KR101344690B1 - girder rigid frame bridge which used ＰＳＣ Ｔ type rigid frame pier - Google Patents

Abstract

The present invention has a PSC T-type ramen pier to implement a low height girder because the length of the girder mounted on the alternating, pier is shortened by the coping of the pier to play a part of the girder to secure the geometry space of the girder The purpose is to provide the used girder ramen continuous bridge.
Girder ramen continuous bridge using the PSC T-type ramen pier according to the present invention for achieving the above object is a girder ramen continuous consisting of a girder on the alternating, pier, and connecting the girder with alternating, pier and rigid structure In the bridge, the pier is a PSC T-type ramen pier is installed in the direction of the axial axis in the parent section, the PS steel fixing portion is installed at both ends of the upper portion of the PSC T-type ramen pier, PS across the PS steel fixing portion Steel is installed, and the upper end of the PSC T-type ramen pier is connected to the cutting jaw cut in the shape of "L" in the transverse direction, the girder is mounted on the connecting jaw of the PSC T-type ramen pier, the girder and PSC T-type ramen pier is characterized in that the rigid connection.

Description

 Girder rigid frame bridge which used PSC T type rigid frame pier}

The present invention relates to a girder ramen continuous bridge using a PSC T-type ramen piers, in particular, to install a PSC T-type ramen piers instead of the general piers, the coping portion of the PSC T-type ramen piers are responsible for the parent moment, the girder is a positive moment The present invention relates to a girder ramen continuous bridge using a PSC T-type ramen bridge.

In general, girder ramen continuous bridges are traditionally constructed in a structure in which girders are mounted on shifts and piers, and the shifts, piers and girders are rigidly connected to steel or reinforced concrete.

The purpose of applying the girder ramen continuous bridge is to realize low profile height, and since the girder has to cover all the span distances with the traditional pier, the minimum height of the girder cannot be achieved and the longest span ramen can be achieved. There was a problem that could not be made.

Accordingly, the present invention has been made to solve the problems described above, so that the coping of the pier to play a role of the girder in part to secure the space of the girder, the length of the girder mounted on the alternating, pier The purpose of the present invention is to provide a girder ramen continuous bridge using a PSC T-type ramen pier that enables short height girder.

Girder ramen continuous bridge using the PSC T-type ramen pier according to the present invention for achieving the above object is a girder ramen continuous consisting of a girder on the alternating, pier, and connecting the girder with alternating, pier and rigid structure In the bridge, the pier is a PSC T-type ramen pier is installed in the axial direction in the parent cement section, PS steel fixing parts are installed at both ends on the PSC T-type ramen pier, the PS steel across the PS steel fixing part Inserted and tensioned, the upper both ends of the PSC T-type ramen pier is cut in an L-shape at a predetermined interval to form a connecting jaw, the girder is mounted on the connecting jaw of the PSC T-type ramen pier, the girder and the PSC T-shaped ramen pier is characterized in that the rigid connection.

As described above, the girder ramen continuous bridge using the PSC T-type ramen piers according to the present invention is installed by the general pier as a PSC T-type ramen piers, the coping portion of the PSC T-type ramen piers are responsible for the parent, In charge of the construction, it is possible to construct a bridge that lowers the height of the girder as a whole, and has the advantage of selectively applying a ramen bridge according to the terrain.

1 is a side view showing a girder ramen continuous bridge using a PSC T-type ramen pier according to the present invention 1,
2 is a cross-sectional view taken along line “AA” of FIG. 1;
3 is a cross-sectional view taken along the line “AA” of FIG. 1;
4 is a cross-sectional view taken along line “BB” of FIG. 1;
5 is a cross-sectional view taken along line “BB” of FIG. 1;
Figure 6 is a side view showing a girder ramen continuous bridge using a PSC T-type ramen pier according to the present invention,
Figure 7 is a side view showing a connection state between the girder using the PSC T-type ramen pier according to the invention 1,
8 is a side view illustrating a connection state between girders using a PSC T-type ramen pier according to the present invention;
Figure 9 is a side view showing the connection between the girder using the PSC T-type ramen pier according to the invention 3.

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

1 is a side view showing a girder ramen continuous bridge using a PSC T-type ramen pier according to the present invention 1, 2 is a cross-sectional view "AA" line 1 of Figure 1, Figure 3 is a cross-sectional view "AA" line 2 of FIG. 4 is a cross-sectional view taken along line “BB” of FIG. 1, and FIG. 5 is a cross-sectional view taken along line “BB” of FIG. 1, and FIG. 6 is a side view illustrating a girder ramen continuous bridge using a PSC T-type ramen pier according to the present invention. Figure 7 is a side view showing the connection between the girder using the PSC T-type ramen pier according to the invention 1, Figure 8 is a side view showing a connection state between the girder using the PSC T-type ramen pier according to the present invention 2, 9 3 is a side view illustrating a connection state between girders using the PSC T-type ramen pier according to the present invention.

As shown in these figures, the girder ramen continuous bridge using the PSC T-type ramen pier according to the present invention, the girder (G) is mounted on the alternating (A), the pier (P), the alternating girder (G) (A) In the girder ramen continuous bridge formed by connecting the bridge (P) and the rigid structure, the bridge (P) is provided with a PSC T-type ramen bridge (P) in the direction of the bridge in the parent cement section, the PSC The PS steel fixing part 10 is installed at both ends of the upper part of the T-type ramen piercing P, and the PS steel material 12 is installed in the PS steel fixing part 10, and the PSC T-type ramen piering P of the A connecting jaw 14 is formed at both ends of the upper end to be cut in a “L” shape at a predetermined interval, and a girder G is mounted on the connecting jaw 14 of the PSC T-type ramen pier P, and the girder ( G) and PSC T-type Ramen Piers (P) are rigidly connected.

In addition, when the alternating (A) and the girder (G) has a rigid structure, secondary tension and continuous tension PS steel fixing part 18 is installed on the back of the shift (A), and the secondary tension and continuous tension PS Secondary tension and continuous tension are made in the steel fixing part 18,

In the case where the shift A and the girder G have a hinge structure, a secondary tension PS steel reset part 18 is installed at an inner side surface or an outer side abdomen of the girder G, and the secondary tension PS steel reset part is installed. In the unit 18, the secondary tension and continuity of the PS steel 12 is made.

The girder (G) is one side or both sides of the both ends are cut in a "b" shape to form a connecting jaw 22, the sheath 28 is embedded in the upper portion of the PSC T-type ramen piercing (P), the sheath ( 28, the continuous connection PS steel material 30 is installed to be integral with the girder G, or the PS steel fixing portion 10 is formed at one end of the girder G, respectively, the PSC T-type ramen pier (P) The girder G is continuously connected to the PS steel 12 across the upper portion, or the continuous connecting steel plate 32 is embedded in the upper portion of the upper portion of the girder G and the upper portion of the PSC T-shaped ramen piercing P. The continuous connection steel plate 32 is welded to the joint steel plate 34.

The girder G is made of one of a PSC girder, a composite girder and a girder.

Hereinafter, the construction of the girder ramen continuous bridge using the PSC T-type ramen pier according to the present invention having the configuration as described above will be described.

As shown in Figures 1 to 9, the girder ramen continuous bridge construction method using the PSC T-type ramen pier according to the present invention, the girder (G) on the alternating (A), pier (P), the girder In the method of constructing a girder ramen continuous bridge connecting (G) with alternating (A), pier (P) and rigid structures, the pier (P) is a PSC T-type ramen pier in the axial direction within the parent section. P), the PS steel mounting portion 10 is installed at both ends of the upper portion of the PSC T-shaped ramen piercing (P), and the PS steel 12 is placed across the PS steel fixing portion 10. Installed in the shape, prestress is introduced into the PS steel 12, and the upper both ends of the PSC T-type ramen piercing P are cut out to form a "L" shaped connecting jaw 14, and the PSC T The girder (G) is mounted on the connecting jaw (14) of the type ramen pier (P), and the girder (G) and the PSC T-type ramen pier (P) is rigidly connected.

Here, in the case where the alternating (A) and the girder (G) has a rigid structure, the secondary tension and continuous tension PS steel mounting portion 18 is installed on the rear surface of the alternating (A), and the secondary tension and continuous tension PS Secondary tension and continuous tension are made in the steel fixing part 18,

In the case where the shift A and the girder G have a hinge structure, secondary tension and sequential tension PS steel mounting portions 18 are installed on the inner or outer surface of the end of the girder G, and the secondary tension is provided. And the secondary tension and sequential tension of the PS steel 12 in the sequential tension PS steel fixing unit 18.

In addition, the girder G cuts one or both ends of both ends of the girder G in a "-" shape to form a connection jaw 22, and mounts the girder G on the shift A. , The girder (G) and the alternating (A) is connected to the rigid structure 24 or the hinge structure (26).

In addition, the sheath 28 is embedded in the upper portion of the PSC T-type ramen piercing P, and the continuous connection PS steel 30 is installed integrally with the girder G through the sheath 28, or the girder G PS steel fitting portions 18 are formed at one end of each side, and the girder G is continuously connected to the PS steel 12 across the upper portion of the PSC T-type ramen piercing P, and the PSC T-type ramen pier A continuous connecting steel plate 32 is embedded in the upper end of P and the upper end of the girder G, and the continuous connecting steel plate 32 is welded to the joint steel plate 34.

The girder G is made of one of a PSC girder, a composite girder and a girder.

The ramen bridge using the PSC T-type ramen pier according to the present invention made up of the construction and construction as described above comprises a PSC T-type ramen pier (P) in the axial direction within the parent section. When the prestress is introduced by the PS steel material 12 in the axial direction in the inconstant partial coping portion of the mold ramen piercing P, a low coping portion can be formed.

In addition, an L-shaped pier connecting jaw 14 is formed on the upper surface of the coping portion at regular intervals in the transverse direction, which is the perpendicular to the axial axis, and "a" of the girder G on the upper surface of the L-shaped pier connecting jaw 14. When inserting and installing the female connecting jaw 22, the PSC T-type ramen piers (P) play the role of girder (G) in the parent moment section, and the installed girder (G) plays the role in the constant moment section. Therefore, it is possible to build a bridge that can reduce the overall height of the girders (G).

In addition, the sheath 28 is installed on the upper portion of the PSC T-type ramen pier P, and the girder G can be stiffened and simultaneously with the PSC T-type ramen pier P, and alternately (A). ) Is a rigid structure 24, the secondary tension and continuous tension PS steel fixing portion 18 protruding on the back of the shift (A) to form, the PS steel (12) on the back of the shift (A), so the shift It is possible to reduce the size of the parent moment generated in (A), and when the alternating (A) is the hinge structure (26), secondary tension and continuous tension PS steels installed on the inner or outer side abdomen near the end of the girder (G). Secondary tension and sequential tension in the fixing unit 18 increases the efficiency of the girder G.

In addition, the girders (G) installed on the PSC T-type ramen pier (P) is formed on both sides of the "J" shape or only one side of the "J" -shaped connection jaw 22 to form a girder (G) It is possible to adjust the height, and in case of PSC T-type ramen piers (P), all of them are hardened structure (24), but in alternating (A), it is possible to selectively use the hardened structure (24) or hinge structure (26) to construct them in a form suitable for the terrain. Can be.

In addition, the continuous connection of the PSC T-type ramen pier P and the girder G embeds a sheath 28 over the PSC T-type ramen pier P, and continuously connects the PS steels through the sheath 28. (30) is installed on each side of the girder (G) PS steel mounting portion 10, respectively, continuously connected by the PS steel material 12 across the upper portion of the PSC T-type ramen piercing (P), or the PSC T-type ramen PSC T is also a method of embedding a continuous connecting steel plate 32 at the upper end of the piers (P) and the upper end of the girder (G), and attaching the joint steel plate (34) to the continuous connecting steel plate (32) by welding. The type ramen pier (P) and the girder (G) may be integrally connected continuously.

As described above, when the general piers are installed as PSC T type ramen piers (P), the coping part of the PSC T type ramen piers (P) is responsible for the parent moment, and the girders (G) are responsible for the positive moment as a whole. It is possible to build bridges with lower girder heights and to selectively apply ramen continuous bridges according to the terrain.

10: PS steel fixing part 12: PS steel
14: pier connecting jaw 16: vertical connecting steel
17: horizontal connecting steel
18: secondary tension and continuous tension PS steel fitting
20: primary tension PS steel mounting portion 22: girder connecting jaw
24: steel structure 26: hinge structure
28: sheath 30: PS steel
32: continuous connection steel sheet 34: junction steel sheet
A: Shift B: Girder Ramen Continuous Bridge
G: Girder P: PSC Type T Ramen Pier
S: slab

Claims (6)

In the girder ramen continuous bridge formed by connecting the girder (G) on the alternating (A), the pier (P), the girder (G) in a rigid structure with the alternating (A), pier (P),
The pier (P) is a PSC T-type ramen pier (P) is installed in the axial direction in the parent section, the PS steel mounting portion 10 is installed on both ends of the PSC T-type ramen pier (P), the PS The PS steel material 12 is inserted into the steel fixing part 10 and is tensioned, and the upper both ends of the PSC T-type ramen piercing P are cut in an L shape at regular intervals in the transverse direction to form a connection jaw 14. Girder (G) is mounted on the connecting jaw 14 of the PSC T-type ramen piercing (P), the girder (G) and the PSC T-type ramen piercing (P) is rigidly connected, the shift (A) In the case of the steel grain structure 24, the secondary tension and the continuous tension PS steel fixing part 18 are installed on the back of the shift A, and the secondary tension and the continuous tension are made, and the shift A is hinged. In the case of the structure 26, secondary tension and continuous tension PS steel fixing parts 18 are installed on the inner side or the outer side of the abdomen near the end of the girder G, and the secondary tension and continuity tension are achieved. One side or both sides of the girder (G) is cut in a "b" shape to form a connecting jaw 22, the sheath 28 is installed on the upper end of the PSC T-type ramen piercing (P), the PSC A girder (G) is mounted on the T-type ramen pier (P), and the continuous connection between the PSC T-type ramen pier (P) and the girder (G) is continuous by the PS steel material 12 inserted into the sheath 28. PS steel material fixing portion 10 is formed at each end of the girder G mounted on the PSC T-type ramen pier P, respectively, and the PS steel 12 crosses the upper portion of the PSC T-type ramen pier P. Continuously connected to each other, continuous connection steel plate 32 is embedded in each of the upper end portion of the PSC T-type ramen piercing (P) and one side upper end of the girder (G), the joint steel plate 34 between the continuous connection steel plate 32 Girder ramen continuous bridge using PSC T-type ramen pier, characterized by continuous connection by welding. delete delete delete delete delete

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