plate 21 facing the upper side to pre-cast concrete (primary concrete pouring). Referring to FIG. 11, in this case, at least a portion 2 ′ of the lower concrete foundation may be a part corresponding to the lower half of the entire lower concrete foundation.

In addition, referring to FIGS. 12 and 13 together, in this method of constructing a pillar structure, the first steel plate 21 and the second steel plate 16 are connected to the lowermost precast segment (1'') on the lower concrete foundation (2). It includes a step of connecting (second step).

For example, in the second step, referring to FIG. 12, the second steel plate 16 is placed on the first steel plate 21 so that the lower surface of the second steel plate 16 faces the upper surface of the first steel plate 21. And the second steel plate 16 can be bolted to the first steel plate 21, and then, referring to FIG. 13, concrete is poured to the required height of the lower concrete foundation 2 (secondary concrete pouring ), it is possible to form the lower concrete foundation (2).

In addition, referring to FIG. 14, the method for constructing a pillar structure includes a step (third step) of stacking one or more of the present precast segments 1 on the lowermost precast segment 1 ″.

In the third step, mortar 121 is injected into the anchor trench 12 of the lowermost precast segment 1'', and the ring member 14 of the present precast segment 1 is placed in the lowermost precast segment 1''. ) Of the anchor trench 12 in the mortar 121 and the present precast segment 1 may be disposed on the lowermost precast segment 1 ″. Alternatively, in the third step, the precast segment 1 viewed so that the ring member 14 of the present precast segment 1 is located within the anchor trench 12 of the lowermost precast segment 1'' is the lowermost precast segment. After placing on the (1 ″), the mortar 121 can be filled with the anchor trench 12 of the lowermost precast segment 1 ″. Thereafter, this process is repeated, and the main precast segment 1 (upper precast segment) adjacent to the upper side of the main precast segment 1 may be stacked. In the third step, the precast segment 1 is viewed until the height formed by the stacking of the lowermost precast segment 1 ″ and the precast segment 1 corresponds to the required height of the column structure to be formed. Can be stacked and arranged.

In addition, referring to FIG. 15, in the method of constructing the post structure, the coping part 3 is connected to the top precast segment 1 of the stacked precast segments 1 and the coping part 3 is arranged. can do. The connection method between the coping unit 3 and the main precast segment 1 is the connection method between the main precast segment 1 described above (connection method between the main precast segment 1 and the lower precast segment 1'). It may be the same or similar to.

According to the above, the present application excludes the existing steel wire tension method of the precast pier, promotes the convenience of construction as much as possible, and minimizes the construction cost, after placing mortar (high-strength concrete) in the ring-shaped anchor trench 12. By embedding and fixing the axial main reinforcing bar 13 to which the ring member 14 is attached, a precast pier can be constructed to exert the effect of continuity. Accordingly, the present application can be said to provide a precast pier and a construction method thereof through the settlement of reinforcing bars.

The foregoing description of the present application is for illustrative purposes only, and those of ordinary skill in the art to which the present application pertains will be able to understand that it is possible to easily transform it into other specific forms without changing the technical spirit or essential features of the present application. Therefore, it should be understood that the embodiments described above are illustrative and non-limiting in all respects. For example, each component described as a single type may be implemented in a distributed manner, and similarly, components described as being distributed may also be implemented in a combined form.

The scope of the present application is indicated by the claims to be described later rather than the detailed description, and all changes or modified forms derived from the meaning and scope of the claims and their equivalent concepts should be interpreted as being included in the scope of the present application.

1: precast segment
1': lower precast segment
11: Concrete body part
112: depression for shear resistance
113: protrusion for shear resistance
12: anchor trench
121: mortar
13: Axial main reinforcement
131: lower main reinforcement
1311: welded joint
1312: Coupler (e.g. Double Coupler)
132: upper main reinforcement
14: ring member
14a: groove (hole in the vertical direction)
15: rebar
16: second steel plate
2: lower concrete foundation
2'part of the lower concrete foundation
21: first steel plate
211: L-shaped reinforcement
3: coping section

Claims (10)

In the precast segment used in the construction of the pillar structure,
A concrete body portion having a trench groove recessed downward from the upper surface of the rim portion corresponding to the axial main reinforcement extending along the circumferential direction;
An anchor trench that is provided in a ring shape with an upwardly opened hollow portion extending along a circumferential direction, and positioned in the trench groove to be coupled with the concrete body portion;
A plurality of axial main reinforcement bars positioned at intervals along the circumferential direction with each upper end connected to the lower surface of the anchor trench and each lower end extending downwardly protruding toward the lower surface of the concrete body portion; And
Including a ring member connected to the lower end of each of the plurality of axial main reinforcement,
When the precast segment is disposed on a lower precast segment adjacent to the lower side thereof, the plurality of axial main reinforcing bars are provided such that the ring member is located inside the hollow portion of the anchor trench of the lower precast segment, and the The hollow part of the anchor trench is filled with mortar,
The anchor trench has a plurality of folds formed repeatedly along the vertical direction on each of the inner and outer circumferential surfaces thereof, and extends along the circumferential direction,
By the corrugation of the outer circumferential surface, the binding force between the anchor trench and the concrete body part is improved than when there is no corrugation of the outer circumferential surface,
By the wrinkles on the inner circumferential surface, the binding force between the anchor trench and the mortar filled in the hollow portion of the anchor trench is improved than when there are no wrinkles on the inner circumferential surface,
The anchor trench has a mortar injection port communicating the outer circumferential surface of the hollow part and the concrete body part so that the mortar can be injected into the hollow part, and communicating the outer circumferential surface of the hollow part and the concrete body part so that the mortar can be discharged from the hollow part. A mortar outlet is formed,
The mortar outlet is positioned to be spaced apart from the mortar inlet by a predetermined distance or more along the circumferential direction, and is positioned relatively above the mortar inlet,
The preset distance is set in consideration of discharge after the mortar is filled in the hollow portion at least a predetermined amount. delete delete The method of claim 1,
Any one of the plurality of axial main reinforcement,
A lower main reinforcement to which the ring member is connected to a lower end; And
The lower side is connected to the lower main reinforcement in a state in which the lower side is shifted outward in the inner and outer direction than the lower main reinforcement, and the upper main reinforcement is connected to the lower surface of the anchor trench. The method of claim 1,
On at least one of the outer outer and inner outer peripheral surfaces of the anchor trench, a plurality of reinforcing reinforcing bars extending in the vertical direction are spaced in the circumferential direction to prevent tensile failure of concrete in the concrete area adjacent to the anchor trench in the concrete body. Precast segments that are placed and placed. The method of claim 1,
In the concrete body portion, a shear resistance protrusion protruding downward is formed in an intermediate portion of the lower surface thereof, and a shear resistance depression protruding downward corresponding to the shear resistance protrusion is formed in an intermediate portion of the upper surface thereof,
The shear resistance protrusion is inserted into the shear resistance depression of the lower precast segment to serve as a shear key. Column structure comprising a precast segment according to claim 1. The method of claim 7,
Lower concrete foundation; And
Further comprising a lowermost precast segment connected to the lower concrete foundation,
At least one precast segment is stacked and disposed above the lowermost precast segment,
The lower concrete foundation is formed in a state in which the first steel plate attached to the lower surface of the L-shaped reinforcement is mounted at a predetermined height,
The lowermost precast segment includes a second steel plate to which the lower end of the axial main reinforcement is connected,
The lowermost precast segment is to be connected to the lower concrete foundation through the connection of the first steel plate and the second steel plate. As the construction method of the pillar structure according to claim 7,
A method of constructing a column structure using a precast segment, comprising the step of stacking the precast segment on the lower precast segment. As the construction method of the pillar structure according to claim 8,
(a) forming at least a part of the lower concrete foundation so that the upper surface of the first steel plate is exposed;
(b) connecting the first steel plate and the second steel plate to connect the lowermost precast segment to the lower concrete foundation; And
(c) stacking one or more of the precast segments on the lowermost precast segment,
The mortar is filled in the step (c), the column structure construction method using a precast segment.

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