KR101251118B1 - A manufacturing method of a composite steel box girder using prestressed concrete for a positive moment area of a bridge - Google Patents

Abstract

The present invention synthesizes the prestressed concrete in the lower flange of the steel box girder which is a tension member in the steel box composite girders installed in the constant moment section of the simple bridge or continuous bridge, thereby greatly increasing the bending rigidity of the steel box composite girders in the constant moment section of the bridge It is an object of the present invention to provide a steel box composite girder that can increase the drastically reduce deflection due to live loads and lower the height of the steel box composite girder.
In the present invention, in order to achieve the above object, in the steel box composite girder combining the lower flange 4 and the prestressed lower concrete 11 of the steel box girder 5 installed in the constant moment section of the bridge,
Shear connector (8) is installed on the upper surface of the lower flange (4) of the steel box girder (5) vertically and laterally at predetermined intervals; A spacer 18 or a thread level adjusting device 29 is installed between the upper surface of the lower flange and the lower surface of the precast lower concrete 9 so that the upper surface of the lower flange 4 and the lower surface of the precast lower concrete 9 can be spaced apart from each other. Becoming;
Both ends are formed so that the cross section is enlarged, the duct 16 is installed in the longitudinal direction of the steel box girder so that the prestressing tendon 19 is installed, and fixing devices at both ends for tension and fixing of the tendon 19. The steel box girder 5 is installed so that the precast lower concrete 9 having the through hole 12 formed in the vertical direction is inserted into the shear connector 8 provided on the upper surface of the lower flange 4. Installed on an upper portion of the lower flange 4;
The tendon 19 is installed in the duct 16 formed in the longitudinal direction of the girder of the precast lower concrete 9, and the tendon 19 is tensioned and fixed by the fixing device 15 installed at both ends thereof, thereby pre-stressing. After the introduction, the grout is injected into the duct 16; The non-shrink mortar 20 is injected into the through-hole 12 to lower flange 4 and prestressed lower concrete of the rigid girder 5 11) is integrated; characterized in that consisting of.

Description

A manufacturing method of a composite steel box girder using prestressed concrete for a positive moment area of a bridge}

The present invention relates to a method for manufacturing a steel box composite girder in which a prestressed concrete is synthesized in a steel box girder bottom flange installed in a constant moment section of a simple bridge or continuous bridge.

1 is a side view of a simple steel box composite girder simple bridge in the prior art. In general, in the case of the steel box composite girder simple bridge, since the constant moment is applied to the entire section, the upper flange 3 of the steel box girder 5 is combined with the concrete base plate 1 to resist the bending compressive force, and the steel box girder ( The lower flange 4 of 5) is configured to resist bending tension.

2 (a) and 2 (b) are cross-sectional views of an open steel box girder and a closed steel box girder, respectively. In Korea, steel box composite girder bridges have mainly used closed steel box girders, but recently, open steel box girders have been evaluated to be more economical than closed steel box girders. Girders are increasingly used.

With the continuous development of steel manufacturing technology, attempts are being made to apply steel box girder bridges in recent years as high-strength plates have been produced, which have significantly increased strength compared to the past. However, when the high strength steel is used, the member becomes thinner and the cross section becomes smaller, so that the cross section secondary moment of the girder becomes smaller, which causes a problem that the deflection due to the live load increases.

Bridges must satisfy both structural safety, such as allowable stress (or strength) conditions, and usability, such as maximum allowable deflection conditions for deflection due to live loads such as vehicle loads. However, when a material having a very high allowable stress, such as a high strength steel, is used, a sag caused by a relatively high load is often satisfactory compared to the use of a material having a small allowable stress.

In addition, there is a case in which the mold height of the girder needs to be lowered due to the mold and the problem.In the case of the steel box girder bridge, even if the mold height is low, the high stress steel can easily satisfy the stress condition, but the sag may not be satisfied due to the large sag. many. In the case of railway bridges, the maximum allowable deflection is smaller than that of road bridges, but the live load is much larger, making it more difficult to satisfy the deflection conditions. Of course, in this case, to meet the live load deflection conditions, it is necessary to increase the amount of steel significantly, but it is difficult to avoid economic inefficiency with this method.

Concrete is a very inexpensive material compared to steel. In particular, concrete is an excellent cost-effective material for compressive forces. Figure 3 is another example of the prior art steel box composite girders in the continuous bridge, the upper flange (3) of the steel box girder (5) is synthesized with the concrete floor plate (1) in the whole section, the steel box girders in the continuous point portion of the parent section The lower flange (4) of (5) is combined with the cast-in-place lower concrete (7) so as to resist the bending compressive force of the continuous section nominal section, thereby reinforcing the rigidity of the steel box girder in the continuous point section economically. It is a double composite steel box girder bridge. As such, the double composite steel box girder bridge is an economical method that can be used as a compressive member in the continuous section parent cement section by effectively utilizing the excellent resistance against the compressive force of concrete in the parent cement section.

However, concrete is a very efficient material for compressive forces but a very weak material for tensile forces and cannot be used as a substitute for steel when tensile forces are applied. By the way, wire rods such as stranded wire are about 5 times stronger than steel plate, but the price is about 1.3 times higher than that of steel plate. Prestressed Concrete (Prestressed Concrete or PSC) is able to resist a predetermined tensile strength by tensioning the tendon, such as the stranded wire to precede the compressive stress to the concrete and can create a tensile member having a very high stiffness (stiffness).

As described above, the prestressed concrete is an economical material having great rigidity while being able to resist a certain tensile force. Therefore, by using this as a tension member in the constant moment section of the steel box composite girder bridge, a new method of synthesizing steel and concrete is required to maximize the structural efficiency of the steel and effectively satisfy the maximum allowable deflection condition of the bridge.

The present invention, in order to solve the problems of the prior art, by synthesizing prestressed concrete in the steel box girder lower flange of the tension member in the steel box composite girders installed in the constant moment section of a simple bridge or continuous bridge, the constant moment of the bridge It is an object of the present invention to provide a method for manufacturing a steel box composite girder that greatly increases the bending rigidity of the steel box composite girder in the section, greatly reducing the deflection due to live loads and lowering the height of the steel box composite girder.

The present invention is provided in order to achieve the above object in the steel box composite girder synthesized the lower flange 4 and the prestressed lower concrete 11 of the steel box girder (5) installed in the constant moment section of the bridge ,
Shear connector (8) is installed on the upper surface of the lower flange (4) of the steel box girder (5) vertically and laterally at predetermined intervals; A spacer 18 or a thread level adjusting device 29 is installed between the upper surface of the lower flange and the lower surface of the precast lower concrete 9 so that the upper surface of the lower flange 4 and the lower surface of the precast lower concrete 9 can be spaced apart from each other. Becoming;
Both ends are formed so that the cross section is enlarged, the duct 16 is installed in the longitudinal direction of the steel box girder so that the prestressing tendon 19 is installed, and fixing devices at both ends for tension and fixing of the tendon 19. The steel box girder 5 is installed so that the precast lower concrete 9 having the through hole 12 formed in the vertical direction is inserted into the shear connector 8 provided on the upper surface of the lower flange 4. Installed on an upper portion of the lower flange 4;
The tendon 19 is installed in the duct 16 formed in the longitudinal direction of the girder of the precast lower concrete 9, and the tendon 19 is tensioned and fixed by the fixing device 15 installed at both ends thereof, thereby pre-stressing. After introduction, injecting grouting into the duct (16);
Injecting the non-shrink mortar 20 into the through-hole 12 to integrate the lower flange 4 and the prestressed lower concrete 11 of the composite girder 5, characterized in that the configuration.

The steel box composite girder manufacturing method of the present invention as described above reduces the amount of steel by sharing a portion of the tensile force acting on the steel box girder lower flange to reduce the amount of steel, the bridge of the bridge using the large rigidity of the prestressed concrete By increasing the cross-section secondary moment of the steel box composite girder in the constant moment section, the deflection due to the live load of the bridge is greatly reduced, thereby reducing the mold height of the steel box composite girder economically.

1 is a side view of a conventional steel box composite girder simple bridge
2 (a) and 2 (b) are cross-sectional views of an open steel box girder and a closed steel box girder, respectively.
3 is a side view of a double composite steel box girder continuous bridge that is another example of the prior art
Figure 4 is a side view of a steel box composite girder simple bridge of one embodiment of the present invention
FIG. 5 is a cross sectional view of the span center portion of FIG.
Figure 6 (a) is a perspective view of the precast lower concrete segment of the present invention
Figure 6 (b) is a side view showing a process of bonding the precast lower concrete segment of the present invention
Fig. 6 (c) is a cross-sectional view showing the introduction of prestress after joining the precast lower concrete segments of the present invention.
6 (d) is a cross-sectional view in which the lower flange and the prestressed lower concrete are synthesized
7 is a cross-sectional view of the device for adjusting the thread level.
8 through 11 are cross-sectional views of other embodiments of FIG.
12 (a) and 12 (b) are perspective views of reinforcing steel tubes
13 is a stress diagram when the reinforcing steel is used and not used in the through-hole
14 is a side view of an embodiment using prestressed lower concrete in a continuous bridge

In order to achieve the above object, part of the bending tension acting on the lower flange 4 in the constant moment section of the steel box composite girder bridge is divided by the prestress lower concrete 11 in which prestress is introduced into the precast lower concrete 9. In order to,
Shear connector 8 is vertically and horizontally installed on the upper surface of the lower flange 4 of the steel box girder 5 at predetermined intervals, and the upper surface of the lower flange 4 and the lower surface of the precast lower concrete 9 are separated from each other. The spacer 18 or the thread level adjusting device 29 is installed between the upper surface of the lower flange and the lower surface of the precast lower concrete 9.
In addition, both ends are formed so that the cross section is enlarged, and the duct 16 is installed in the longitudinal direction of the steel box girder so that the prestressing tendon 19 is installed, and fixed to both ends for tension and fixation of the tendon 19. The steel box girder 5 is installed such that the precast lower concrete 9 having the device 15 and the through hole 12 formed in the vertical direction is inserted into the shear connector 8 provided on the upper surface of the lower flange 4. It is installed on the upper flange 4 of the bottom.
The precast lower concrete 9 is provided with a tendon 19 in the duct 16 formed in the longitudinal direction of the girder, and the tendon 19 is tensioned and fixed by the fixing device 15 provided at both ends to reduce prestress. After the introduction, grout is injected into the duct 16, and the non-shrink mortar 20 is injected into the through hole 12 so that the prestressed lower concrete 11 is lower flange of the steel box girder 5. (4) is synthesized on top.
The construction of the steel box composite girder is shown in a side view of the steel box composite girder simple bridge of one embodiment of the present invention of FIG.

6 (a) to 6 (d) illustrate a process in which the precast lower concrete segment 10 is synthesized in the lower flange 4 of the steel box girder bridge. Figure 6 (a) is a perspective view of the precast lower concrete segments manufactured to a size that can be installed in the steel box girders. The precast lower concrete segment 10 is usually bonded in the girder longitudinal direction (crossing direction) using epoxy, in which case the uneven shear key 13, 14 matches the joint surface of the precast lower concrete segment 10. Made by casting. However, in the case of joining the precast lower concrete segment 10 using non-shrink mortar or the like, a concave shear key is provided at the joint without performing a match casting.

The precast lower concrete segment 10 located at both ends of the precast lower concrete segment 9 where all of the precast lower concrete segments 10 are bonded is used for tension and fixation of tendons 19 such as PS strands. The cross section is enlarged and manufactured to facilitate the installation of the fixing device 15.

A tendon 19 is installed on the precast lower concrete 9 and tension-fixed thereto, and grout is injected into the duct 16 on which the tendon 19 is installed to the precast lower concrete 9. The prestressed lower concrete 11 into which the prestress is introduced is coupled using the lower flange 4 of the steel box girder and the shear connector 8 so that the plurality of through holes 12 are vertically inserted so that the shear connector can be inserted. The duct 16 for inserting the tendon 19 in the longitudinal direction of the steel box girders 5 is installed.

Bonding of the precast lower concrete segments 10 is performed by sealing the lower surface and the side surface between the bonding surfaces and then pouring non-shrink mortar or the like, or applying epoxy to the bonding surfaces, and then precast lower concrete segments 10. A predetermined compressive force is introduced and joined using a temporary steel bar 17 or the like installed on the upper part. At this time, the precast lower concrete segment 10 is installed at a slight interval on the upper surface of the lower flange 4 of the steel box girder 5, for this purpose, a spacer 18 or a screw level adjusting device 29 is used.

Since the spacer 18 installed between the lower flange 4 and the precast lower concrete 9 is not easy to adjust the spacing including the manufacturing error, the spacer 18 may be used instead of the spacer 18 to freely adjust the spacing. As shown in Fig. 7, the level adjusting nut 27 is provided on the lower surface of the precast lower concrete 9, and the screw type level adjusting device 29 in which the level adjusting bolt 28 is coupled to the level adjusting nut 27 is used. . These screw leveling devices 29 usually require four per precast lower concrete segment. It is not necessary to remove the level adjusting bolt 28 of the screw-type level adjusting device 29, but if it is to be removed for reuse or the like, if grease or the like is applied to the level adjusting bolt 28 before synthesis, even after curing of the non-shrink mortar Removal is possible.

FIG. 6 (b) is a side view illustrating a process of bonding the precast lower concrete segment of FIG. 6 (a) with epoxy. When joining the precast lower concrete segment 10 in the upper portion of the lower flange 4 of the steel box girder 5 when the shear connector 8 is previously installed in the upper portion of the lower box 4 of the steel box girder It is appropriate to form a slot-type through hole 12 to secure the necessary clearance in the.

If bolted studs are used as the shear connector (8), only the nut (22) is installed on the upper surface of the lower flange (4) during assembly of the precast lower concrete segment (10). If there is no large play in the axial direction, the circular through hole 12 may be formed.

When the bonding of the precast lower concrete segments 10 is completed and the epoxy or mortar used as the bonding material reaches a predetermined strength, the tendon 19 is inserted into the duct 16 and precast as shown in FIG. 6 (c). Prestress is introduced by tension from both ends of the lower concrete. It is safe to install an appropriate injury prevention hole to prevent unexpected injuries (floating) of the prestressed lower concrete 11 due to the tendency of tendons during the introduction of the prestress by the tendons 19.

FIG. 6 (d) is a cross-sectional view showing that the non-shrink mortar 20 is injected into the through hole 12 of the precast lower concrete 9 into which prestress is introduced, and then synthesized with the steel box girder lower flange. Since there is a space between the prestressed lower concrete 11 and the lower flange 4, the non-shrink mortar 20 having fluidity is injected and integrated.

Synthesis of the lower flange 4 and the prestressed lower concrete 11 by using the non-shrink mortar 20 is carried out at the stage required for synthesis in the construction of the bridge. For example, prestressed lower concrete acts only as a load before synthesis, but after synthesis, it is resisted to the load after synthesis as part of the steel box synthesis girder, so synthesis is performed before the step that requires synthesis.

8 to 11 are cross-sectional views of other embodiments in which the prestressed lower concrete 11 is synthesized in the lower flange 4 of the steel box girder 5. 8 shows a spacer 18 between the lower flange 4 and the prestressed lower concrete 11 of the steel box girder, and the shear connecting member 8 fixed to the upper surface of the lower flange 4 is lower than the prestressed. The prestressed lower concrete 11 is installed on the lower flange 4 so as to be located in the through hole 12 formed in the concrete 11, and the lower prestressed concrete 11 is disposed on the lower flange 4 of the steel box girder 5. Steel box composite girder to synthesize

FIG. 9 is a steel box composite girder for synthesizing the prestressed lower concrete 11 on both side portions of the steel box girder lower flange 4, and the non-contraction mortar 20 injected into the through hole 12 does not flow out. The grout dam 21 is installed between the upper surface of the lower flange 4 and the lower surface of the prestressed lower concrete 11 at the end of the lower prestressed concrete 11.

10 is a steel box composite girder in which the lower flange 4 of the steel box girder and the prestressed lower concrete 11 are synthesized at the bottom of the abdomen 2, and a stud type shear connector is used for the abdomen 2 of the steel box girder. In the case of synthesis, the stud type shear connector of the abdomen 2 cannot be installed if the stud type shear connector installed in the abdomen 2 is not installed because of the interference of the stud type shear connector. It is appropriate to pre-weld (22) to the abdomen 2, then install the precast lower concrete segment 10 and bolted studs 23 to the nut 22.

Of course, it is also possible to install the studs using the stud gun after installing the precast lower concrete segment 10 on the lower flange 4 in the field, but it is advantageous in terms of cost and quality to install the studs in the factory. 11 is a steel box composite girder where the lower flange 4 and the lower part of the abdomen 2 of the steel box girder are combined with the prestressed lower concrete 11 at both side portions of the steel box girder lower flange, and the through-hole 12 The grout dam 21 is installed between the upper surface of the lower flange 4 and the lower surface of the prestressed lower concrete 11 at the central end portion of the prestressed lower concrete 11 so that the non-shrink mortar 20 is injected into the insulator. It is configured to.

12 (a) and 12 (b) are steel pipes each having a circular cross section and a slot-shaped cross section, which are inserted into a through hole 12 in which a shear connector 8 is installed. Since the prestress is introduced around the through hole 12 before it is filled with the non-shrink mortar 20, it has a somewhat complicated stress distribution. In particular, concentration of compressive stress occurs in some areas around the through-holes. The use of steel pipes can alleviate this local stress concentration and facilitate the formation of through-holes.

FIG. 13 is a stress diagram showing a difference between concrete stresses when a long hole steel pipe is reinforced and not reinforced in a through hole. FIG. 12 is a result of the structural analysis by modeling only one quarter of the through-hole area in consideration of the repeatability and symmetry of the through-holes. The left side of FIG. 12 is a case where the long steel pipe is not reinforced, and the right side is a case where it is reinforced with a long steel pipe, that is, the distribution of minimum principal stress, ie, the maximum compressive stress. When a pressure of 30 MPa is applied to a plane perpendicular to the Y axis, the maximum compressive stress of 71.1 MPa is applied when the long steel pipe is not reinforced, and the maximum compressive stress of 42 MPa when reinforced with a long steel pipe. This acts on concrete.

Therefore, it can be seen that reinforcing the through-holes with steel pipes can effectively alleviate the concentrated phenomenon of compressive stress. The steel tube also constrains the grout material being filled in the through-holes, thereby enhancing the strength of the grout material by the confinement effect. Of course, when reinforcing the through-holes with the steel pipes 21 and 22, it is preferable to attach various types of reinforcing bars or small studs to the steel cylinders so as to be integral with the concrete.

14 is a side view of a double composite steel box girder bridge using prestressed lower concrete in the constant moment section of a continuous bridge. Prestressed lower concrete (11) is used only in the constant moment section of the continuous bridge, and in the parent section, it uses the site-casting bottom concrete (7), like the existing double-composite steel box girder bridge, and casts the site between the stationary section and the parent section. The concrete (26) is used to continue. The precast lower concrete 9 may be used in the parent section, and the cast-in-place concrete 26 is used between the precast lower concrete 9 of the parent section and the prestressed lower concrete 11 of the constant moment section. Is appropriate.

1: concrete base plate 2: abdomen
3: upper flange 4: lower flange
5: steel box girder 6: longitudinal reinforcement
7: Cast-in-place lower concrete 8: Shear connector
9: Precast lower concrete
10: Precast lower concrete segment
11: Prestressed lower concrete
12 through hole 13 shaped shear key
14: iron shear key 15: fixing device
16: duct 17: steel rod
18: spacer 19: tendon
20: no shrinkage mortar 21: grout dam
22: nut 23: bolted stud
24: round steel pipe 25: long steel pipe
26: cast-in-place concrete 27: nut for level adjustment
28: level adjusting bolt 29: screw type level adjusting device

Claims (3)

In the steel box compounding girder which combined the lower flange 4 and the prestressed lower concrete 11 of the steel box girder 5 installed in the constant moment section of the bridge,
Shear connector (8) is installed on the upper surface of the lower flange (4) of the steel box girder (5) vertically and laterally at predetermined intervals;
A spacer 18 or a thread level adjusting device 29 is installed between the upper surface of the lower flange and the lower surface of the precast lower concrete 9 so that the upper surface of the lower flange 4 and the lower surface of the precast lower concrete 9 can be spaced apart from each other. Becoming;
Both ends are formed so that the cross section is enlarged, the duct 16 is installed in the longitudinal direction of the steel box girder so that the prestressing tendon 19 is installed, and fixing devices at both ends for tension and fixing of the tendon 19. The steel box girder 5 is installed so that the precast lower concrete 9 having the through hole 12 formed in the vertical direction is inserted into the shear connector 8 provided on the upper surface of the lower flange 4. Installed on an upper portion of the lower flange 4;
The tendon 19 is installed in the duct 16 formed in the longitudinal direction of the girder of the precast lower concrete 9, and the tendon 19 is tensioned and fixed by the fixing device 15 installed at both ends thereof, thereby pre-stressing. After the introduction, the grout is injected into the duct 16; The non-shrink mortar 20 is injected into the through-hole 12 to lower flange 4 and prestressed lower concrete of the rigid girder 5 11) is integrated; steel box composite girder manufacturing method using prestressed concrete used in the constant moment section of the bridge, characterized in that consisting of. 2. The precast subconcrete segment (10) of claim 1, wherein the precast subconcrete (9) is segmented into a plurality of precast subconcrete segments (10) in an axial direction, wherein the segmented precast subconcrete segments (10) are epoxy prior to introducing the prestress. Or bonding using non-shrink mortar; steel box composite girders using prestressed concrete used in the constant moment section of the bridge, characterized in that the addition. According to claim 1 or 2, wherein the through-hole 12 formed in the vertical direction of the precast lower concrete (9) is inserted through the steel pipe 24, 25 having a circular or slotted cross section (12) reinforcing the surroundings; manufacturing method of the steel box composite girder using prestressed concrete used in the constant moment section of the bridge, characterized in that the addition.

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