KR101571069B1 - Precast pier construction method with reinforecing block - Google Patents

Abstract

Precast column units can be easily leveled to prevent widening and lowering on the columns, which is very advantageous for on-site construction and quality control. It is also easy to secure the bonding performance of precast column units that are stacked up and down. It is possible to construct the pier construction more quickly and it is possible to more reliably reinforce the connection part between the lower part of the foundation structure and the precast column unit, A precast pier construction method is disclosed.

Description

[0001] PRECAST PIER CONSTRUCTION METHOD WITH REINFORCING BLOCK [0002]

The present invention relates to a precast pier construction method with a securing block. More specifically, the present invention relates to a pier construction method in which a precast column unit (pierce segment) is continuously connected upward from a foundation while a coping portion is connected to the upper end of the pier, and more precisely, it is possible to construct a precast column unit more stably, And more particularly, to a precast pier construction method having a fixed block.

Figures 1A and 1B illustrate an example of constructing a bridge pier using conventional pierce segments.

That is, as shown in FIG. 1A, it can be seen that the lower part 20 of the column structure made of reinforced concrete in the shape of a rectangular parallelepiped is installed on the ground D, and on the upper surface, (40) are coupled with each other.

The precast column unit 40 for leveling is formed with the precast column unit 10 to form the trunk portion of the column structure but the level adjusting precast column unit 40 is first placed on the column lower portion 20, And the precast column unit 10 is stacked on the precast column unit 40 for level adjustment.

For this purpose, the pre-cast column unit 40 for level adjustment comprises a body 42 and a connecting member 42 including a body portion and a reinforcing bar installed to pass through the body portion upwardly and downwardly, 42 are projected downward from one end face (bottom face) of the end face of the body portion to extend to the bottom face of the lower portion 20 of the column structure.

At this time, a hollow sleeve 44 having no mortar injection port and a discharge port is formed at the other end of the coupling member 42. One end of the hollow sleeve is connected to the other end of the coupling member, (Upper surface) of the end surface.

The precast column unit 10 laminated on the upper surface of the precast leveling unit 40 for level adjustment is also provided with a connecting member 12 installed to be embedded in the inside of the trunk like the precast column unit 40 for leveling, And a hollow sleeve 14 exposed on an upper surface of the hollow sleeve 14. The hollow sleeve 14 is also filled with mortar 15 therein.

Since the hollow sleeve 44 is exposed on the upper surface of the level control precast column unit 40 constructed in this manner, the hollow reinforcement member 40 is inserted into the hollow reinforcing sleeve 44 of the pre- (13) is inserted and connected.

In this case, the reinforcing insert 13 of the precast column unit 10 is inserted into the hollow sleeve 44 of the precast column unit 40 for level adjustment so that the mortar 15 filled in the hollow sleeve 44 is hardened The precast column unit 10 can be coupled to the pre-cast column unit 40, which is integrated with the final column post 20 in advance.

When the precast column units 10 are stacked by assembling a plurality of precast column units 10 as high as the planned column constructions, the precast column units 10 positioned at the final upper end as shown in FIG. (30).

That is, it can be seen that the coping portion 30 is installed in the state where the precast column unit 10 is installed at the uppermost end as shown in FIG. 1A. Basically, such a coping portion is a precast product manufactured in a trapezoidal cross- And is made of a concrete member.

In this case, it can be understood that the coping fin 30 and the washer and nut 33 are installed in the uppermost precast column unit 10 in particular.

The coping diluent 31 may be made of a member such as a deformed reinforcing bar or a steel bar, and the insertion reinforcing hole 13 may be formed at the lower end thereof as the connecting member 12, and a male screw portion may be formed at the upper end thereof.

First, the coping portion 30 also forms an insertion hole 34 extending upward and downward to fit the hollow sleeves 14 installed in the precast column unit 10.

The upper end of the upper reinforcing precast column unit 10 is exposed through the insertion hole 34 of the coping annular member 31 from the upper side so that the lower reinforcing insert 13 is exposed on the upper surface of the uppermost precast column unit 10 So that the mortar 15 is inserted into the filled hollow sleeve 14.

It can be seen that the upper end of the coping finishing material 31 is joined to the uppermost precast column unit 10 by using the washer and the nut 33 and the coping finishing material 31 to the upper coping portion 30.

However, the conventional pre-cast pier construction method may be advantageous in securing the leveling by separately using the pre-cast column unit 40 for level adjustment, but since the work is somewhat complicated and a plurality of the connection members 12 and the hollow sleeves 14 are used, There is a problem that the quality and workability may be somewhat lowered and the economical efficiency may be somewhat lowered.

Accordingly, it is possible to adjust the level more easily when stacking the precast column unit for precast pier and to further reinforce the weak connection part of the lower part (foundation) of the column structure and the lower precast column unit The present invention provides a precast pier construction method capable of sufficiently securing structural joining between precast column units in a lamination construction and having a construction block having excellent workability and workability.

To this end,

First, in order to adjust the leveling of the precast column unit, a leveling groove is formed at a predetermined depth on the upper surface of the foundation, a leveling plate is installed on the bottom surface of the leveling groove, and the bottom surface of the precast column unit is supported on the upper surface of the leveling plate do.

This makes it possible to prevent widening of the lower part (upper and lower bonding surfaces) on the precast column unit that is simply stacked on the upper surface of the foundation.

Second, the pre-cast column units are stacked by introducing a prestress by a tension member into the upper and lower precast column units. That is, a plurality of vertical through holes are previously formed in the precast column unit, and one end of a tension member, which is a PC stranded wire, is inserted into a communicating vertical through hole of the lowermost precast column unit and the uppermost precast column unit, Through the U-shaped sheath, to the upper surface of the uppermost precast column unit via the other vertical through-holes so that the tension member passes through the precast column unit and the foundation in the U-shape and is settled after the upper surface of the uppermost precast column unit So that the prestress is introduced into the upper and lower precast column units using the prestress.

Therefore, it is possible to sufficiently secure the structural joining performance of the upper and lower precast column units, and the excellent workability and workability can be achieved by introducing the prestress at a time into all the stacked upper and lower precast column units using a tension member.

Such tensions may be used for joining the upper and lower precast column units and for joining the coping units installed to be placed on the uppermost precast unit, so that the precast unit and the coping unit can be joined by the tension members.

Third, by using epoxy, shear grooves and shear keys on the joining surfaces of the stacked upper and lower precast column units, it is possible to solve the problems such as widening on the joining surfaces, and in particular, Thereby effectively preventing the installation of the unit and effectively managing the quality.

Fourth, when the precast column unit and the coping unit are completed, a fixed block is formed around the lowermost column unit by using the cast concrete and the concrete reinforcement around the lowermost column unit to reinforce the connection between the foundation and the lowermost column unit Thereby making it possible to reinforce the weak connection part.

At this time, since the concrete plays a role of integrating the leveling plate into the front end groove, it also serves to close the front end groove.

According to the present invention, a leveling operation that can prevent the widening of the precast column unit and the lower part of the precast column unit can be easily performed in the precast column unit stacking construction, which is very advantageous in terms of site construction and quality control.

In addition, the joining performance of the precast column units stacked up and down can be easily secured, and it is possible to construct the bridge piers more rapidly if the construction is highly advantageous for the high bridge construction.

Also, it is possible to more reliably reinforce the connection portions between the lower part of the foundation structure and the precast column unit, and thus it is possible to provide a precast bridge construction method with a fixing block, which is very suitable for structural performance and maintenance.

FIGS. 1A and 1B illustrate a prior art pre-cast pier construction trial and partial extract,
FIGS. 2A and 2B illustrate the construction of a precast pier with a fixed block of the present invention,
Figures 3a, 3b and 3c show the precast column unit of the present invention,
FIGS. 4A, 4B, 4C, and 4D are flowcharts of a precast bridge pier construction method with a fixed block of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings, which will be readily apparent to those skilled in the art. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. In order to clearly illustrate the present invention, parts not related to the description are omitted, and similar parts are denoted by like reference characters throughout the specification.

Throughout the specification, when an element is referred to as "comprising ", it means that it can include other elements as well, without excluding other elements unless specifically stated otherwise.

[Precast Bridge Bridge 100 with Fixing Block 160 of the Present Invention]

FIGS. 2A and 2B illustrate a construction and a perspective view of a precast bridge pier 100 (simply referred to as a precast bridge bridge) having a fixed block 160 of the present invention in a completed state.

2A and 2B, the precast bridge 100 includes a foundation 110, a plurality of precast column units 120, a tension member 140, a coping unit 150, and a fixing unit 160 ).

The foundation 110 may be made of cast concrete using a form in the form of a reinforced concrete box body as a lower foundation of the precast bridge pier 100, or it may be manufactured by a precast method.

The base 110 has a leveling groove 111 formed at a certain depth to adjust the leveling of the precast column unit 120 stacked on the upper surface. The leveling grooves 111 are formed in grooves larger than the cross sectional area of the precast column unit 120. The lower end of the precast column unit 120 is inserted into the leveling grooves 111, (Horizontal movement due to the vertical load) is restrained, so that a kind of shear block effect is obtained.

The U-shaped sheath 112, which is U-shaped and downwardly exposed, is formed on the leveling groove 111, and an upper surface of the U-shaped sheath 112 is exposed on the upper surface of the leveling groove 111.

The U-shaped sheath 112 is disposed to communicate with a vertical through-hole 121 of a precast column unit 120 to be described later. Referring to FIG. 2, a plurality of U- It can be seen that it is arranged inside the housing 110.

Further, a leveling plate 113 such as a steel plate is disposed on the bottom surface of the leveling groove 111.

That is, since the bottom surface of the leveling groove 111 formed by the concrete is not easy to secure the level, the leveling plate 111 such as a steel plate or the like is provided on the leveling groove 111 so that the precast column unit 120 can be horizontally supported. ).

At least one leveling plate 113 is disposed on the bottom surface of the leveling groove so that the upper surface of the leveling plate 113 is formed in a horizontal plane. In FIG. 2, the leveling plate 113 has a plurality of circular plates It can be seen that it is installed.

The lower end portion of the leveling plate 113 is inserted into the leveling groove 111 formed in advance in the course of the base fabrication, while the lowermost precast column unit 120 is stably mounted on the leveling plate 113 while leveling the leveling stably. The initial setting of the column unit 120 can be effectively performed.

In the leveling grooves 111 of the foundation 110, a plurality of precast column units 120 are stacked.

The precast column unit 120 is a precast column unit having a predetermined height, for example, a circular cross section. The precast column unit 120 may be formed as a solid cross-section, and may be formed as a hollow section, May be used.

The precast column unit 120 is formed such that a plurality of vertical through holes 121 formed so as to pass through the inside of the body portion 122 are spaced apart from each other on the concentric circle of the body portion.

The vertical through-holes 121 serve as passages for inserting the tension members 140, which will be described later, and the vertical through-holes 121 of the precast column unit 120, which are vertically stacked, are arranged to communicate with each other.

The upper and lower surfaces of the precast column unit 120 to be laminated are referred to as joining surfaces A1 and A2. It is very important to horizontally join these joining surfaces. This is because it is very difficult to adjust the pre-cast column unit 120 when the pre-cast column unit 120 is stacked without being joined horizontally on the joint surface because it is manufactured in advance, which greatly reduces the workability and workability This is because it becomes a factor.

In order to achieve a bonding performance of the precast column unit 120 which is laminated on the joining surfaces, the present invention uses shear keys and shear grooves.

The shear grooves 123 in the form of vertical grooves are formed in the upper and lower abutting surfaces A1 and A2 by inserting the shear keys 124. The shear keys 124 of the present invention include the vertical bar portions 124a, And a conical portion 124b at the upper end of the vertical portion is used.

The front end grooves 123 into which the vertical bars 124a are inserted are formed in the form of vertical grooves 123a spaced apart from each other on the upper or lower bonding surfaces A1 and A2 of the precast column unit 120, The lower or upper joining surfaces A2, A1 are formed in the shape of a conical part groove 123b and spaced apart from each other.

3A, a conical part groove 123b is formed on the lower joint surface A2 of the precast column unit 120 located at the center and a vertical groove 123a is formed on the upper joint surface A1 , And the precast column units 120 disposed at the upper and lower sides are shear-jointed to each other by the shear key 124. When the shear key 124 is used, the stacking of the precast column unit 120 due to lifting becomes much more advantageous.

In the present invention, a plurality of pre-cast column units 120 are bonded to each other at an initial height by a shear key, a shear groove, and a shear groove according to the height of the pier. In order to sufficiently secure the bonding performance by applying epoxy to the joint surfaces can do.

The precast column unit 120 is installed such that the lowermost precast column unit 120 is supported by the leveling plate 113 provided in the leveling grooves 111 of the foundation 110 and the intermediate precast column unit 120 One or more lamination units are stacked on the lowermost precast column unit 120 and a coping unit 150 is mounted on the uppermost precast column unit 120.

At this time, the vertical through holes 121 of the pre-cast column units 120, which are laminated, are arranged to communicate with each other in an upward and downward direction, and are arranged to communicate with the U-shaped sheath 112 of the foundation 110.

At this time, the uppermost precast column unit 120, the intermediate precast column unit 120, the lowermost precast column unit 120 and the foundation 110 are basically constrained to each other by an adhesive such as a shear groove, a shear key, and an epoxy However, it is difficult to expect the structural integration behavior.

Accordingly, the present invention is structurally integrated by a prestress using a tensile material 140 (denoted as 140a so as to be separated from a caffeine-installed tensile material) as shown in FIGS. 3B and 3C.

One end of the tension member 140 such as a PC stranded wire is inserted into the vertical through hole 121 of the uppermost precast column unit 120 so that the vertical part of the intermediate precast column unit 120, Through the through holes 121 and the U-shaped sheath 112 of the base 110,

The intermediate precast column unit 120 and the vertical through holes 121 of the uppermost precast column unit 120 are taken out via the other lower end precast column unit 120 and the intermediate precast column unit 120,

Both ends of the tensile material 140 are fixed after being tensed at the upper surface of the uppermost uppermost precast column unit 120 so that the precast column units 120 and the bases 110 are integrated with each other by press bonding by a prestress.

Since the tension member 140 has flexibility, it is easy to construct and a plurality of the tension members 140 can be installed according to the number of the vertical through holes, which is effective because the work type is not complicated.

For example, the coping portion 150 may be formed of a reinforced concrete structure having a trapezoidal shape formed by a flange portion extending horizontally on both sides of the body portion to support the bridge superstructure girder. And a fixing groove 152 is formed on the upper surface of the fixing hole 152 at a predetermined depth.

The tension member 140 of the uppermost precast column unit 120 is connected to other tension members using a coupler or the like and the connected tension member is exposed to the fixing groove 152 via the vertical through hole 151, But it may be difficult to introduce a prestress to such an extent that the large-sectioned coping portion 150 is integrally joined to the precast column unit 120 by such a method.

3B and 3C, the pre-cast column unit 120 and the vertical through-hole 121 and the U-shaped sheath 112 in the base 110 are not provided with a tension member, The tension member 140 (indicated by 140b so as to be separated from the tension member 140a installed in the precast column unit) is inserted into the vertical through hole 151 exposed in the fixing groove 152 on the upper surface of the upper surface 150,

Via the capping portion 150, the stacked uppermost precast column unit 120, and the U-shaped sheath 112 of the foundation 110,

The end portions of the tension members in the final coping portion fixing grooves pass through the other lowermost precast column unit 120, the intermediate precast column unit 120 and the uppermost precast column unit 120 and the vertical through holes 121 and 151 of the copings Tension, and fixation, thereby making it possible to integrate the coping portion and the foundation and precast column units.

When the use of the tensile material 140 is completed, the grouting material 130 such as a non-shrinkage mortar is injected into the vertical through holes, the fixing groove, and the U-shaped sheath to be cured and finished.

At this time, the connection between the lowermost precast column unit 120 and the foundation 110 is the weakest part of the horizontal load.

Therefore, the present invention is applicable particularly to the case where the reinforced concrete reinforcing bars 114 are drawn out from the foundation 110 around the lowermost precast column unit 120, And a constant concrete coating is formed around the lowermost precast column unit 120.

In the present invention, such a concrete covering is referred to as a fixing block 160. At this time, the concrete placed to form the fixed block is injected into the leveling grooves 111 of the foundation 110 to fill up the leveling grooves and the leveling plate to integrate them (filling material). Therefore, the leveled precast column unit 120, So that it is possible to maintain the horizontality of the images.

[Method of constructing the precast bridge 100 with the fixing block 160 of the present invention]

4A, 4B, 4C, and 4D illustrate a method of constructing a precast pier 100 in accordance with an embodiment of the present invention.

First, as shown in FIG. 4A, the foundations 110 are installed. That is, when the bridge is constructed, the foundation 100 is installed in the space where the bridge is to be constructed in order to dig the ground.

The base 110 has a leveling groove 111 formed on the upper surface thereof and also a fixed reinforcing bar 114 is drawn out and the U-shaped sheath 112 is exposed on the upper surface of the leveling groove 111. Further, a leveling plate 113 is provided on the bottom surface of the lever groove 111.

The lower end of the lowermost precast column unit 120 is inserted into the leveling hole 111 so as to be supported by the leveling plate 113 to complete the leveling operation.

At this time, the vertical through-hole 121 of the lowermost precast column unit 120 is arranged to communicate with the U-shaped sheath 112.

Next, as shown in FIG. 4B, the lower joint surfaces of the intermediate precast column unit 120 are brought into contact with the upper joint surfaces of the lowermost precast column unit 120 so as to be stacked.

At this time, epoxy (adhesive, not shown) is applied to the bonding surfaces and the shear grooves 124 are inserted into the front end grooves 123 as shown in FIG.

In FIG. 4B, it can be seen that a total of three precast column units 120 are stacked. The vertical through holes 121 of the precast column units 120 are arranged so as to communicate with each other.

4C, a tension member 140a is inserted into the vertical through hole 121 to connect the precast column unit 120 and the base U-shaped sheath 112 to another vertical through hole 121 The tension members 140 are fixed on the upper joint surface after they are tensioned. Such tension and fixing can be accomplished by using a hydraulic jack, an anchorage or the like not shown.

The foundation 100 and the precast column unit 120 are first pressed together by using a prestress to integrate them, and the grouting material 130 is injected into the resin through-hole and the U-shaped sheath to be cured.

The coping unit 150 is lifted and brought into contact with the upper joint surface of the uppermost precast column unit 120 and the coping unit 150 and the precast column unit 120 without the tension member are lifted, The tension member 140b drawn out to the front end groove of the final coping unit via the vertical through hole 121 and the U sheath 112 is also tightened after the tension so that the coping unit 150 and the precast column unit 120 It is unified by the prestress.

Of course, finishing with the grouting material is the same.

Next, as shown in FIG. 4D, concrete is placed on the inner side of the fixed reinforcing bar 114 on the inner side to be injected to the inside of the leveling groove 111, and the reinforcing bars 114 are fixed around the lowermost precast column unit, So that the connecting portion between the foundation 110 and the lowermost precast column unit 120 is reinforced.

It will be understood by those skilled in the art that the foregoing description of the present invention is for illustrative purposes only and that those of ordinary skill in the art can readily understand that various changes and modifications may be made without departing from the spirit or essential characteristics of the present invention. will be. It is therefore to be understood that the above-described embodiments are illustrative in all aspects and not restrictive. For example, each component described as a single entity may be distributed and implemented, and components described as being distributed may also be implemented in a combined form.

The scope of the present invention is defined by the appended claims rather than the detailed description and all changes or modifications derived from the meaning and scope of the claims and their equivalents are to be construed as being included within the scope of the present invention do.

100: Precast pier
110: Foundation
111: Leveling groove
112: U-shaped sheath
113: Leveling plate
114:
120: Precast column unit
121: vertical through hole 122: body part
123: shear groove 123a: vertical groove
123b: conical part groove
124: Shekhki
124a: vertical bar
124b:
130: Grouting material
140: Tension material
150:
151: Vertical through hole
152: Settling groove
160: fixed block

Claims (3)

a leveling groove 111 is formed on an upper surface of the leveling groove 111 and a base 110 having a U-shaped sheath 112 extending downward is disposed on the bottom surface of the leveling groove 111,
(b) a vertical through hole 121 is formed in the body portion 122 so as to communicate with the U-shaped sheath 112 so as to be exposed to the upper and lower bonding surfaces A1 and A2, and the lowermost precast column Stacking the intermediate and uppermost precast column units on the uppermost surface of the lowermost precast column unit after the lower end of the unit is inserted and supported;
(c) The uppermost precast unit, the intermediate precast unit, and the tension member 140a passing through the vertical through-hole 121 of the lowermost precast column unit and a part of the U-shaped sheath 112 of the foundation 110, Fixing the pre-cast column unit (120) and the foundation (110) by introducing a prestress into the pre-cast column unit (120) and integrating them;
(d) installing a coping portion on the upper surface of the uppermost precast column unit where a fixing groove is formed on the upper surface and a vertical through hole extending downward from the fixing groove is exposed on the lower surface; And
(e) a U-shaped sheath (not shown) of the foundation 110 which is not passed through the vertical penetration hole 121 of the coping unit 150, the uppermost precast unit, the intermediate precast unit, and the lowermost precast column unit, Fixing the prestressing member 140b on the upper surface of the fixing groove of the coping unit after tension to introduce the prestress into the precast column unit 120, the base 110 and the coping unit 150 to integrate the prestressing unit In addition,
In the step (a), the leveling plate 113 is disposed on the bottom surface of the leveling groove 111 at a position where the U-shaped sheath is not blocked, and the lowermost precast column unit 120 is placed on the leveling plate 113 And,
Placing the concrete around the lowermost precast unit to form the fixed block 160 so that the fixed reinforcing bar 114 drawn up to the base leveling groove is embedded after the step (e) The concrete is injected into the leveling grooves 111 of the foundation 110 to integrate the leveling grooves 111 and the leveling plate 112 so as to integrate them to maintain the leveling of the precast column units 120 leveled. A method of precast pier construction with a building block. The method according to claim 1,
The stacking construction of the middle and uppermost precast column units on the uppermost surface of the lowermost precast column unit
The shear grooves 124 provided in the front end grooves 123 of other precast column units are inserted into the front end grooves formed in the upper and lower joining surfaces A1 and A2 of the precast column unit so that the precast column units are vertically joined ,
Wherein the shear key is formed by integrally forming the vertical bar portion and the conical portion above the vertical bar portion so that the conical portion is inserted into the conical portion groove of the front end groove and the vertical portion is inserted into the vertical groove. Precast pier construction method. delete

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