KR101318773B1 - T-shaped composite girder segment integrated by i-shaped girder filled with concrete and slab and construction method of slab by prefabrication of the t-shaped composite girder segment - Google Patents

Abstract

PURPOSE: A T-shaped composition unit girder with an I-shaped concrete filled girder and a bottom plate integrally coupled and a precast bottom plate construction method using the same are provided to deliver a product, which is manufactured in a factory by a pre-casting method, to the site and then assemble the product, thereby emergency-recovering or temporary installing the bridge that is damaged and washed away by the natural disaster. CONSTITUTION: A T-shaped composition unit girder with an I-shaped concrete filled girder and a bottom plate integrally coupled includes an I-shaped steel girder portion (10), a shear connector (40), a cover plate (50), a central plate (20), and a bottom slab portion (30). A pair of I-shaped steels includes the one end portions of lower flanges forming an abutment joint welding portion (50), and has a space (8) which has the close lower portion and the open upper porting so that the one portion of the space becomes a concrete filling portion. The concrete is poured in the concrete filled portion of the I-shaped steel girder portion and the bottom slab portion to be integrated.

Description

T-shaped composite girder segment integrated by I-shaped girder filled with concrete and slab and construction method of slab by prefabrication of the T-shaped composite girder segment}

The present invention relates to a T-shaped composite unit girder for bridges formed by integrally combining an I-type concrete filling girder and a precast deck and a method of constructing a prefabricated deck composite girder bridge using the same.

Various studies have been made on bridges constructed by precast method of prestressed concrete (PSC) bridges which are lightweight, high rigidity, short construction period and low construction cost.

Applicant, as an example to satisfy this demand, through the composite girder of the I-shaped steel and concrete in which a pair of H-shaped steel in the Korean Patent No. 10-1182680 and filled concrete therebetween, lightweight and rigid I suggested concrete type I girder filling girder and girder bridge using the same to increase low profile and long span.

The I-shaped concrete filling girder according to the Korean Patent No. 10-1182680 is formed of a pair of H-shaped steel and one or all of the space portion filled with concrete filled with one side flange side ends are combined to form a closed space portion It is configured to include a concrete filling, the manufacturing step of preparing a pair of H-beams, the flange side ends of the pair of H-beams are placed in contact with each other and welded to join the side ends to contact each other, flange side It includes a filling step of placing concrete in a part or all of the closed space formed by the end is joined to each other, and through this step, the factory-produced girders are brought into the site to install the bridge and mounted on the shift or piers It is then inserted inside the girder to prevent structural deflection and to increase structural rigidity against bending. Before and after the amount of concrete for PC strand in the longitudinal direction by 1, is a technique that a base to relax into secondary.

Girder bridge is the most common and common type of bridge type, and it is a bridge with a structure that allows the girder to put the load (vehicle or person) on the upper slab that is the bottom plate of the bridge. When the upper slab is made of concrete slab, it is common to adopt a composite structure using a shear connector to integrate the girder and the upper slab, and at this time, the upper slab, which is the bottom plate, is usually cast in place and integrated with the girder. to be.

However, in the case of the above-described type of concrete filling girder and the girder bridge using the same according to the applicant's domestic patent No. 10-1182680 of the present applicant, only the type I concrete filling girder is produced at the factory, and the bottom plate slab of the bridge coupled to the upper portion thereof. Since it is placed in the field and combined with the girder as in the case of the ordinary girder bridge, it is necessary to shorten the construction period of the bridge, such as when the bridge is destroyed or lost due to natural disaster such as heavy rain or landslide. In case of urgent restoration or construction, there is a limit to shortening the construction period.

The present invention, while maintaining the technical advantages of the I-shaped concrete filling girder according to the applicant's domestic patent No. 10-1182680 described above, and furthermore, especially when the bridge is destroyed or lost due to natural disasters such as heavy rain or landslides Precast composite girder bridge for prefabricated deck slabs for urgent repair or construction of bridges. Combined with I-shaped concrete girder, the slab slabs on the upper part of the bridge with a predetermined unit width are integrated in the factory in advance. In the field, it is possible to quickly build bridges by simply combining these composite unit girders vertically and horizontally without additional floor plate construction.

Synthetic unit girder according to the present invention, the concrete filled in the abdomen (web part) of the I-type concrete filling girder by the factory production and the concrete filled as a bottom slab slab integrally cast together the I-type concrete girder and the bottom plate It is the point of the technical thought that the slab is integrated.

Domestic Patent No. 10-1182680

This invention has the following objectives.

1. The bottom plate slab of a predetermined unit width placed on the upper part of the I-type composite girder according to Korean Patent No. 10-1182680 is manufactured in a factory so as to be integrated with the I-type composite girder and made into a unit structure having a size that can be transported to the site. This provides an economical precast method that can minimize the site construction time and construction time of the deck plate, which is the bridge overhead work.

2. Since the product is manufactured by factory production, the construction period of the girder can be shortened significantly.

3. T-type synthetic unit girder is made by precast method integrated in the factory to provide homogeneous excellent quality.

4. To provide synthetic unit girder to economically and urgently recover bridges lost or damaged due to feng shui disasters / water damage.

The T-type composite unit girder integrally combining the I-type concrete filling girder and the bottom plate slab according to the present invention,

A pair of I-beams having an upper flange, a lower flange having a width wider than the width of the upper flange, and a web connecting the upper and lower flanges vertically forms a pair of welded joints at one end side of the lower flange in a direction parallel to each other. An I-shaped girder portion formed by a flange and a portion surrounded by both webs, the lower portion of which is blocked and the upper portion of which is opened, the space being a concrete filling portion; And

A concrete slab slab placed on top of the I-shaped girder section, the width of which is larger than the length of the entire flange of the I-shaped girder section, the longitudinal reinforcing bar is extended to the outside, the sheath pipe for PC strand wire insertion a bottom plate slab portion having a sheath pipe embedded therein and concrete being poured together with the concrete filling portion of the I-type girder to be integrated with the I-type girder to form a cross-section T-shaped composite unit girder;

Characterized in that comprises a (first embodiment).

In addition, the T-type composite unit girder integrally combining the I-type concrete filling girder and the bottom plate slab according to the present invention, in the configuration of the first embodiment as described above, the space part of the I-shaped girder is divided into an upper space and a lower space It is further provided with a central plate is installed horizontally, the concrete filling unit is filled with concrete integrally with the bottom plate slab portion is characterized in that the upper space portion over the entire length of the I-shaped girder portion.

In addition, in the T-type composite unit girder of the first embodiment configuration in which the I-type concrete filling girder and the bottom plate slab integrally combined according to the present invention, the concrete filling unit is integrally filled with the bottom plate slab, I In addition to the upper space portion throughout the longitudinal direction of the type steel girder portion, characterized in that it further comprises a lower space portion of the longitudinal direction of the I-type concrete filling girder.

In addition, in the T-type composite unit girder of the first embodiment in which the type I concrete filling girder and the bottom plate are integrally coupled according to the present invention, the lower space portion of the I-shaped concrete filling girder is part of the lengthwise direction of the concrete. When is filled is the lower space is filled with the concrete is characterized in that the section in which the bending tensile stress acts on both ends of the girder in the longitudinal direction and the girder.

In addition, the T-type composite unit girder of the first embodiment configuration in which the I-shaped concrete filling girder and the bottom plate slab integrally combined according to the present invention, one end is welded to the upper surface of the upper flange of the pair of I-shaped steel and the other end is It characterized in that it further comprises a plurality of shear connection material embedded in the slab concrete slab.

In addition, the T-type composite unit girder of the first embodiment configuration in which the type I concrete filling girder and the bottom plate slab are integrally combined according to the present invention, one end is welded to the upper surface of the center plate and the other end is the upper hole of the I type girder. It characterized in that it further comprises a plurality of shear connection material embedded in the concrete filled in the liver.

In addition, the T-type composite unit girder integrally combining the I-type concrete filling girder and the bottom plate according to the present invention is characterized in that the cover plate is further provided to be coupled to the lower flange bottom of the pair of I-shaped steel.

In addition, the T-type composite unit girder integrally combining the type I concrete filling girder and the bottom plate slab according to the present invention,

A pair of I-beams having an upper flange, a lower flange having a width equal to the width of the upper flange, and a web connecting the upper and lower flanges vertically is joined to each other in a direction parallel to each one end of the upper and lower flanges. This makes an enclosed space surrounded by the upper and lower flanges and both webs, I-shaped girder portion that the sealed space is a concrete filling portion; And

A concrete slab slab placed on top of the I-shaped girder section, the width of the length is longer than the flange length of the I-shaped girder, the longitudinal reinforcing bars are extended to the outside, the sheath pipe for inserting PC strands ( Sheath pipe is embedded, and the bottom plate slab portion is formed with the concrete filling portion of the I-type girder portion is integrated with the I-type girder portion to form a T-shaped composite unit girder cross-section;

Each of the upper flanges of the pair of I-shaped steels is characterized in that work holes are formed at equal intervals or inequality intervals in communication with the filling portion along the longitudinal direction of the I-shaped steels (second embodiment).

In addition, in the second embodiment of the T-type composite unit girder integrally combining the type I concrete filling girder and the bottom plate slab according to the present invention, the space part of the type I girder is divided into an upper space part and a lower space part horizontally. A central plate is further provided, and the concrete filling unit in which concrete is integrally filled with the bottom plate slab is characterized in that the upper space portion over the entire length of the I-shaped girder portion.

In addition, in the second embodiment of the configuration of the T-type composite unit girder integrally combining the I-shaped concrete filling girder and the bottom plate according to the present invention, the concrete filling unit which is integrally filled with the bottom plate slab, I type It is characterized in that the lower space portion over the part of the longitudinal direction of the I-type concrete filling girder in addition to the upper space portion throughout the longitudinal direction of the girder.

In addition, in the T-type composite unit girder of the second embodiment in which the type I concrete filling girder and the bottom plate are integrally coupled according to the present invention, the lower space portion of the I-shaped concrete filling girder is part of the lengthwise direction of the concrete. When is filled is the lower space is filled with the concrete is characterized in that the section in which the bending tensile stress acts on both ends of the girder in the longitudinal direction and the girder.

In addition, the T-type composite unit girder of the second embodiment in which the I-shaped concrete filling girder and the bottom plate are integrally combined according to the present invention, one end is welded to the upper flange upper surface of the pair of I-shaped steel and the other end is the bottom. It is characterized in that it further comprises a plurality of shear connector embedded in the slab concrete.

In addition, the T-type composite unit girder of the second embodiment in which the type I concrete filling girder and the bottom plate are integrally coupled according to the present invention, one end is welded to the upper surface of the center plate and the other end is an upper space part of the I type girder. It characterized in that it further comprises a plurality of shear connection material embedded in the concrete filled in.

In addition, in the second embodiment of the T-type composite unit girder integrally combining the I-shaped concrete filling girder and the bottom plate according to the present invention, a cover plate coupled to the lower flange lower surface of the pair of I-shaped steel is further provided. It is done.

In addition, the construction method of the prefabricated girder bridge using the T-type composite unit girder that integrally combined the I-type concrete filling girder and the bottom plate according to the present invention,

A pair of I-beams having an upper flange, a lower flange having a width wider than the width of the upper flange, and a web connecting the upper and lower flanges vertically form a butt joint in one end side of the lower flange in a direction parallel to each other. A first step of providing an I-type girder by a space surrounded by upper and lower flanges and both webs, the lower part of which is blocked and the upper part of the upper part being opened to form a concrete filling part;

A bottom plate slab placed on the upper part of the I-type girder, the width of which is larger than the flange length of the I-type girder, the longitudinal reinforcing bar extending inside is exposed to the outside, sheath pipe for inserting PC strand wire (sheath) The pipe is buried, and concrete is poured together with the concrete filling part of the I-type girder to be integrated with the I-type girder, and the bottom plate slab forming the composite unit girder having a cross-section T-type is hardened. Step 2;

Bring the required number of cross-section T-shaped composite unit girders to the site and arrange them vertically and horizontally to have a predetermined interval, and then connect the transverse rebars exposed to the outside between adjacent unit girders with reinforcing bars and connect the PCs in the longitudinal direction. A third step of connecting a sheath pipe for inserting a strand wire;

A fourth step of embedding concrete between the adjacent unit T-shaped composite unit girder to bury the reinforcing bar and the sheath pipe; And

The fifth step of inserting and tensioning PC strands in a sheath pipe for inserting PC strands in the longitudinal and horizontal direction of adjacent section T-shaped composite unit girders

And a control unit.

In addition, the construction method of the prefabricated girder bridge using the T-type composite unit girder integrally combining the I-type concrete filling girder and the bottom plate according to the present invention,

Immediately after the third step, the step of inserting the PC strand along the longitudinal direction of the I-shaped girder portion in the concrete filling portion of the I-shaped girder portion, characterized in that it further comprises a tensile fixing.

The T-type composite unit girder integrally combining the I-type concrete filling girder and the bottom slab according to the present invention is made of a unit structure that can be transported to the site in advance in the factory, and the construction cost is low, but the quality is uniform and excellent. The construction of the bridge is completed by carrying out the uniformly produced T-type composite unit girder to the site, mounting it on the alternating or pier, and then integrating it in the longitudinal and transverse directions, which greatly shortens the construction period of the bridge. have. Due to this effect, the prefabricated girder bridge using the T-type composite unit girder integrally combining the I-shaped concrete girder and the bottom slab according to the present invention can recover economically and quickly the bridges lost or damaged due to wind and water disaster. It is a technology suitable for urgency.

1 is a perspective view showing a girder for I-type concrete filling according to a first embodiment of the present invention.
2 is a schematic cross-sectional view of a T-type composite unit girder integrally combining the I-type concrete filling girder and the bottom plate slab according to the first embodiment of the present invention.
3 is a perspective view showing a girder for I-type concrete filling according to a second embodiment of the present invention.
4 is a schematic cross-sectional view of a T-type composite unit girder integrally combining the I-type concrete filling girder and the bottom plate slab according to the second embodiment of the present invention.
5 is a schematic perspective view of a T-type composite unit girder integrally combining an I-type concrete filling girder and a bottom plate slab according to a second embodiment of the present invention.
6 is a cross-sectional view illustrating a state in which a T-type composite unit girder integrally combining an I-type concrete filling girder and a bottom plate slab according to the present invention is placed adjacent to the site.
7 is a perspective view illustrating a state in which a T-type composite unit girder integrally combining an I-type concrete filling girder and a bottom plate slab according to the present invention is brought into the field and arranged horizontally and then coupled.
FIG. 8 is a perspective view illustrating an example in which concrete is filled in the entire abdomen of the I-type concrete filling girder and the PC strands in the longitudinal direction are disposed in the concrete.

1 is a perspective view showing a girder for I-type concrete filling according to a first embodiment of the present invention, Figure 2 is a combination of the type I concrete filling girder and the bottom plate slab integrally according to the first embodiment of the present invention It is a schematic cross-sectional view of a T-type compound unit girder.

As can be seen from Figures 1 and 2, the I-shaped concrete filling girder 10 according to the first embodiment of the present invention has an upper flange (2) having a predetermined width (w1), the width of the upper flange ( A pair of I-beams 9, 9 having a lower flange 4 having a wider width w2 (w2> w1) and a web 6 connecting the upper and lower flanges vertically, have a lower flange ( 4) One end side of each side is welded to be in contact with each other in parallel with each other to form a lower butt joint 5, the portion surrounded by the upper and lower flanges (2) (4) and both webs (6) (6), the lower part is blocked and the upper part is It is an I-shaped girder part 10 which forms the open space part 8 (8a, 8b).

Reference numeral 20 is both ends welded longitudinally to the inner surface of the web 6 of the pair of I-shaped steels 9 and 9, respectively, to connect the space portion 8 to the upper space 8a and the lower space 8b. As the central plate 20 partitioned into a section, considering that compressive stress is generated at the upper side of the girder and tensile stress is generated at the lower side of the girder, the inner space of the girder is divided up and down and the concrete having high resistance to the compressive force is divided into It is a configuration to be integrated into the top only. In addition, by the central plate 20, the input position and the input amount of concrete are advantageously determined mechanically and economically, and the cross section performance (cross section secondary moment) of the steel girders is also increased, thereby increasing the rigidity as the main body of the bridge. It also has a meaning.

In this embodiment, the opening 7 continuous in the upper longitudinal direction of the space 8 serves as a work hole for welding the central plate 20 to the inner surface of the weir 6 and a work hole for pouring concrete. The transverse spacing is less than the horizontal spacing between the two webs 6 and 6, although it is determined to be of sufficient size, so that it acts as a catch for the concrete filled in the superspace 8b. It is beneficial in terms of integration between the concrete and slab slabs filled in the.

Reference numeral 40 is a plurality of shear connectors, one end is welded to the upper surface of the upper flange (2) of the pair of I-shaped steel (9) (9) and the other end is embedded in the concrete filled in the bottom slab (35), As is adopted in conventional concrete steel composite structures, it may be a stud bolt (Fig. A) or a decay bracket (Fig. B), and this shear connector 40 is also installed on the upper surface of the center plate 20 as necessary. Although not shown, it may be attached to the inner side of the web (6).

As shown in FIG. 2, the bottom plate slab 30 horizontally coupled to the upper surface of the upper flange 2 of the I-shaped girder 10 has the above-described I-type girder formed by the concrete 38 constituting the slab. It is placed and hardened with the concrete 36 injected into the upper space portion 8a of the part 10 and hardened, and the reinforcing bars 32 and 34 in the longitudinal and horizontal directions are embedded therein and protrude outward from the slab in the left and right directions. Sheath pipes 35 and 37 in the longitudinal and horizontal directions for inserting the PC strand are embedded therein.

In this first embodiment, the cover plate 50 is further coupled to the lower flange bottom surfaces of the pair of I-shaped steels 9 and 9, thereby mutually integrating and cross-sectional performance between the pair of I-shaped steels 9 and 9. The increase of flexural tensile stress and shear stress can be obtained by the increase of.

Figure 3 is a perspective view showing a type I concrete filled girder according to a second embodiment of the present invention, Figure 4 is a combination of the type I concrete filled girder and the bottom plate slab integrally according to a second embodiment of the present invention 5 is a schematic cross-sectional view of a T-type composite unit girder, and FIG. 5 is a schematic perspective view of a T-type composite unit girder integrally combining an I-type concrete filling girder and a bottom plate slab according to a second embodiment of the present invention.

3 to 5, the I-type concrete filling girder 10 according to the second embodiment of the present invention has an upper flange 2 having a predetermined width w 3, and the width w 3 of the upper flange. A pair of I-beams 9 and 9 having lower flanges 4 (w3 = w4) having a width w4 equal to) and webs 6 connecting these upper and lower flanges vertically, the upper and lower flanges ( 2) The one end side of (4) is welded to be in contact with each other in a parallel direction to form an upper and lower butt joint welding part 5, whereby the inside is surrounded by a portion surrounded by the upper and lower flanges 2, 4 and both webs 6, 6; It is an I-type girder 10 which comprises the closed space 8.

The second embodiment is different from the first embodiment described above, in the second embodiment, the upper and lower flanges 2 and 4 of the pair of I-shaped steels 9 and 9 forming the I-shaped steel girders 10. The lengths are the same, and one end side of the upper and lower flanges 2 and 4 are welded to be in contact with each other in a parallel direction to form an upper and lower butt joint welding portion 5, thereby forming the upper and lower flanges 2, 4 and both webs 6 and 6 ( 6) the inner space is enclosed by the part enclosed by the enclosed part, and due to this configuration, the work of placing concrete in the enclosed space 8 and the central plate 20 to the inner surface of the wee 6 In order to perform the welding operation, as shown in FIG. 3, a part H of which the butt joint welded part of the upper flange 2 is removed at equal or uneven intervals is formed to form this part H. It communicates with the space 8 and the outside through.

In this embodiment, a portion of the upper flange 2 welded to the butt joint, which is not extracted, is completely buried in concrete so that the buried upper flange portion can function as an additional shear connector, and thus, the first embodiment described above. There is an effect that can further consolidate the integration of the bottom plate slab 30 and the I-type girder 10 than in the case of the example.

On the other hand, it is to be understood that the size or position of the above-described picking-up portion H can be variably determined according to design conditions or working conditions.

In this second embodiment, the bottom plate of the lower flange of the pair of I-shaped steels 9 and 9 is further coupled to the cover plate 50 so that the integration and cross-sectional performance of the pair of I-shaped steels 9 and 9 members can be achieved. The effect of enhancement of flexural tensile stress and shear stress can be obtained.

Although the first and second embodiments as described above show and explain that the concrete is filled only in the upper space 8a of the I-shaped girder portion, the third embodiment shown in FIG. 8 shows the I-shaped concrete filling girder. While the entire abdomen is filled with concrete, longitudinal PC strands 90 can be further embedded in the type I steel girders, which are the mechanical subjects.

According to the third embodiment of the present invention, when the concrete is also filled in the lower space portion over the whole or part of the longitudinal direction of the I-type concrete girder, at least the lower space in which the concrete is filled is the length of the girder. It includes a section in which bending tensile stress acts on both ends and the girder in the direction. In this third embodiment, the center plate 8 adopted in the first and second embodiments described above may or may not be used as it is, or the center plate may be discontinuously installed along the longitudinal direction of the girder. In the third embodiment, when the central plate 8 is integrally installed in the entire length of the girder, as in the above-described second embodiment, the work hole take-off part H formed in the upper flange is formed, The inner part (not shown) for the working hole (concrete filling hole) may be provided at equal intervals or unequal intervals in the longitudinal direction, and the concrete may be filled up to the lower space of the girder through the hollow part.

Figure 6 is a cross-sectional view showing a state in which the I-shaped concrete filling girder and the bottom plate slab T-type composite unit girder 100 integrally combined according to the present invention is placed adjacent to the site, and FIG. It is a perspective view showing a state in which a plurality of T-type composite unit girder 100 is integrally coupled to the I-type concrete filling girder and the bottom plate slab is placed on the site and arranged in the vertical and horizontal direction.

In the construction of the prefabricated girder bridge using the T-type composite unit girder 100 according to the present invention, a unit capable of transporting the bridge deck slab 30 having a predetermined unit width with the I-type composite girder 10 at the factory can be transported on site. The construction of the actual bridge is carried out by moving the T-shaped synthetic unit girder 100 made at the factory by the precast method to the site as necessary and combining them integrally, as shown in FIGS. 6 and 7. As described above, the T-shaped composite unit girders 100 are arranged side by side in the width direction of the bridge to be laid at a predetermined interval, and then reinforcing bars 32a and 34a protruding to the outside of the bottom slab adjacent to the reinforcing bar 60. ) Is connected to each other and the concrete is placed in the space between the solidified, and then the PC strand (70) in the longitudinal sheath pipe as shown in Figure 7 in the longitudinal and transverse direction to the tension and Completed by settling.

Although not shown in the drawing, after the completion of the PC strand (70) by inserting in the longitudinal and transverse direction to the tension and fixation, as needed, road paving asphalt may be further placed on the upper surface of the bottom slab.

When the construction process of the prefabricated composite girder bridge using the T-type composite unit girder 100 according to the present invention in more detail,

I-shaped steel having an upper flange 2, a lower flange 4 having a width w2, w4 greater than or equal to the width w1, w3 of the upper flange, and a web 6 connecting the upper and lower flanges vertically. A space in which the lower part is blocked or closed by a part surrounded by the upper and lower flanges and both webs by forming a paired joint welding part 5 in the direction parallel to each other in one end side of the lower flange or each one end of the upper flange. 8) a first step of forming an I-type girder 10 in which the space becomes a concrete filling part;

A bottom plate slab placed on top of the I-type girder, the width (w5) is greater than the length of the flange of the I-type girder, longitudinal transverse reinforcement 32, 34 is extended to the outside exposed to the outside The longitudinal sheath pipes 35 and 37 for inserting the PC strand wire are embedded, and the concrete 38 is integrally placed together in the concrete filling space 8a or 8 of the type I girder. A second step of integrating with the I-type girder 10 and placing and hardening the bottom slab slab 30 to form a T-shaped composite unit girder 100 as a whole;

Reinforcing the longitudinal reinforcing bars 32a and 34a exposed to the outside between adjacent unit girders after carrying out the necessary number of the cross-sectional T-shaped synthetic unit girders 100 to the site and having a predetermined interval therebetween. A third step of connecting each other with the connecting member 50 and connecting the sheath pipes 35a and 37a for inserting the PC strand in the longitudinal and transverse directions;

A fourth step of embedding concrete in the reinforcing bar connection space between the adjacent unit T-shaped synthetic unit girder 100 to bury the reinforcing bar and the sheath pipe; And

Fifth step of inserting and stretching PC strands in sheath pipes 35 and 37 for inserting PC strands in the longitudinal and horizontal direction of adjacent unit T-shaped composite unit girder 100

And a control unit.

Also in the concrete filling part of the I-shaped girder section immediately after the third step of the construction process of the prefabricated girder bridge using the T-type composite unit girder 100 according to the present invention, along the longitudinal direction of the I-shaped girder section Inserting the PC strand (90) may further comprise the step of fixing the tension.

Unexplained symbol S is a stiffener (vertical stiffener).

Although the foregoing is not explicitly described in the description of the present invention, those skilled in the art may easily fall within the scope of the present invention as long as they may fall within the scope of the claims as examples of modifications that can be easily conceived by those skilled in the art. It must be understood.

2: upper flange 4: lower flange
6: web 7: opening
8a: upper space portion 8b: lower space portion
10: type I girder 20: center plate
30: slab slab 40: shear connector
50: cover plate 60: reinforcing bar connector
70: PC strand 100: T-type composite unit girder

Claims (8)

A pair of I-shaped steels having an upper flange 2, a lower flange 4 having a width wider than that of the upper flange, and a web 6 connecting the upper and lower flanges vertically are parallel to each other at one end side of the lower flange. By forming the butt joint 5 in the direction, the area enclosed by the upper and lower flanges and both webs forms a space 8 in which the lower part is blocked and the upper part is opened, so that at least a part of the space becomes this concrete filling part. Part 10;

A plurality of shear connectors 40, one end of which is welded to the upper surface of the upper flange 2 of the pair of I-shaped steels 9 and 9, and the other end is embedded in the concrete 38 filled in the bottom plate slab 30. ;

A cover plate 50 coupled to the bottom surface of the lower flange of the pair of I-shaped steels 9 and 9;

A center plate 20 having both ends welded to the web inner surfaces of the pair of I-shaped steels 9 and 9 to divide the space portion 8 into an upper space 8a and a lower space 8b;

A plurality of shear connection members 40 welded to the upper surface of the central plate 20 and having the other end embedded in concrete filled in the I-type girder 10; And

A concrete slab slab placed on top of the I-shaped girder portion, the width is greater than the length of the entire flange of the I-shaped girder portion, longitudinally reinforcing bars 32, 34 are disposed inside the exposed exposure, Sheath pipes (35) and (37) for inserting PC strands are embedded, and bottom plate slab parts in which concrete is poured together with the concrete filling portion of the I-type girder portion to be integrated with the I-type girder portion ( 30);

T-type composite unit girder 100 that integrally combines the I-type concrete filling girder and the precast bottom plate, characterized in that it comprises a
A pair of I-beams 9, 9 having an upper flange 2, a lower flange 4 having a width equal to the width of the upper flange, and a web 6 connecting the upper and lower flanges vertically. I-shaped girder 10, which forms an enclosed space surrounded by the upper and lower flanges and both webs by forming the butt joint welding portions in parallel directions with each end side of the upper and lower flanges, wherein the sealed space is a concrete filling portion 10;

A plurality of shear connectors 40, one end of which is welded to the upper surface of the upper flange 2 of the pair of I-shaped steels 9 and 9, and the other end is embedded in the concrete 38 filled in the bottom plate slab 30. ;

A cover plate 50 coupled to the bottom surface of the lower flange of the pair of I-shaped steels 9 and 9;

A center plate 20 having both ends welded to the web inner surfaces of the pair of I-shaped steels 9 and 9 to divide the space portion 8 into an upper space 8a and a lower space 8b;

A plurality of shear connection members 40 welded to the upper surface of the central plate 20 and having the other end embedded in concrete filled in the I-type girder 10; And

A concrete slab slab placed on top of the I-type girder, the width of the length is longer than the flange length of the I-type girder, longitudinal reinforcing bars 32, 34 are arranged in the interior is exposed to the outside, PC Sheath pipes 35 and 37 for embedding strand wires are embedded, and concrete is poured together with the concrete filling portion of the I-shaped girder portion, and the bottom plate slab portion 30 is integrated with the I-shaped girder portion 30. );

Each of the upper flanges of the pair of I-beams is formed with I-shaped concrete filling girder and precast bottom plate, characterized in that the work hole is formed at equal intervals or uneven intervals in communication with the filling portion along the longitudinal direction of the I-beams. T-type composite unit girder (100)

delete delete delete delete I-shaped steel having an upper flange 2, a lower flange 4 having a width w2, w4 greater than or equal to the width w1, w3 of the upper flange, and a web 6 connecting the upper and lower flanges vertically. A pair is formed by abutting-joint 5 between one end side of the lower flange or each one end of the upper and lower flanges in parallel with each other, thereby enclosing a space where the lower portion is blocked or closed by a portion enclosed by the upper and lower flanges. A first step of providing an I-type girder 10 in which the space is a concrete filling space 8 or 8a;

A bottom plate slab placed on top of the I-type girder, the width (w5) is greater than the length of the flange of the I-type girder, longitudinal transverse reinforcement 32, 34 is extended to the outside exposed to the outside The longitudinal sheath pipes 35 and 37 for inserting the PC strand wire are embedded, and concrete is poured together into the concrete filling space 8a or 8 of the type I steel girders together. A second step of placing the bottom plate slab portion 30 integrally formed with the girder 10 and manufacturing and preparing the composite unit girder 100 having a T-section as a whole;

After loading the required number of cross-section T-shaped composite unit girder 100 into the site and arranging it in the longitudinal direction to have a predetermined interval, the longitudinal cross-bars exposed to the outside between adjacent T-shaped composite unit girder 100 ( A third step of connecting 32a) 34a to each other with a reinforcing bar connector 50 and to connect sheath pipes 35a and 37a for PC strand insertion in the longitudinal and transverse directions;

A fourth step of embedding concrete in the reinforcing bar connection space between the adjacent unit T-shaped synthetic unit girder 100 to bury the reinforcing bar and the sheath pipe; And

A fifth step of inserting and tensioning the PC strand wire 70 into the sheath pipes 35 and 37 for inserting the PC strand wire in the longitudinal and horizontal directions of the adjacent unit T-shaped composite unit girder 100;
Precast deck construction method using a T-type composite unit girder integrally combining the I-type concrete filling girder and the bottom plate, characterized in that it comprises a
In claim 7,
Immediately after the third step, I-type concrete, characterized in that it further comprises the step of fixing by inserting the PC strand (90) in the concrete filling portion of the I-type girder section along the longitudinal direction of the I-type girder section Construction method of precast deck using T-shaped composite unit girder combining the filling girder and the bottom plate

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