KR20130077191A - Prestressed concrete girder with half-depth cantilever and construction method using the same - Google Patents

Abstract

PURPOSE: A Prestressed concrete girder including a half section cantilever unit and a bridge construction method using the same are provided to improve the efficiency of a bridge construction by reducing construction periods for molding on a bottom plate. CONSTITUTION: A Prestressed concrete girder (100) including a half section cantilever unit comprises a concrete girder (110) and a cantilever unit (140). The concrete girder comprises a connection reinforcing bar (125) on the upper part as a connection member, and a reinforcing bar is arranged inside the concrete girder. Tendons to which prestress is applied are installed in a sheath pipe (77). The cantilever unit protrudes to one side of a transverse direction at the upper part of the concrete girder so that a part of the connection reinforcing bar is embedded.

Description

Prestressed concrete girder with half-section cantilevered part and bridge construction method {PRESTRESSED CONCRETE GIRDER WITH HALF-DEPTH CANTILEVER AND CONSTRUCTION METHOD USING THE SAME}

The present invention relates to a prestressed concrete girder having a half-section cantilever portion and a method of constructing a bridge using the same, wherein the half-section cantilever portion is formed so as to be part of the bottom plate thickness when the prestressed concrete girder is positioned on the outermost side of the bridge. The present invention relates to a prestressed concrete girder equipped with a half-section cantilever portion that enables the construction of concrete decks to be simpler, minimizes the risk of safety accidents, and improves construction efficiency, and a bridge construction method using the same.

In general, the bridge shown in FIG. 1 constructed using concrete girder has a plurality of concrete girders 10 and 10 'mounted on the lower structure of the bridge, and the bottom plate is placed on the upper side of the concrete girder 10 and 10'. After installing the molds for casting (not shown), the concrete that is not hardened in the mold for placing slabs is cured to synthesize the slab concrete 20 on the upper side of the concrete girder (10, 10 '), and the slab concrete (20 ) And is installed by installing a protective wall (21).

In order to construct the concrete deck 20 in the construction of the bridge formwork for pouring the concrete deck 20 must be installed. The decking formwork can be easily installed in the area between the concrete girders 10 and 10 'in a form supported by the concrete girders 10 and 10', but the outermost outside area of the concrete girders 10 and 10 ' In the cantilever part, it is very complicated to install so as to be supported by the outermost concrete girder 10 '.

As an example, the process of installing the bottom plate formwork 30 in the outermost region, 'b' having a certain height to accommodate the concrete that is not hardened while extending laterally outward from the outermost concrete girder 10 '. The receiving bracket 32 of the cross section is positioned outside the outermost concrete girder 10 'and the inner side of the receiving bracket 32 is supported by a vertical support 31 fixed to the outermost concrete girder 10'. In addition, the complicated process of the so-called bracket foot method of installing the inclined support 33 for supporting the outer side of the concrete girder 10 'and the receiving bracket 32 while adjusting the length with the turnbuckle 33a was necessarily accompanied. Then, after arranging the sagging prevention support 34 on the upper surface of the receiving bracket 32 by a square wood or the like, the pouring formwork 35 is installed thereon.

Thus, the process of installing the bottom plate placing formwork 30 on the cantilever portion of the bridge deck, that is, the outermost girder, is not only very demanding, but also the concrete girders 10 and 10 'are mounted on the lower structure such as piers. Since it is made in the state, there was a problem that the risk of safety accidents increases.

Therefore, there is an urgent need for a method for reducing the risk of a safety accident while making the installation of the bottom plate placing form 30 outside the outermost girder 10 'in construction of a bridge.

In order to solve the problems described above, the present invention, when manufacturing the prestressed concrete girder located on the outermost side of the bridge, by forming the cantilever portion to form a part of the bottom plate concrete in advance in the upper flange, It is an object of the present invention to provide a prestressed concrete girder and a bridge construction method using the same, so that the construction can be made very easily in a short time to improve the efficiency of the process to shorten the construction period.

In addition, the present invention is installed in the prestressed concrete girder in advance to form a part of the bottom plate concrete as described above, since the construction of the formwork for the construction of the bottom plate protruding outward in the transverse direction of the bridge is made more secure, Another aim is to minimize the possibility of safety accidents.

The present invention comprises the steps of installing the lower surface formwork for concrete placement to be supported on the ground in order to achieve the object as described above; Arranging reinforcing bars and sheath pipes on the connecting member exposed upwardly of the girder and the lower surface formwork; Installing a side formwork to receive the rebar; Placing concrete which is not hardened in the formwork to produce a girder; Installing a tension member in the sheath tube and tensioning the tension tube to introduce compression prestress into the girder; After the compression prestressing step, synthesizing a cantilever portion having a half cross section to protrude in one direction from an upper end portion of the girder; It is configured to include, wherein the steps are all provided before the mounting on the substructure of the bridge provides a method of manufacturing a prestressed concrete girder.

The outermost side of the bridge is constructed so that the cantilever portion protrudes to one side to form a part of the bottom plate in the concrete girder prior to mounting the girder on the pier or alternating foot in manufacturing the concrete girder positioned on the outermost side of the bridge. Since the difficult process of installing the formwork for placing the concrete deck in the transverse direction of the girder is eliminated, it is easier to lay the deck and shorten the construction period. have.

In addition, by dramatically minimizing the safety accidents that may occur during the construction of the deck slab formwork at the position protruding to the outside of the outermost girder, it is possible to ensure the safety of the operator more securely in the construction process of the bridge. The effect can be obtained.

In addition, in manufacturing the prestressed concrete girder having the cantilevered portion as described above, by compressing the tension material in the concrete girder before the cantilevered portion is synthesized to introduce the compression prestress, the cantilevered portion is compressed to the synthesized cross section. Compression prestress can be introduced into the girder with less tension than in the case of introducing prestress, and even if the same amount of tension is applied to other prestressed concrete girders without a cantilever, it can be collectively adjusted with the same amount of rise.

On the other hand, according to another field of the invention, the present invention is provided with a connecting member exposed on the upper side, and a girder incorporating a tension member for introducing prestress; After introducing the prestress by the tension member, a half-section cantilever portion is synthesized on the upper side of the girder so that at least part of the connecting member is embedded, and has a shape projecting to one side with respect to the girder; It provides a girder, characterized in that configured to include, in this case, the reinforcing bar is usually used as a connecting material.

Through this, the installation process of the formwork for placing the concrete deck is easier and faster to ensure the safety of the operator, and enables the close synthesis of the concrete deck and the cantilever portion to be poured.

On the other hand, according to another field of the invention, the present invention comprises the steps of preparing a second girder having a first girder having no cantilever portion and a half-section cantilever portion manufactured according to claim 1 or 2; Mounting the first girder and the second girder to expose the half-section cantilever portion to the outermost portion of a bridge; Mounting a half-section bottom plate between the first girder and between the first girder and the second girder; Synthesizing the concrete deck with the first girder and the second girder by placing concrete on the half section bottom plate and the half section cantilever; Provides a method of construction of bridges, including.

At this time, the first girder and the second girder may be prestressed concrete girder (I-shaped or U-shaped, etc.), I-shaped steel girder, casing concrete is synthesized in a part of the I-shaped steel girder. It may also be a composite girder.

The term "longitudinal direction" used in the present specification and claims is generally defined in the axial direction as a longitudinal direction through the bridge, and the term "lateral direction" used in the present specification and claims is used in the "longitudinal direction". It is defined as a direction perpendicular to the axis as a direction perpendicular to '.

In addition, the 'cantilever portion protruding to one side of the concrete girder' described in the present specification and claims may protrude to one side over the entire longitudinal length of the concrete girder, or to one side only for a part of the longitudinal length of the concrete girder. Includes all protruding configurations. That is, the formwork for placing the bottom plate concrete on the outside of the outermost girder in the transverse direction can be made only by the cantilever portion protruding to one side over the entire length of the girder, but the longitudinal The cantilever portion protruding to one side at intervals in the direction may be utilized as a part of the bottom plate placing form (for example, a support for supporting the formwork), which is installed outside the transverse direction of the outermost girder.

In addition, the description of 'preparing girder formwork to produce concrete girders on the ground' described in the present specification and claims means that the formwork's installation position is "before mounting on the undercarriage of the bridge", the formwork directly on the ground It is not limited to being installed but is defined as including the installation of formwork on a facility installed on the ground.

The term 'connector' used in the present specification and claims refers to a member in which at least a portion is embedded in the cantilever portion which is extended from the girder and may be formed in various forms such as reinforcing bars and studs.

The term 'half section' used in the present specification and claims is defined as 'partial cross section of the entire cross section' and is not limited to exactly 'half thickness of the entire cross section'.

As described above, in the present invention, in manufacturing a prestressed concrete girder installed on a bridge, the cantilever portion having a part thickness of the bottom plate is provided on the girder located on the outermost side of the bridge before mounting on a substructure such as a bridge. By pre-synthesizing the girder so as to protrude to one side of the girder, it is not necessary to install the formwork for placing the concrete deck at the position protruding outward in the transverse direction of the outermost girder on the substructure such as the piers, so The present invention provides a prestressed concrete girder capable of improving the construction efficiency of bridges by shortening the bottom plate construction period, and a manufacturing method thereof.

The present invention by minimizing the safety accident that can occur when installing the formwork for placing the bottom plate in the position protruding to the outside of the outermost girder in the process of constructing the bridge using the prestressed concrete girder manufactured as described above, An advantageous effect can be obtained to more securely guarantee the safety of the worker.

In addition, the present invention, as the cantilever portion is tensioned to the tension material prior to the synthesis of the concrete girder to introduce the prestress, even if there is a difference in cross-section with the prestressed concrete girder located at the center portion in the transverse direction of the bridge without the cantilever portion Since the amount of rise of these girders can be adjusted within an allowable range, all the amount of rise of the girders mounted on the lower structure can be adjusted within a certain range, thereby making it possible to firmly synthesize the girder and the bottom plate.

1 is a cross-sectional view showing a conventional concrete girder bridge,
Figure 2 is a formwork installation diagram for installing the bottom plate of the 'A' part of Figure 1,
3a to 3e is a view showing the configuration according to the manufacturing sequence of the prestressed concrete girder provided with the cantilever portion according to an embodiment of the present invention,
Figures 4a to 4c is a view showing a construction method of the bridge according to an embodiment of the present invention using the prestressed concrete girder shown in Figure 3e,
Fig. 5 is a diagram showing the configuration of the half-section bottom plate.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings. In the following description, well-known functions or constructions are not described in detail to avoid obscuring the subject matter of the present invention.

As shown in Figure 3e, the prestressed concrete girder (hereinafter referred to as 'PSC girder', 100) according to an embodiment of the present invention, the reinforcement is reinforced inside and the connecting reinforcement 125 as a connecting material on the upper side The cantilever portion protruding to one side in the transverse direction on the upper side of the concrete girder 110 so that a portion of the concrete girder 110 and the reinforcing reinforcement 125 are embedded in the sheath pipe 77 and the tension member for introducing prestress is embedded. 140.

That is, the PSC girder 100 is located at the outermost side in the lateral direction when the bridge is constructed, the cantilever portion 140 protruding to one side forms a part of the bottom plate concrete (300 in Fig. 4c) and at the same time It serves as a formwork for pouring the plate concrete 300, to facilitate the synthesis process of the bottom plate concrete 300 at the time of construction of the bridge.

Here, the concrete girder 110 is manufactured by the manufacturing method of a general PSC girder, the cross-sectional shape is as shown in Figure 3e, but may be made in various forms in addition to.

The cantilever part 140 is formed of reinforced concrete having a thickness (H1) thinner than the thickness (H) of the bottom plate concrete synthesized on the upper surface of the PSC girder 100, the end portion protruding to one side of the bottom plate concrete An extension part 140a extending upward by the thickness H is provided. Through this, the concrete which is not hardened on the upper side of the can kill lever unit 140 is poured, and the bottom plate concrete 300 is formed together with the cantilever unit 140.

The cantilever part 140 has a reinforcing bar 131 for reinforcing the internal strength as shown in FIG. 3D, and a loop joint reinforcing bar 133 coupled with the bar that is reinforced on the bottom plate concrete 300. , Is embedded in the bottom plate concrete 300 so that the horizontal shear reinforcing bars 132 for shear reinforcement are exposed. A guardrail or a barrier wall is installed above the extension part 140a, so that a barrier wall reinforcing bar 134 coupled thereto is installed.

The tension member is installed in the sheath tube 77 arranged in a parabolic form along the longitudinal direction of the girder, and the compression prestress is introduced in the longitudinal direction of the concrete girder 110 by being tensioned.

PSC girder 100 according to an embodiment of the present invention having a cantilever portion 140 as described above is provided with a cantilever portion 140 protruding to one side in the transverse direction by the composite length of the bottom plate concrete on the girder upper side Since the installation of the formwork for the synthesis of the bottom plate 300 is excluded, the process is simplified to significantly shorten the time required for the conventional bridge construction. Above all, as shown in FIG. 2, the installation of the form of the crow's feet in the state of mounting the girder to the lower structure such as the pier, there is an advantageous effect that solves the problem that the safety accidents of workers exist at once. .

Hereinafter, a manufacturing method of the PSC girder 100 having the cantilever unit according to the embodiment of the present invention configured as described above will be described in detail.

Step 1 : As shown in FIG. 3A, a reinforcing bar 120 including a transverse reinforcing bar 121 and a longitudinal reinforcing bar 122 is disposed on a lower surface formwork (not shown) installed to be supported on the ground. In this case, the formwork includes all forms of plywood, steel plate, ground, and the like, which are installed to support the bottom surface of the PSC girder 100.

At this time, the exposed reinforcing bars 125 exposed on the upper side of the concrete girder 110 so as to be partially embedded by the cantilever unit 140 synthesized in a subsequent process are reinforced together as a connecting material. Then, the sheath pipe 77 is installed to support the reinforcing bars 120 in which the tension member for introducing the compression prestress to the concrete girder 110 is installed.

Step 2 : As shown in FIG. 3B, the side formwork 60 for forming the cross section of the concrete girder 110 having a predetermined shape is installed to include the reinforcing bar 120. At this time, the shape of the concrete girder 110 may be made of an I-shaped girder consisting of an upper flange, a lower flange, and an abdomen as shown in the figure, but may have a shape in which the cross section changes according to the installation conditions and the length of the girder.

Step 3 : Then, as shown in Fig. 3c, the concrete which is not hardened in the side formwork 60 is poured and cured to manufacture the concrete girder 110. At this time, the upper side of the concrete girder 110 so that the exposed reinforcement 125 is in an exposed state. Next, the side formwork 60 surrounding both sides of the concrete girder 110 is removed.

Step 4 : Then, a tension material, such as a strand, is inserted into the sheath pipe 77 arranged in a convex parabolic shape downwardly along the longitudinal direction of the concrete girder 110 to settle tension to introduce compression prestress to the concrete girder 110. do.

As described above, when the tension material is tensioned in the concrete girder 110 and the compression prestress is introduced before the cantilever portion 140 is synthesized, the cantilever portion 140 introduces the compression prestress to the synthesized synthetic cross section. In comparison, compression prestress can be introduced into the girders with less tension. In addition, the rise of the girder is generated when the compression prestress is introduced by the parabolic tension member disposed in the concrete girder 110, even if the same amount of tension as the other prestressed concrete girder without a cantilever Since the girder does not have a cantilever, the girder quality is equally managed.

Step 5 : Then, install the formwork assembly 80 for synthesizing the cantilever portion 140 as shown in FIG. 3D. Since the cantilever part 140 is constructed in a form protruding to one side in the lateral direction of the concrete girder 110, the cantilever part formwork 81 is first installed in accordance with the outline projecting from the upper side of the concrete girder 110, and the cantilever part After providing the support plate 82 of sufficient thickness in the bottom surface so that the bottom surface of the form | work 81 may be prevented from deformation, the copper plate 83 which connects and supports this support plate 82 and the ground 9 is provided.

As such, as the formwork 81 for the synthesis of the cantilever portion 140 forming a part of the bottom plate concrete 300 is installed to be supported by the club 83 on the ground, the girder 10 in the conventional lower structure , 10 ') is much simpler and safer than the process of constructing the floorboard casting formwork in the form of crow's feet.

At this time, the cantilever part formwork 81 is preferably formed to protrude to one side in the transverse direction over the entire longitudinal length of the concrete girder 110. However, according to another embodiment of the present invention, one side in the transverse direction at intervals with respect to the longitudinal length of the concrete girder 110 so that it can serve only as a support for installing the bottom plate formwork outward in the transverse direction of the outermost girder. The cantilever part 140 may be synthesized in a form protruding to be.

Step 6 : Then, the reinforcement 130 is placed in the cantilever part formwork 81 as shown in FIG. 3D. More specifically, the reinforcing bar 131 for reinforcing the internal strength of the cantilever unit 140, the loop joint reinforcing bar 133 that is bound to the reinforcing bar of the bottom plate concrete 300 by precast or in-situ casting, and the floor Horizontal shear reinforcing bars 132, which are embedded in the plate concrete 300 and perform shear reinforcement, and barrier wall reinforcing bars 134, which reinforce the railing or the protection wall, are reinforced.

Step 7 : Then, as shown in FIG. 3E, the cantilever portion 140 is poured into the cantilever portion formwork 81 to synthesize the cantilever portion 140 in the concrete girder 110. Then, the cantilever part die 81 is removed. The cantilever part 140 serves as a mold for placing the bottom plate while forming a part of the bottom plate 300 of the bridge, and thus is manufactured to have a thickness H1 smaller than the thickness H of the bottom plate 300.

Steps 5 to 7 in the embodiment of the present invention described above was installed by installing a copper bar (83) supported on the ground (9) on the lower surface of the formwork 81 when the cantilever portion, but unlike the formwork ( Instead of being supported by the club 83 from the ground, it is also possible to construct such that it is supported by a club (not shown) extending from the concrete girder 110 or by using another structure.

The PSC girder 100 provided with the cantilever portion 140 according to the embodiment of the present invention manufactured as described above is installed at the outermost side in the lateral direction at the time of construction of the bridge, and the cantilever portion 140 of the bridge Forming part of the bottom plate concrete 300 serves as the formwork of the concrete to the bottom plate concrete 300 in the field.

Hereinafter, a method of constructing a bridge according to an embodiment of the present invention constructed as described above will be described in detail with reference to FIGS. 4A to 4C.

Step 1 : As shown in Fig. 4a, the PSC girders 100 and 10 fabricated on the ground are mounted on the lower structure of the bridge. The PSC girder 100 in which the cantilever part 140 shown in FIGS. 3A to 3E is synthesized is positioned at the outermost side in the lateral direction, and the PSC girder 10 without the cantilever part 140 is mounted therebetween.

Step 2 : Next, as shown in FIG. 4B, the half-section bottom plate 200 is mounted on the girder 10 and 100 laterally adjacent to the side space of the PSC girder 100 and 10. At this time, the half-section bottom plate 200 is commonly used as its general shape, as shown in Figure 5, the reinforcing bars 201 and 201 are vertically and horizontally exposed and the exposed rebar 201a is exposed to the outside, It is firmly coupled with the floor plate 300 that is cast in the field. Accordingly, it is possible to synthesize the concrete floor plate 300 on the upper side of the PSC girder (100, 10) without installing a separate formwork.

Step 3 : Then, as shown in Figure 4c, by curing the hardened concrete on the half-section bottom plate 200 and the cantilever portion 140 to the bottom plate concrete 300 to the upper side of the PSC girder (10, 100) To synthesize.

Then, paving the pavement surface in the bottom plate concrete 300 and install the railings 310 on both sides to complete the construction of the bridge (1000).

In the above, the preferred embodiments of the present invention have been described by way of example, but the scope of the present invention is not limited to these specific embodiments, and may be appropriately changed within the scope described in the claims.

In other words, the preferred embodiment of the present invention has been described as an example in which the cantilever unit 140 is synthesized in the prestressed concrete girder, but the material of the girder is made of steel only or a steel composite girder combined with steel and concrete. In addition, the connector is installed to partially expose the upper side of the girder, and at least a portion of the connector is synthesized so as to be embedded in the half-section cantilever part to manufacture a girder having a half-section cantilever part through the above embodiment. In addition, all the various modified embodiment within the range of a claim is all included in the scope of the present invention.

10: PSC girder
100: PSC girder with cantilever part
110: concrete girder
140: cantilever part

Claims (3)

As a production method of prestressed concrete girder,
Installing a lower surface formwork for concrete placing to be supported on the ground;
Arranging reinforcing bars and sheath pipes on the connecting member exposed upwardly of the girder and the lower surface formwork;
Installing a side formwork to receive the rebar;
Placing concrete which is not hardened in the formwork to produce a girder;
Installing a tension member in the sheath tube and tensioning the tension tube to introduce compression prestress into the girder;
After the compression prestressing step, synthesizing a cantilever portion having a half cross section to protrude in one direction from an upper end portion of the girder;
It is configured to include, wherein the steps are all made before the mounting of the bridge substructure structure of the prestressed concrete girder.
A girder having an exposed connection member on the upper side, and a tension member for introducing prestress;
After introducing the prestress by the tension member, a half-section cantilever portion is synthesized on the upper side of the girder so that at least part of the connecting member is embedded, and has a shape projecting to one side with respect to the girder;
Girder, characterized in that configured to include.
As a construction method of the bridge,
Preparing a second girder having a first girder having no cantilever portion and a half sectional cantilever portion manufactured according to claim 1 or 2;
Mounting the first girder and the second girder to expose the half-section cantilever portion to the outermost portion of a bridge;
Mounting a half-section bottom plate between the first girder and between the first girder and the second girder;
Synthesizing the concrete deck with the first girder and the second girder by placing concrete on the half section bottom plate and the half section cantilever;
Method of construction of bridges, including.

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