KR102042090B1 - Abutment integrated with H-pile in integral abutment bridge, and Constructing method thereof - Google Patents

Abstract

The present invention relates to an integral shift that can be usefully applied to earth pressure separation type integral shift bridges, and a method of constructing such an integral shift, and specifically, a plurality of H piles 1 installed intruding into the ground. As an integral shift (100) comprising an alternating structure (4) constructed in an integrated state with the head of the H stake (1) by the site-casting concrete so that the head of the H stake (1) is embedded, the precast floor By constructing the alternating structure 4 by the site-pouring concrete using the plate-reinforcing bar assembly 3 and the supporting plate 2, the separation between the alternating structure 4 and the ground is ensured and the ground transfer of the load through the ground is ensured. It is possible to prevent ground disturbance by suppressing, and to effectively prevent local breakdown and the like by suppressing stress concentration in the load transfer process to the H-pile 1 Relates to rebar combination with a support plate integral with the shift and construction method with the integrated structure of the H pile and concrete structure with alternating "cast bottom plate.

Description

Abutment integrated with H-pile in integral abutment bridge, and Constructing method

The present invention relates to an integral shift in an integral shift bridge in which an H stake and an in-place cast concrete alternating structure are integrated, such as a seismic separation integrated bridge, and a method of constructing such an integrated structure. In constructing the alternating structure using the cast-in-place concrete on the head and constructing the integral shift in the integral shifting bridge, by using the precast deck plate-reinforced steel reinforcement and supporting plate, the alternating structure is constructed by the cast-in-place concrete To prevent ground disturbances by ensuring separation between the alternating structure and the ground, suppressing ground transfer of loads through the ground, and effectively preventing local breakdown by suppressing stress concentration during load transfer to the H-pile. New configuration of "precast decks-reinforcement bars" "Integral shift having a unified structure of H pile and concrete alternating structure using an assembly and a support plate" and a construction method thereof.

The bridge that forms the shift in an integrated form of the H pile of the steel installed in the ground and the concrete structure is called an "integrated shift bridge" and an example thereof is disclosed in Korean Patent Registration No. 10-0312066. In particular, Republic of Korea Patent No. 10-1664834 discloses another example of the prior art for the integral bridge bridge under the name of the invention "earth pressure-separated integrated bridge and its construction method".

This integral bridge bridge has a superior force generated at both ends of the bridge in the bridge direction by allowing the H pile and the bridge to move freely in the bridge direction when the bridge axial displacement of the bridge superstructure occurs due to temperature change or dry shrinkage. Minimize the effect caused by the structural features.

In the prior art, after constructing the H pile into the ground, the integral shift is constructed by constructing an alternating structure by pouring concrete in the field so that the head of the H pile protruding from the ground is embedded in the concrete. It was. However, in the prior art, the bottom surface of the alternating structure is directly in contact with the ground, and in this case, the weight of the bridge is transferred to the ground through the ground in addition to the H pile, thereby disturbing the ground.

In addition, in the prior art, when the alternating structure moves in the axial direction due to temperature change or drying shrinkage, the alternating direction of the alternating structure is increased due to excessive frictional force caused by direct contact between the bottom of the alternating structure and the ground. Not only will it not be free to move, but it will also cause significant disturbances to the ground.

On the other hand, when the integral shift bridge moves in the axial direction, the shaft ("weak axis") where the secondary cross section moment of the H stake is small ("weak axis") is disposed to resist the load in order to minimize the force due to the bending resistance of the H stake. In the prior art, due to this configuration, excessive acupressure stress occurs on the contact surface with the concrete forming the alternating structure by the side portions of the upper and lower flanges of the H pile, which causes the acupressure breakdown of the concrete of the alternating structure. There is a problem that is very likely to occur. In order to reinforce this, a method of applying a method such as reinforcing the reinforcing bar which provides the core restraint effect on the concrete of the alternating structure around the pile or installing a separate pressure plate on the head of the H pile has been proposed. There is no proposal to effectively reinforce the joint surface between the lower end of the alternating structure and the upper and lower flanges of the H pile.

Republic of Korea Patent Publication No. 10-0312066 (August 28, 2001). Republic of Korea Patent Publication No. 10-1664834 (announced on October 13, 2016).

The present invention has been developed to overcome the above limitations of the prior art. Specifically, the present invention is an integral shift that can be usefully applied to earth pressure separation type integral bridges and the like, and integrally combines an alternating structure made of concrete members on the head of the H-penetrated pipe. Construct shifts, minimizing direct contact between the bottom of the alternating structure and the ground and allowing the bridge's own weight to be transferred to the ground through the H pile, thereby minimizing ground transfer through the ground of the bridge's own weight and thereby suppressing ground disturbance It aims to provide a technology that enables it.

In addition, the present invention, by minimizing the friction caused by the direct contact between the alternating structure and the ground to separate the alternating structure from the ground, when the alternating axial displacement of the bridge superstructure occurs due to temperature changes or dry shrinkage, the alternating structure is free to the axial direction It aims to provide a technology that allows movement and prevents disturbances to the ground during this process.

Furthermore, the present invention, even if excessive horizontal displacement occurs in the axial direction by effectively dispersing the stress concentrated in the contact portion between the lower end of the alternating structure and the upper, lower flange of the H pile due to the axial movement of the bridge superstructure It is an object of the present invention to provide a technique for maintaining the integrity of the connection between the H and the H pile.

In order to achieve the above object, in the present invention, a plurality of H piles intruding into the ground, and the alternating structure that is built in a state integral with the head of the H pile by the site-cast concrete so that the head of the H pile is embedded As an integral shift, a support plate made of a plate member is arranged in a horizontally across the H pile and integrally coupled to the H pile; The precast deck-reinforced bar assembly, which is pre-fabricated to have a plate-shaped precast deck with a through-hole formed at the center and a rebar assembly fixed to the precast deck, has a H pile at the through section. A plurality of precast bottom plates are successively formed in one flat member by being installed on each of the plurality of H piles so that the penetrating portion is blocked by the supporting plate while being placed on the supporting plate in the penetrating state. Concrete is cast in place over the planar member made by the plurality of precast decks, the head and the reinforcing bar assembly of the H stake are embedded in the concrete, and the alternating structure is constructed with the support plate integrated with the concrete. The ground of H pile is inserted into the ground and the lower surface of the alternating structure is not in contact with each other, and the load applied through the alternating structure is directly applied to the head of the H pile and transferred to the supporting plate and distributed to the H pile. An integral shift is provided which is characterized in that a loss.

The present invention also provides a method for constructing such integral shifts.

In the integrated shift and the construction method according to the present invention described above, the upper surface of the support plate, may be integrally provided in the state in which the buried connection member is projected so as to be embedded in the concrete of the alternating structure, furthermore, the support plate is a pair of two The plate member constituting each support plate is formed with a cutout portion into which the upper flange and the lower flange of the H pile are fitted, so that each support plate is horizontally approached in the lateral direction of the H pile so that the upper flange and the lower portion are cut. It may have a configuration that is provided by coupling the support plate to the H pile in a state that each flange is made to fit.

In the integral shift according to the present invention, when the alternating structure is separated from the ground, when the axial displacement of the bridge superstructure occurs due to temperature change or dry shrinkage, the alternating structure is freely throttled without causing friction force between the alternating structure and the ground. It is possible to move in the direction, there is an advantage that the disturbance of the ground caused by the friction force does not occur in this process.

In addition, in the integral shift according to the present invention, a part of the load applied to the H stake through the alternating structure is transferred to the support plate through the buried connection material and is applied to the H stake in a distributed form, thereby causing destruction due to the concentration of load transfer. There is an advantage that can effectively prevent problems such as. That is, according to the present invention, when the axial movement of the bridge upper structure occurs, it is possible to effectively dissipate the stress generated at the contact portion between the lower end of the alternating structure and the upper and lower flanges of the H pile, and thus the alternating structure There is an advantage that can effectively maintain the soundness at the connection between the and H pile.

Furthermore, in the integral shift according to the invention. As above, the load is transmitted to the H pile in a distributed form through the buried connection member and the support plate, and the ground and the lower surface of the alternating structure are in a separated state without directly contacting each other, thereby minimizing the transfer of the load to the ground through the ground. There is also an advantage that can effectively suppress the disturbance of the ground.

1 is a schematic assembly perspective view showing a state in which the support plate and the precast alternating bottom plate member are assembled to the head of the H pile according to the present invention.
FIG. 2 is a schematic exploded perspective view showing a state in which each component for forming the state shown in FIG. 1 is separated.
3 is a schematic perspective view showing various embodiments of the support plate.
FIG. 4 is a schematic perspective view of the precast deck plate-reinforcing bar assembly provided in the embodiment of the present invention shown in FIGS. 1 and 2.
FIG. 5 is a schematic perspective view illustrating a process in which the support plate shown in FIG.
FIG. 6 is a schematic perspective view illustrating a process in which the support plate shown in FIG.
FIG. 7 is a schematic perspective view showing that the precast deck plate-reinforcing bar assembly is placed on the support plate while the support plate is coupled to the H pile.
8 is a schematic perspective view showing a state in which a support plate and a precast bottom plate-reinforcing reinforcing bar assembly are coupled to each H pile after installing a plurality of H piles.

Hereinafter, with reference to the accompanying drawings, preferred embodiments of the present invention will be described. Although the present invention has been described with reference to the embodiments shown in the drawings, this is described as one embodiment, whereby the technical spirit of the present invention and its core configuration and operation are not limited.

In the integrated shift 100 according to the present invention, the concrete is poured in the field so that the H-pile 1 installed in the ground and the head (protrusion above the ground) of the H-pile 1 are embedded. The shift structure 4 is constructed in such a way as to be integrated with the head of the H pile 1 by the following process.

1 is assembled with a support plate 2 and a precast bottom plate-reinforcing reinforcing bar assembly 3 on the head of the H pile 1 in order to integrally construct a shift structure to the head of the H pile in accordance with the present invention A schematic assembled perspective view showing a state is shown, and FIG. 2 is a schematic exploded perspective view showing a state in which each component for achieving the state shown in FIG. 1 is separated. FIG. 3 is a schematic perspective view showing various embodiments of the support plate 2, and FIG. 4 is a schematic of a precast sole plate-reinforcing bar assembly 3 provided in the embodiment shown in FIGS. 1 and 2. A perspective view of phosphorus is shown.

Penetrating and installing the H pile (1) made of steel in the ground, while the head of the H pile (1) protrudes above the ground, the support plate (2) is integrally coupled to the head of the H pile (1). The support plate 2 is made of a plate member and is arranged in a shape to cross the H pile 1 horizontally and is integrally coupled to the H pile 1. An upper surface of the support plate 2 is integrally provided with a buried connection member 21 such as a stud in a protruding state, and when the alternating structure 4 is constructed by in-situ concrete as described below, the buried connection member 21 alternates. It is embedded in the concrete of the structure (4).

Therefore, in the force transmission process between the alternating structure 4 and the H pile 1, a force dissipation action by the buried connection member 21 occurs, whereby the alternating structure 4 and the H pile 1 directly contact each other. The stress concentration phenomenon can be suppressed, and the acupressure breakdown due to the stress concentration can be effectively prevented. As described above, in the prior art, the head of the H pile is simply embedded in the concrete forming the alternating structure while the H pile is disposed so that the weak axis of the H pile (the direction in which the upper and lower flanges extend) faces the axial direction. Therefore, when the bridge moves in the axial direction, excessive acupressure stress occurs on the contact surface with the concrete forming the alternating structure by the side portions of the upper and lower flanges of the H pile, which may cause the acupressure destruction on the concrete of the alternating structure. There was a problem that this was very high. However, in the present invention, the support plate 2 having the buried connection member 21 as described above is integrally provided in the H pile 1, and the buried connection member 21 is alternately structured by the site-casting concrete so that the buried connection member 21 is embedded in the concrete. ) Is formed on the upper surface of the support plate 2, so that part of the load applied to the H pile 1 through the alternating structure 4 is directly H through the head of the H pile 1 embedded in the alternating structure 4. Although transmitted to the pile 1, a part of the load acting on the H pile 1 by the alternating structure 4 is transmitted to the H pile 1 through the buried connection material 21 and the support plate 2. That is, not all of the load by the alternating structure 4 is transmitted through the direct connection surface 21 and the support plate 2, but is distributed by bypass through the direct contact surfaces of the upper and lower flanges of the H pile 1 and the concrete. It is delivered to the H pile (1). Thus, in the present invention, it is possible to distribute the stress in the contact surface between the concrete forming the H pile (1) and the alternating structure (4), thus solving the problems caused by the stress concentration as in the prior art, bridge superstructure and shift Even if the horizontal displacement occurs, it is possible to maintain the integrity of the connection between the alternating structure and the H pile.

On the other hand, as will be described later, the present invention may be provided with a precast floor-reinforced steel assembly (3), if necessary, in this case, the support plate (2) between the alternating structure (4) and the H pile (1) In addition to performing a stress distribution function, the precast bottom-rebar assembly 3 supports the precast floor-rebar assembly 3 so that the precast floor-rebar assembly 3 is stably positioned at the designed position, and furthermore, the precast floor Blocking the penetrating portion 30 in the state where the H pile 1 penetrates the penetrating portion 30 of the reinforcing bar coupling unit 3 to prevent the on-site casting concrete for the construction of the alternating structure 4 from leaking. It also functions. That is, in the case of using the precast floor-reinforcing bar assembly 3, the supporting plate 2 crosses the H-pile 1 at the lower surface of the precast floor-reinforcing bar assembly 3, and then the precast floor-reinforcing bar assembly. (3) to form a plane to close the through portion 30.

As mentioned above, the supporting plate 2 is formed of a plate member, and two pairs are formed as shown in FIG. 3 (a), and each plate member includes an upper flange 11 of the H pile 1. The lower flange 12 may have a configuration in which the cutout portions 20 to which the flanges 12 are fitted. FIG. 5 is a schematic perspective view illustrating a process in which the support plate 2 illustrated in FIG. 3A is coupled to the H pile 1 and a state in which the coupling installation is completed, respectively, as shown in FIG. The support plate 2 is horizontally approached in the lateral direction of the H pile 1 so that the upper flange 11 and the lower flange 12 are fitted to the cutout 20, respectively. ) Is integrally attached to the H pile (1).

However, in the present invention, the support plate 2 is a portion fitted horizontally to the region surrounded by the upper, lower flanges 11 and 12 and the abdomen 13 of the H pile 1, as shown in (b) of FIG. Branch may be made of a plate member having a planar shape of the T-shape. In the support plate 2 shown in (b) of FIG. 3, portions other than the horizontal fitting of the upper and lower flanges 11 and 12 and the area enclosed by the abdomen 13, the support plate 2 is formed by the H pile ( When coupled to 1) will be present horizontally on the outside of the H pile (1).

FIG. 6 is a schematic perspective view illustrating a process in which the support plate 2 shown in FIG. 3 (b) is coupled to the H pile 1 and a state in which coupling is completed, respectively, of FIG. 3 (b). As shown in FIG. 6, the support plate 2 is also horizontally approached in the lateral direction of the H pile 1 to be brought into contact with the H pile 1, and then welded to a portion that is in contact with the H pile 1. H is integrally attached to the pile (1).

Although not illustrated in the drawing, the support plate 2 is a simple rectangular plate member having a width equal to the length of the abdomen 13 of the H pile 1 and a length of at least half of the upper and lower flanges 11 and 12. It may be made of. In this case, the support plate 2 protrudes outward from the upper and lower flanges 11 and 12 while being horizontally fitted in the area surrounded by the upper and lower flanges 11 and 12 and the abdomen 13 of the H pile 1. The part is present, and thus it is possible to perform all the functions of the support plate 2 described above. In other words. In the present invention, the support plate 2 includes a portion to be horizontally fitted in the area surrounded by the upper and lower flanges 11 and 12 and the abdomen 13 of the H pile 1, the precast bottom plate 31 to be described later It is sufficient that the plate member having a size of more than half the area of the penetrating portion 30 formed in the.

Furthermore, in the above, the support plate 2 has been described as forming a pair of two so as to be respectively coupled at both sides of the H pile 1, the support plate 2 is inserted in the center corresponding to the planar shape of the H pile 1 The ball is formed of one plate member, it may be provided integrally to the H pile 1 by welding or the like in the state in which the H pile 1 is inserted into the insertion hole.

After the supporting plates 2 are respectively installed on both sides of the H pile 1 as illustrated in FIGS. 5B and 6B, the precast bottom plate as shown in FIG. 7 as necessary. The rebar assembly 3 may be further provided. That is, in the present invention, after the support plate 2 is installed on the H pile 1, the formwork is placed above the support plate 2 and the concrete is poured, so that the support plate 2 is made of concrete. It is also possible to construct an integral shift in the form of being integrated on the lower surface, but the alternating structure 4 may be constructed by further installing a "precast deck plate-reinforcing bar assembly" (3).

As illustrated in FIG. 4, the precast bottom plate-reinforcing bar assembly 3 includes a precast bottom plate 31 which forms the bottom surface of the alternating structure 4, and a lower end of the precast bottom plate 31. It is configured to include a reinforcing bar assembly 32 is fixed to and installed to extend vertically to the top of the precast bottom plate 31. Specifically, the precast bottom plate 31 is a plate-shaped member having a thickness pre-fabricated by cement-based materials such as concrete, and a penetrating portion 30 through which the H stake 1 penetrates is formed in the vertical direction at the center thereof. It is. The rebar assembly 32 is a member embedded in the concrete forming the alternating structure 4 to reinforce the alternating structure 4, and may be formed of an assembly of vertical reinforcing bars and horizontal reinforcing bars as illustrated in the drawing. In the present invention, the reinforcing bar assembly 32 has a lower end integrally fixed to the precast bottom plate 31. For this purpose, the precast bottom plate 31 is manufactured with the lower end of the reinforcing bar assembly 32 embedded in the cement-based material forming the precast bottom plate 31. As mentioned above, the reinforcing bar assembly 32 basically has a reinforcing function of the alternating structure 4, and thus, when constructing the alternating structure 4 by in-situ concrete as described later, the reinforcing structure of the alternating structure 4 is described. It is possible to omit or minimize the reinforcement for the reinforcement, so that the work efficiency can be improved by reducing the field work. Further, the reinforcing bar assembly 32 plays a large role in making the precast base plate 31 and the site-cast concrete to be placed thereon firmly integrate.

The precast bottom plate-reinforcing bar assembly 3, which is prefabricated with the reinforcing bar assembly 32 and the precast bottom plate 31 in one piece, penetrates the H-pit 1 through the penetrating portion 30. It is mounted on the support plate (2). FIG. 7 is a schematic perspective view showing the installation of the precast bottom plate-reinforcing reinforcing bar assembly 3 on the support plate 2 in a state in which the support plate 2 is coupled to the H pile 1. When the work as shown in FIG. 7 is made, the support plate 2 supports the precast sole plate 31 at its lower surface, and the precast sole plate-reinforcing bar assembly 3 is stably positioned at the desired height. Done. In addition, in the state where the precast bottom plate-reinforcing bar assembly 3 is installed on the support plate 2 as described above, the load of the load applied from the precast bottom plate-reinforcing bar assembly 3 is directly transferred through the support plate 2 to the H pile ( Delivered to 1).

On the other hand, when the precast bottom plate-reinforcing bar assembly 3 is placed on the support plate 2, the through part 30 formed in the precast bottom plate 31 is blocked by the support plate 2, and the support plate The buried connection member 21 provided on the upper surface of the (2) is in a state protruding through the through part (30).

In the above, it was described that the support plate 2 and the precast bottom plate-reinforcing bar assembly 3 are installed in the H pile 1 by exemplifying one H pile 1, but in the integrated shift according to the present invention, the shift is performed. Since the structure has a configuration that is coupled to the plurality of H pile heads, the plurality of H piles are installed to form a row in the perpendicular direction of the axial axis, and then the support plate (2) to each H pile through the process as described above And precast bottom plate-reinforced reinforcing bar assembly (3) is installed. FIG. 8 is a schematic perspective view showing a state in which the support plate 2 and the precast bottom plate-reinforcing bar assembly 3 are coupled to each H pile after installing the plurality of H piles.

After arranging the precast deck plate-reinforcing bar assemblies 3 on all of the plurality of H piles 1 as shown in FIG. 8, formwork (not shown in the drawing) is installed and site-cast concrete is poured. By constructing the alternating structure 4 with the head of the H pile 1 and the reinforcing bar assembly 32 embedded in concrete, the integral shift 100 according to the present invention is manufactured. At this time, if necessary, before the installation of the formwork member or before the casting of the site-casting concrete, the work of further reinforcing the additional reinforcing bar for reinforcing the alternating structure 4 may be performed. However, as mentioned above, the precast deck plate-reinforced bar assembly 3 is equipped with a rebar assembly 32 for reinforcing the alternating structure 4, so that even when additional rebars need to be added, the amount of reinforcement is increased. Can be minimized, thereby reducing the number of on-site work, improving work efficiency, and reducing costs.

When the precast deck plate-reinforcing bar assembly 3 is disposed on all of the plurality of H piles 1, the precast deck plate 31 provided in each precast deck plate-reinforcing bar assembly 3 is While horizontally continuous with each other, to form a flat member having a length in the axial direction perpendicular to the alternating design, the planar members formed in such a way that the precast bottom plate 31 is horizontally continuous with each other substantially alternate structure ( At the same time, the lower surface of 4) forms the lower surface of the formwork for concrete casting, and serves as a formwork member. Therefore, in the present invention, even if the alternating structure (4) is made of cast-in-place concrete, the installation of the formwork member is not necessary, and the construction efficiency is greatly improved.

In the integrated shift 100 according to the present invention constructed by the above method, as described above, the lower surface of the alternating structure 4 constructed by the site-pouring concrete consists of a precast bottom plate 31 to support the plate 2 Will be on top. That is, in the present invention, even when the alternating structure 4 is constructed by placing concrete in the field, the support plate 2 is present between the precast floor plate 31 and the ground, and the site is cast by the precast floor plate 31. Between the concrete and the ground. Therefore, the "completely separated state of the alternating structure 4 and the ground" in which the ground of the ground on which the H pile 1 is inserted and the lower surface of the alternating structure 4 are not directly in contact with each other is created.

As described above, in the present invention, since the alternating structure 4 is separated from the ground, when the axial displacement of the bridge superstructure occurs due to temperature change or dry shrinkage, the alternating structure 4 is shifted without causing friction force between the alternating structure 4 and the ground. The structure 4 can move freely in the axial direction, and in this process, the ground disturbance caused by the frictional force does not occur.

Since the head of the H pile 1 is embedded in the alternating structure 4 and integrated, the load applied through the alternating structure 4 is transferred to the H pile 1 as a result, but in the present invention, the precast floor plate- Since the reinforcing bar assembly 3 is placed on the supporting plate 2 coupled to the H pile 1 and the supporting plate 2 is integrated with the alternating structure 4 constructed by the cast-in-place concrete, the alternating structure 4 is A portion of the load applied to the H pile 1 is transmitted to the support plate 2 through the buried connection member 21 to the H pile 1, and thus the load is substantially distributed in the H pile 1. ) Is added. As such, in the present invention, the load is not concentrated to the H pile 1 only through the direct contact portion of the head and the alternating structure 4 of the H pile 1, and the buried connection material 21 and the support plate 2 are not transferred. It is transmitted to the H pile (1) in a dispersed form, thereby effectively preventing problems such as causing breakage due to concentration of load transmission.

That is, in the prior art, when the bridge moves in the axial direction, excessive acupressure stress occurs on the contact surface with the concrete forming the alternating structure by the side portions of the upper and lower flanges of the H pile, which causes the acupressure breakdown of the concrete of the alternating structure. Although very likely to occur, in the case of the present invention, it is possible to disperse the stress in the contact surface between the concrete forming the H pile and the alternating structure through the configuration including the buried connection member 21 as described above, and thus as in the prior art By solving the problem due to the stress concentration, it is possible to maintain the integrity of the connection between the alternating structure and the H pile even if the horizontal displacement of the bridge superstructure and alternating.

Furthermore, in the present invention, the load is transmitted to the H pile 1 in a distributed form through the buried connection member 21 and the support plate 2 as described above, and the ground and the alternating structure 4 due to the presence of the buried connection member 21. Since the lower surface is in a separated state without direct contact, it is possible to minimize the transfer of the load to the ground through the ground has the advantage that can effectively suppress the disturbance of the ground.

In addition, in the present invention, the shear connector for shear bonding between the steel flange and the concrete bottom plate can be used as the buried connector 21 in the existing steel composite bridge, and thus the shear connector is installed in the processed steel sheet. Existing methods can be used to install the buried connectors very efficiently.

In describing the present invention, in the embodiment illustrated in the drawings, the H-pillar is disposed such that the weak axis of the H-pillar (the direction in which the upper and lower flanges extend) is oriented in the axial direction, but the present invention is not limited thereto. The weak axis may be oriented perpendicular to the axial axis.

The integral shift of the present invention described above may be usefully applied to various types of integral alternating bridges, such as "earth pressure separating integral alternating bridges".

1: H stake
2: support plate
3: Precast Sole-Reinforced Bar Assembly
4: shift structure
100: integral shift

Claims (6)

A plurality of H piles (1) installed in the ground and the alternating structure (4) built in the state integral with the head of the H pile (1) by the site-pouring concrete so that the head of the H pile (1) is embedded As an integral shift 100 to say,
The support plate 2 which consists of plate members is arrange | positioned in the shape which transverses the H pile 1 horizontally, and is integrally couple | bonded with the H pile 1;
An upper surface of the support plate 2 is integrally provided with the buried connection member 21 protruding;
Precast floor prefabricated to have a plate-shaped precast bottom plate 31 with a penetrating portion 30 formed in the center and a reinforcing bar assembly 32 fixed to the precast bottom plate 31. A plate-reinforcing bar assembly (3) is placed on the support plate (2) with the H-penetration (1) penetrating the through section (30);
Each precast bottom plate-reinforcing reinforcing bar assembly 3 has a buried connection member 21 of the support plate 2 protruding through the penetrating portion 30 and blocked by the support plate 2 so that the penetrating portion 30 is formed. Installed in each of the plurality of H piles 1 in a clogged form, and the plurality of precast bottom plates 31 continuously form one flat member;
And the mold is installed to achieve a shift structure (4), the concrete a plurality of landscape when the lower face of the abutment structure (4) is created and by casting a bottom plate 31 at the same time as yirum be to also serve as a mold member is planar member Site-poured above, the rebar assembly 32 is embedded in the concrete of the alternating structure 4 and the precast bottom plate 31 is integrated with the alternating structure 4, the head of the H pile 1 and the buried connection material ( 21) is embedded in the site-poured concrete so that the alternating structure 4 is constructed with the support plate 2 integrated with the concrete;
A portion of the load applied to the H pile 1 through the alternating structure 4 is transferred directly to the H pile 1 through the head of the H pile 1 embedded in the alternating structure 4, but the alternating structure 4 A part of the load applied to the H pile 1 through) is transmitted in a form distributed by way of the buried connection member 21 and the support plate 2 to the H pile 1 in a by-pass manner;
The ground of the ground on which the H pile 1 is inserted and the lower surface of the alternating structure 4 produced by the site-pouring concrete directly contact each other due to the support plate 2 and the precast bottom plate 31 placed thereon. It is in a separated state without the bridge structure, characterized in that the alternating structure (4) can move in the axial direction without causing ground disturbance caused by the frictional force between the alternating structure (4) and the ground when the axial displacement of the bridge superstructure occurs One-piece shift.
The method of claim 1,
The support plate 2 is a pair of two,
The plate member constituting each of the supporting plates 2 is formed with a cutout 20 into which the upper flange 11 and the lower flange 12 of the H pile 1 are fitted. The support plate 2 is coupled to the H pile 1 in a state in which the upper flange 11 and the lower flange 12 are fitted to the cutout 20 so as to approach horizontally in the side direction of the pile 1. Integral shift characterized in that.
delete Install a plurality of H piles 1 in the ground;
It consists of a plate member, the support plate (2) which is integrally provided with the buried connection member 21 is protruded on the upper surface, is arranged in the form to cross the H pile (1) horizontally coupled to the H pile (1) integrally Install;
Precast bottom plate-reinforced to have a plate-shaped precast bottom plate 31 with a penetrating portion 30 formed in the center and a reinforcing bar assembly 32 fixed to the precast bottom plate 31. After the reinforcing bar assembly 3 is manufactured in advance and transported to the site, the reinforcing connector 3 of the support plate 2 is placed on the support plate 2 in a state where the H-penetration 1 penetrates the through part 30. The precast bottom plate-reinforcing bar assembly 3 is installed on each of the plurality of H piles 1 so as to protrude through the penetrating portion 30 and the penetrating portion 30 is blocked by the support plate 2. Two precast bottom plates 31 in series to form one flat member;
By a plurality of pre-created by casting a bottom plate 31, so when the lower face of the abutment structure (4) at the same time as yirum install the mold to the top also has planar member being performed serves as a mold member, and cast-in-place concrete, rebar assembly (32) is embedded in the site-pouring concrete forming the alternating structure (4) and the precast deck 31 is integrated with the site-pouring concrete forming the alternating structure (4), the head of the H pile (1) and the buried connection material ( 21) is embedded in the concrete and the support plate (2) including the step of building the alternating structure (4) in the state of being integrated with the site-cast concrete, thereby the load of the load applied to the H pile (1) through the alternating structure (4) Some are transferred directly to the H pile 1 through the head of the H pile 1 embedded in the alternating structure 4, but a part of the load applied to the H pile 1 through the alternating structure 4 is the buried connection material. 21 and ji It is transmitted in a form distributed by way of the plate (2) to the H pile (1), the ground of the ground is installed H-penetration 1 and the lower surface of the alternating structure (4) made by the site-cast concrete, Due to the support plate 2 and the precast bottom plate 31 placed thereon, they are separated from each other without being in direct contact with each other, resulting in ground disturbance caused by friction between the alternating structure 4 and the ground when an axial displacement of the bridge superstructure occurs. A method of constructing an integral shift, characterized in that the alternating structure (4) to construct an integral shift having a configuration that can move in the axial direction without causing.
The method of claim 4, wherein
The support plates 2 are paired in two;
Plate members constituting each of the supporting plates 2 form cutouts 20 into which the upper flange 11 and the lower flange 12 of the H pile 1 are fitted;
When the support plate 2 is integrally installed to the H pile 1, the upper plate 11 and the lower portion of the cutout 20 are brought into close contact with each support plate 2 horizontally in the lateral direction of the H pile 1. Construction method of the integral shift characterized in that the support plate (2) is attached to the H pile (1) in a state that the flange 12 is made to fit each.
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