KR101204040B1 - precast concrete member and assembled concrete abutment of bridge - Google Patents

Abstract

Precast concrete member according to the present invention and prefabricated concrete shift using the same, including the base portion 110 and the wall portion 120, the insertion groove is fitted into the wall portion is assembled on the upper surface of the base portion 110 A plurality of precast concrete members 121 and 122 are formed, and the wall portion 120 is fitted along the insertion groove 111 and continuously connected to each other to be assembled to the foundation 110. The precast concrete member, the precast concrete member 121, 122 is manufactured by a centrifugal molding method, and has a pair of mating surfaces facing each other to be continuously connected to each other, any one Shear keys 121a and 221a protrude from the mating surface, and shear key grooves 121b and 221b into which the shear key is inserted are formed on the other mating surface. According to this configuration, by using the precast concrete member, but by eliminating the mortar work and on-site pouring work, there is an effect that the construction can be significantly shortened and high-strength high-quality construction by reducing the process quickly.

Description

Precast concrete member and assembled concrete abutment of bridge

The present invention relates to a precast concrete member and a prefabricated concrete shift using the same. More particularly, the present invention relates to a precast concrete member and a prefabricated concrete shift which eliminates the need for a separate temporary wall for the installation using the same.

In general, bridges are composed of structures of various types and shapes depending on the type of facility to be supported and the purpose of use, and its role should be sufficient strength and durability to safely maintain the function of the bridge and facilities supported by the bridge. .

In order to construct a conventional bridge shift, as shown in FIG. 1, the temporary earth wall 11 is constructed to secure a space for the shift A, and the foundation pile 12 is constructed through an excavation process. After constructing the lower foundation with rebar, formwork, and concrete, the walls were constructed with rebar, formwork, and concrete, and then backfilled to construct the superstructure.

 The shift construction of the bridge as described above is complicated in a series of work processes, difficult to control the quality of each work process, the construction period is very long, and is not economical in terms of construction costs.

Therefore, in recent years, the construction which requires the use of a precast concrete member and which does not need a separate temporary block wall for alternating installation is performed.

Alternately using a precast concrete member, a square or H-shaped precast concrete member 13 (14) as shown in Figs. 2A and 2B is opposed to the space M1 of the connecting portion ( M2) is attached to the wet joint method by the site work that continuously connects the wall pile by pouring concrete (mortar), and by placing the cap concrete on the upper part and installing the teaching device on it. The concrete members were placed on the site by connecting and reinforcing the concrete members with connecting reinforcing bars, and a wing wall was installed on the site to support the filling part (the part filled with the backfill material) around the shift.

An object of the present invention is to provide a precast concrete member and a prefabricated concrete shift that can be used to reduce the process and quickly construction by eliminating the mortar work and on-site pouring work to significantly shorten the construction period and can be constructed with high strength and high quality. .

The precast concrete member according to the present invention is manufactured by a centrifugal molding method, and is provided with a pair of coupling surfaces facing each other so as to be continuously connected to each other, one of the coupling surfaces protrudes a shear key, and the other coupling surface is Characterized in that the shear key groove is formed that the shear key is inserted.

The prefabricated concrete shift according to the present invention includes a base portion and a wall portion, wherein an upper surface of the base portion is formed with an insertion groove into which the wall portion is fitted and assembled, and the wall portion is fitted along the insertion groove and connected continuously. And formed of a plurality of precast concrete members assembled to the foundation, the precast concrete members having a pair of mating surfaces facing each other so as to be continuously connected to each other, a shear key protrudes on one mating surface, The other coupling surface is characterized in that the shear key groove is formed is the shear key is inserted.

The shear key and the shear key groove are continuously formed along the longitudinal direction or the transverse direction of the engagement surface, or intermittently formed along the longitudinal or transverse direction of the engagement surface.

The first precast concrete member and the last precast concrete member of the wall portion are flanged precast concrete members supporting the fill portion.

The flanges of the first precast concrete member and the last precast concrete member are connected to each other by reinforcing steel wires.

The flange of the first precast concrete member and the last precast concrete member is extended downward, the insertion portion is formed in the base portion, the extension of the flange may be fitted into the insertion groove.

A plurality of through holes are formed in the precast concrete member, and a tension member for generating prestress is inserted into the through holes of the precast concrete member connected continuously.

The through hole includes a transverse steel wire through hole and a transverse steel wire through hole, and the transverse steel wire through hole is provided with a tension member for generating prestress mainly for assembling a precast concrete member and inserted therein. The steel wire through hole is provided with a tension member for generating prestress to support the back earth pressure of the wall portion.

The precast concrete member is provided with holes for drainage piping or electrical wiring.

A plurality of support piles embedded in the ground layer to support the foundation are connected to the lower portion of the foundation.

The upper part of the precast concrete member is formed with a latching portion for catching a girder, the seating device for supporting the girder is installed.

According to the precast concrete member according to the present invention and prefabricated concrete shift using the same, the precast concrete member can be used to omit the mortar work and the site casting work, thereby reducing the process and constructing it quickly, significantly shortening the construction period and constructing high-quality high-quality construction. It can be effective.

1 is a view showing a conventional shift construction method,
Figure 2 is a cross-sectional view for explaining the alternate construction method using a conventional precast concrete member,
3 is a schematic configuration diagram showing a bridge to which the present invention is applied;
4 is a perspective view showing a prefabricated concrete shift according to the present invention,
5 is a detailed view showing another example in which the tension member of FIG. 4 is mounted;
6 is a perspective view showing the precast concrete member of FIG.
7 is a perspective view showing another example of the precast concrete member of the prefabricated concrete shift of the present invention;
8 is a perspective view showing an embodiment in which the second precast concrete members of the present invention are connected by a steel wire,
9 is a perspective view showing an embodiment in which the second precast concrete member of the present invention is reinforced;
10A, 10B, and 10C are a plan view, an elevation view, and a left side view showing a precast concrete member of the present invention in which a longitudinal steel wire through hole is further formed;
11 (a) and 11 (b) are an operating state diagram of the steel wire member provided in the longitudinal steel wire through hole of FIG. 10;
12 is a partial plan view showing another embodiment of the shear key and shear keyway according to the present invention (including separation and assembly),
Figure 13 is a partial plan view (including a separate and assembled state) showing another embodiment of the shear key and shear keyway of the present invention.

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

3 is a schematic block diagram showing a bridge to which the present invention is applied. As shown, a plurality of bridges 102 are provided at a predetermined distance between both side shifts (100: prefabricated concrete shifts) of the bridge to which the present invention is applied, and each of the shifts 100 and each of the bridges 102 The girder 104 is installed over the top. On the girder 104, a slab (not shown) through which a vehicle or the like can pass is installed, and the girder 104 is mounted on the shift 100 and the pier 102 via the bridge device 106.

The abutment device 106 has a structure corresponding to vertical loads, vibration displacements, etc. with respect to the girder 104 and the slab, and flexibly corresponding to horizontal loads, bending, rotational displacement, and telescopic displacement, An elastic member such as rubber, a bearing, a damper, or a seismic isolation system having a good damping function against an earthquake or wind load is a structure that transmits a load to the shift 100 and the pier 102 through a mount.

The pier 102, the girder 104 and the bridge device 106 is a general structure that can be configured in a variety of structures, so a detailed description thereof will be omitted.

4 is a perspective view showing a prefabricated concrete shift 100 according to the present invention. As shown in the figure, the prefabricated concrete shift 100 includes a base portion 110 in the form of a mat plate, and a wall portion 120 fitted to the foundation portion 100.

On the upper surface of the base portion 110, the wall portion 120 is inserted and erected so that the insertion groove 111 is assembled along the longitudinal direction, such as bolt nut (not shown) is formed, the lower portion of the base portion 110 There are a plurality of support files 112 embedded in the ground layer (not shown) to support the base 110.

The wall portion 120 is formed of a plurality of precast concrete members 121 (first: precast concrete members) that are fitted along the insertion groove 111 and continuously connected to each other to be assembled to the foundation 110. The first precast concrete member and the last precast concrete member of the wall portion 120 are flanges (122b, 122'b) for supporting the fill portion (minced portion filled with backfill) body 122a, 122 ' precast concrete members 122 and 122 ': second precast concrete members protruding horizontally from the top of a).

The precast concrete members 121, 122, 122 ′ are fixed to the foundation 110 by wires W so that they do not fall during soil filling.

As shown in FIG. 6, a shear key 121a is formed to protrude on one side (one coupling surface) of the first precast concrete member 121, and the shear key 121a is formed on the other surface (the other coupling surface). Shear key grooves 121b to be inserted are formed, and adjacent precast concrete members are continuously connected to each other. The shear key 121a and the shear key groove 121b are continuously formed along the longitudinal direction of the coupling surface. The shear key and shear key groove may be formed along the transverse direction of the mating surface, and the shear key and shear key groove may be intermittently formed along the longitudinal or transverse direction of the mating surface.

It is preferable that the shear key or shear key groove is not formed on the outer surface of the second precast concrete members 122 and 122 'to improve the appearance quality (shown in FIG. 4).

The first and second precast concrete members 121, 122, 122 ′ are provided with a plurality of transverse steel wire through holes H1 and penetrate the transverse steel wires of the precast concrete members connected continuously. In the hole H1, a tension member 123 for pre-stressing the main assembly of the precast concrete member is inserted and fixed by the fixing unit 124.

As shown in FIG. 5, a guide tube 125 is inserted into the steel wire through hole, and the tension member 123 is inserted into the guide tube 125 to be fixed by the fixing unit 124 '. It may be assembled.

The first and second precast concrete members 121, 122, 122 ′ are provided with a plurality of drain pipes or holes H 2 for electrical wiring. Conventional shifts are installed so that utility lines such as electrical wiring or drainage pipes are exposed to the outside, but in the present invention, utility lines such as electrical wires or drainage pipes are installed inside the bridge through the holes H2, thereby improving aesthetics. do.

The upper part of the precast concrete member 121, the engaging portion 126 is formed is caught by the end of the girder 104 is installed, the cross-section device for supporting the girder 104 on the horizontal surface of the engaging portion 126 106 is optionally installed.

The precast concrete members 121, 122, 122 'are made of a PHC precast concrete member produced by a centrifugal molding technique.

The PHC (Pretentioned spun High strength Concrete) file is a high-strength pile based on the pretension method of concrete compressive strength of 78.5 N / mm2 (800Kgf / ㎠) made by applying centrifugal force, and the concrete allowable compressive stress is very large. (Prestressed Concrete) It can withstand greater axial load than pile, and evenly introduces prestresses as required in the section formed of concrete with compressive strength of 800Kgf / ㎠ or more, and is excellent in impact strength. Since it completely absorbs the tensile stress caused by the reflected wave, there is no crack, and even a hard layer in the middle, which is difficult to hit with a conventional PC pile, can be easily penetrated into a deeper and harder strata. Since the stress is large, it is widely used as the most suitable pile for seismic design that receives both axial and horizontal forces.

There are many known methods for manufacturing PHC piles. The most common method for manufacturing centrifugal moldings is the use of multiple PC steel rods with a diameter of 7 to 13 mm as an axle. After winding ordinary steel wire (diameter 3.2mm) into spiral bar, spot weld the contact between shaft and spiral muscle to make reinforcing bar, and then cast concrete at 70% of tensile strength to reinforce bar After being embedded in the concrete, the concrete was chopped by centrifugal molding, and then the high temperature and high pressure curing (cure condition: charged to the inside of the autoclave tank and heated up to 180 ° C in 4 hours with the air pressure raised to 10 atm). After 3 hours, the mixture is prepared by slow cooling to room temperature).

The support pile 112 may also be manufactured and assembled in a precast form manufactured by the PHC pile manufacturing technique.

7 is a perspective view showing another example of the precast concrete member of the prefabricated concrete shift of the present invention. In this embodiment (Fig. 7), the shear key 221a is intermittently arranged along the longitudinal direction of the first precast concrete member 221 on one side (one coupling surface) of the first precast concrete member 221. The front key groove 221b into which the front end key 221a is inserted is intermittently arranged and protrudingly formed on the other side surface (the other side of the mating surface), so that the adjacent precast concrete members are continuously connected to each other.

Since the steel wire through hole H1, the locking portion 226, the stapling device 206, and the like are the same as those in the embodiments of FIGS. 3 and 5, detailed description thereof will be omitted.

Figure 8 is a perspective view showing an embodiment in which both sides of the second precast concrete member of the present invention connected by a steel wire. As shown in the present embodiment, the flanges of the second precast concrete members 122 and 122 'installed on both sides of the wall part 120 are connected to the reinforcing steel wire 323 to reinforce the wall part 120. It is a state. This embodiment prevents damage such as the flanges opening when the backfill is filled between the flanges of the second precast concrete members 122 and 122 '. Since the rest of the configuration of FIG. 8 is the same as that of the embodiment of FIG. 4, detailed description thereof will be omitted.

9 is a perspective view showing an embodiment in which the second precast concrete member of the present invention is reinforced. As shown, the present embodiment is a flange of the second precast concrete member 422 in the wall portion 420 consisting of the first precast concrete member 421 and the second precast concrete members 422 and 422 '. The lower side extends, and the lower side of the flange of the second precast concrete members 422 and 422 ′ is fitted into the insertion groove 411 of the base 410 to reinforce the wall 420. Since the rest of the configuration including the support file 412 is the same as the embodiment of FIG. 3, detailed description thereof will be omitted.

10A, 10B, and 10C are a plan view, an elevation view, and a left side view showing a precast concrete member of the present invention in which a longitudinal steel wire through hole is further formed. As shown in the drawing, the first precast concrete member 521 is provided with a plurality of longitudinal steel wire through holes H3 in addition to a plurality of horizontal steel wire through holes H1, and is installed in the through holes H3. Prestress is generated in the first precast concrete member 521 by the tension member (not shown). That is, the longitudinal steel wire through hole (H3) is provided with a tension member for generating a prestress to support the back earth pressure of the wall portion.

On the other hand, the longitudinal steel wire through-hole (H3) for installing the tension member in the second precast concrete member may be formed, of course.

11 (a) and 11 (b) are operation state diagrams of the steel wire member provided in the longitudinal steel wire through hole of FIG. As shown in Fig. 11 (a), when the tension member provided in the longitudinal steel wire through hole is tensioned, a resistance force that resists the backfill side earth pressure on the back surface of the precast concrete member 521 (as shown in Fig. 11 (b)). ) Can be expected because of the support function.

Meanwhile, the present invention is made of a precast concrete member 721 having a shear key 721a and a shear key groove 721b formed in a wedge shape as shown in FIG. 12, or as shown in FIG. 13, a shear key 821a and a shear key 721a. The shear key groove 821b may be made of a precast concrete member 821 formed in an annular shape.

The precast concrete member of the present invention may be provided with a plurality of hollow portions (through holes or grooves) to reduce the weight.

According to the precast concrete member according to the present invention and prefabricated concrete shift using the same, since the precast concrete member is manufactured using a centrifugal molding method, it is possible to manufacture a high quality member in large quantities, and to apply the mortar for attaching the precast concrete member. It is possible to install the device by only assembling (dry joining) the members without the work and placing the concrete on site, so the effect of shortening the construction period is excellent, and the pre-stress is generated by the tension member on the wall part. There is no fear that the wall part will fall during the soil filling after assembly. Since precast concrete members with flanges are assembled on the left and right sides of the wall part, the assembly work is easy and quick construction is possible. It forms so utilities It is easy to install the tee line.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is evident that many alternatives, modifications and variations will be apparent to those skilled in the art. The scope of the technical protection shall be determined by the technical idea of the appended claims.

100: shift 102: pier
104: girders 106, 206: stapling device
110: foundation 111: insertion groove
112: support file 120: wall portion
121, 221: first precast concrete member
121a, 221a: Shear Key 121b, 221b: Shear Key Groove
122, 122 ': second precast concrete member
122a, 122'a: body 122b, 122'b: flange
123: tension member 124, 124 ': anchorage
125: guide tube 126, 226: locking portion
H1: Transverse steel wire through hole H2: Pipe or wiring hole
H3: Longitudinal steel wire through hole

Claims (13)

delete delete delete Including the foundation and the wall,
Insertion grooves are formed on the upper surface of the base portion is inserted into the wall is assembled, the wall portion is formed of a plurality of precast concrete member is fitted along the insertion groove and connected continuously to be assembled to the foundation,
The precast concrete member has a pair of coupling surfaces facing each other to be continuously connected to each other, one of the coupling surface is a shear key protrudes, the other coupling surface is formed with a shear key groove into which the shear key is inserted,
And a plurality of through holes are formed in the precast concrete member, and a tension member for generating prestress is inserted into the through holes of the precast concrete member continuously connected to each other. The method of claim 4,
And the first precast concrete member and the last precast concrete member of the wall portion are precast concrete members with flanges supporting the fill portion. The method according to claim 5,
And the flanges of the first precast concrete member and the last precast concrete member are connected to each other by reinforcing steel wires. The method according to claim 5,
The flange of the first precast concrete member and the last precast concrete member is extended to the lower side, the base portion is formed with an insertion groove,
Prefabricated concrete shifts characterized in that the extension of the flange is fitted in the insertion groove. delete The method of claim 4,
The through hole includes a transverse steel wire through hole and a longitudinal steel wire through hole,
Prefabricated concrete shifts, characterized in that the transverse steel wire through-hole is provided with a tension member for generating prestress mainly for the assembly of the precast concrete member. The method of claim 4,
The through hole includes a transverse steel wire through hole and a longitudinal steel wire through hole,
Prefabricated concrete shifts characterized in that the longitudinal steel wire through-hole is provided with a tension member for generating a prestress to support the back earth pressure of the wall portion. The method of claim 4,
The precast concrete member is a prefabricated concrete shift, characterized in that the hole for drainage piping or electrical wiring is formed. The method of claim 4,
Prefabricated concrete shifts, characterized in that the lower portion of the foundation is embedded in the ground layer is connected to a plurality of support piles for supporting the foundation. The method of claim 4,
The upper part of the precast concrete member is formed with a latching portion is caught,
Prefabricated concrete shift, characterized in that the locking unit is installed on the engaging portion supporting the girder.

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