JP6343214B2 - Steel slab reinforcement structure - Google Patents

Description

  The present invention relates to a reinforcing structure for a steel deck and a method for reinforcing a steel deck.

As a floor slab used for a bridge, a steel slab reinforced by welding ribs such as vertical ribs and horizontal ribs made of steel on the lower surface of a flat deck plate made of steel is known.
Such steel slabs are widely used because they are simpler to construct on site than reinforced concrete slabs because they do not require concrete placement or are lightweight.

By the way, the steel floor slab is fatigued and damaged by the load of the vehicle passing over the bridge and the earthquake, the welded portion of the deck plate and rib is cracked, and the phenomenon that the crack propagates into the deck plate and weld bead has occurred, It is necessary to reinforce this.
Therefore, as in Patent Document 1, a steel reinforcing plate is brought into contact with the lower surface of the deck plate of the steel floor slab, and a through hole is formed in the deck plate and the reinforcing plate. A reinforcing method for fixing the reinforcing plate to the deck plate is performed.

However, with this type of reinforcement method, it is necessary to remove the pavement provided on the top surface of the deck plate and perform drilling work in order to form a through hole through which the bolt passes through the existing deck plate. It takes time.
Moreover, since it is necessary to regulate the traffic of the bridge within the range where the pavement is removed, it also hinders traffic. Furthermore, since the through hole is formed in the deck plate, the strength of the deck plate itself may be reduced.

JP 2008-50774 A

  Therefore, the problem to be solved by the present invention is to reinforce the steel floor slab without forming a through hole in the deck plate.

  In order to solve the above-described problems, according to the present invention, a stud bolt is welded to the lower surface of the deck plate of the steel deck and the reinforcing plate applied to the lower surface of the deck plate is fixed by the stud bolt.

That is, the steel floor slab reinforcement structure according to the present invention includes a steel deck plate, a steel rib disposed below the deck plate, a bottom surface of the deck plate, and a side surface of the rib. A stud bolt connected to at least the lower surface of the deck plate via a welded portion; and a bolt communication hole penetrating in the thickness direction. The stud bolt is inserted into the bolt communication hole, and the upper surface of the stud plate is connected to the deck plate. A steel reinforcing plate abutted on the lower surface and a nut that is screwed into the stud bolt and presses the reinforcing plate against the lower surface of the deck plate are provided.
Here, the stud bolt may be connected not only to the lower surface of the deck plate but also to the side surface of the rib via a welded portion.

  In the steel plate slab reinforcement structure, the reinforcing plate has a counterbore portion communicating with the bolt insertion hole on a contact surface with the deck plate, and the diameter of the bolt communication hole is that of the stud bolt. It is preferable that the diameter of the counterbore part is smaller than the diameter of the welded part and larger than the diameter of the welded part of the stud bolt.

The steel slab reinforced structure includes a stud bolt connected to a side surface of the rib via a welded portion, and the reinforcing plate is bent in a dogleg shape (L-shape), and the deck A plurality of bolt insertion holes, which are in contact with the lower surface of the plate and the side surface of the rib, and are welded to the side surfaces of the stud bolt and the rib connected to the lower surface of the deck plate via a welded portion. It is preferable that stud bolts connected through the respective parts are inserted.
Alternatively, in the reinforcing structure of the steel slab, the rib has a notch, and a plurality of the stud bolts are interposed on the bottom surface of the deck plate with welds interposed between the notch of the rib. The reinforcing plate is inserted through the notch and is in contact with the lower surface of the deck plate, and the plurality of stud bolts are inserted into the plurality of bolt insertion holes of the reinforcing plate, respectively. It is preferable. In this case, it is more preferable that the reinforcing plate has a branch portion depending from the plate surface, and the branch portion closes the notch portion of the rib.

  In the steel slab reinforcing structure, the stud bolt is preferably a torcia-type bolt whose pin tail is broken when a predetermined axial force is applied.

  Further, the method for reinforcing a steel deck according to the present invention includes a step of welding a stud bolt to at least the bottom surface of the deck plate among the bottom surface of the steel deck plate and the side surface of the steel rib of the existing steel deck. And a step of abutting a steel reinforcing plate having a bolt insertion hole penetrating in the thickness direction against the lower surface of the deck plate while inserting the stud bolt into the bolt insertion hole, and a nut on each stud bolt. And screwing and fixing the reinforcing plate to the lower surface of the deck plate.

When reinforcing the steel slab, it was decided to fix the reinforcing plate applied to the bottom surface of the deck plate with the stud bolt welded to the bottom surface of the deck plate, so that a through hole for inserting the bolt into the deck plate should be formed Is no longer necessary.
For this reason, it is not necessary to peel off the pavement on the top surface of the deck plate when reinforcing the steel floor slab, so that the labor can be saved and the reinforcement work can be performed while the vehicle is passing.
Since no through hole is made in the deck plate, it is possible to prevent the strength of the deck plate itself from being lowered.

(a) is a cross-sectional view of the reinforcing structure of the steel deck according to the first embodiment, (b) is an enlarged cross-sectional view of the crack portion (a) is a cross-sectional view of the reinforcing structure of the steel deck according to the second embodiment, (b) is an enlarged cross-sectional view of the cracked portion An enlarged cross-sectional view of the main part of a steel slab reinforcement structure

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
As shown in FIG. 1, a steel slab reinforcement structure 10 according to the first embodiment includes a deck plate 11 and a U-rib 12 as a vertical rib welded to the lower surface of the deck plate 11. This is a reinforced version of an existing steel slab used as a slab.
As a newly added structure as the reinforcing structure 10, a stud bolt 13 welded to the lower surface of the deck plate 11 and the side surface of the U rib 12, a reinforcing plate 14 applied to the lower surface of the deck plate, and the stud bolt 13 And a nut 15 screwed in.

  In addition to the vertical ribs, the deck plate 11 is provided with a number of horizontal ribs for reinforcement, and is supported from below by a girder such as a main girder. It is the same as the floor slab (not shown). Further, the structure of the vertical rib is not limited to the U rib 12.

Further, the deck plate 11 has a flat top surface paved with asphalt or the like in the installed state of the steel floor slab to form a paved portion 11a, on which a vehicle such as an automobile passes.
In addition, both sides of the pavement portion 11a protrude and become ground cover in order to prevent deviation of the vehicle (not shown).

The deck plate 11 is formed from a steel plate. Although the kind of the steel is not specifically limited, normal steel and fatigue-resistant steel can be illustrated. Although the thickness of the deck plate 11 is not specifically limited, 12 mm-16 mm can be illustrated. The tensile strength and Vickers hardness of the deck plate 11 are not particularly limited, but can be exemplified by 450 to 550 N / mm ² and 130 to 200 Hv.

A large number of U ribs 12 are arranged in parallel in the width direction on the lower surface of the deck plate 11, and extend parallel to the longitudinal direction of the deck plate 11. Although the deck plate 11 is reinforced by the U-rib 12, these structures are the same as those of a conventional steel slab.
The U rib 12 is made of steel, and includes a bottom panel 12a and a side panel 12b rising from both sides of the bottom panel 12a, and a cross section perpendicular to the longitudinal direction has a substantially U-shaped appearance.
The U rib 12 is formed, for example, by bending both sides of the center of the long steel plate in the width direction, and the center of the steel plate becomes the bottom panel 12a and both sides become the side panels 12b.
The U ribs 12 are welded with the front end portions (upper end portions) of the side panels 12b in contact with the lower surface of the deck plate 11 to form rib weld portions 12c.
In the present embodiment, a damaged portion 12d such as a crack is generated in the weld bead of the rib weld portion 12c, and this is reinforced.

As shown in FIGS. 1 and 3, the plurality of stud bolts 13 are formed on the bottom surface of the deck plate 11 and the side surface of the U rib 12 (side panel 12 b) by the bolt welded portion 13 a around the rib welded portion 12 c having the damaged portion 12 d. Welded.
The bolt welded portion 13a is in a so-called welding collar state and is wider than the diameter of the stud bolt. The dimension of the welding collar is determined by the dimension of the ferrule that is put on the welding part during welding work.
Although the welding conditions are not particularly limited, it can be exemplified that the welding current is 1600 to 1800 A and the energization time is 1 to 2 seconds. The welding operation may be performed manually by the work vehicle holding the welding gun upward, or may be performed automatically or semi-automatically using a welding apparatus.

As shown in FIG. 3, as the stud bolt 13, a Torcia-type bolt having a pin tail 13 b that breaks when a predetermined axial force is applied is used. The Torcia bolt can easily manage the axial force by observing whether the pin tail 13b is broken. FIG. 1 shows the stud bolt 13 after the pin tail 13b is broken.
Moreover, as for the strength of the stud bolt 13, it is preferable that the tensile strength is 600 to 1000 N / mm ^{2 because} it is suitable for connecting the deck plate 11 and the reinforcing plate 14 by a friction bonding method.
This is because if the tensile strength is less than 600 N / mm ² , the strength becomes insufficient and the number of stud bolts 13 increases. Further, if the tensile strength exceeds 1000 N / mm ² , the bolt welded portion 13a may be broken earlier than the stud bolt main body, and the performance of the stud bolt 13 cannot be fully exhibited.

The diameter of the stud bolt 13 is not particularly limited, but is preferably a large diameter from the viewpoint of tensile strength and the like, and can be exemplified by 18 to 22 mm.
The dimensions of the bolt welded portion 13a are not particularly limited, but it is necessary to be large enough to prevent the stud bolt 13 from falling off the deck plate 11, and when the diameter of the stud bolt 13 is 22 mm, the outer diameter Is 24 to 27 mm, and the height is 7 to 9 mm.
The Vickers hardness of the stud bolt 13 can be exemplified as 250 to 370 Hv because it has an influence on strength and toughness if it is too hard or too soft from the relationship with the tensile strength.
Since the Vickers hardness and the like of the stud bolt 13 can be adjusted by heat treatment (QT treatment: quenching and tempering treatment), a stud bolt subjected to heat treatment is preferably used.
Although the composition of the stud bolt 13 is not particularly limited, it is possible to exemplify a carbon steel having a carbon equivalent of 0.35 to 0.45% by weight from the relationship with tensile strength, Vickers hardness, and the like. Moreover, it is preferable that 0.0005 to 0.0020 weight% of boron is contained.

As shown in FIG. 1, the reinforcing plate 14 that is bent in the shape of a letter abuts from the lower surface of the deck plate 11 to the side surface (side panel 12 b) of the U rib 12 so as to surround the damaged rib weld 12 c. Has been.
A plurality of bolt insertion holes 14a, which are circular holes penetrating in the thickness direction, are formed in the reinforcing plate 14, and the diameter of the bolt insertion holes 14a is larger than the diameter of the stud bolt 13 and the stud bolt. The diameter is smaller than the diameter of the 13 bolt welded portions 13a.
A stud bolt 13 is inserted through the bolt insertion hole 14a. When the diameter of the stud bolt 13 is 22 mm, the bolt insertion hole 14 a can be exemplified as 23 to 24 mm.

A cylindrical counterbore portion 14b communicating with the bolt insertion hole 14a is formed on the contact surface of the reinforcing plate 14 with the deck plate 11 and the U rib 12.
The diameter and height of the spot facing portion 14b are larger than the outer diameter and height of the bolt welding portion 13a of the stud bolt 13, and the bolt welding portion 13a of the stud bolt 13 is accommodated in the spot facing portion 14b. Yes. For example, when the dimensions of the bolt welded portion 13a of the stud bolt 13 are those exemplified above, the counterbore portion 14b can be exemplified as having a diameter of 27 to 30 mm and a height of 9 to 11 mm.
Thus, by providing the counterbore part 14b in which the bolt welding part 13a is accommodated, the diameter of the bolt insertion hole 14a can be made close to the diameter of the part other than the counterbore part 14b of the stud bolt 13 to reduce the diameter. For this reason, when connecting the deck plate 11 and the reinforcing plate 14 by a friction joining method, it is possible to ensure a desired axial force and frictional force.
The reinforcing plate 14 having a U-shaped cross section is formed by bending a steel plate. Although the kind of the steel is not specifically limited, normal steel and fatigue-resistant steel can be illustrated. The thickness of the reinforcing plate 14 is not particularly limited, but can be the same as that of the deck plate 11.

As shown in FIGS. 1 and 3, the nut 15 is screwed into the stud bolt 13 from below the reinforcing plate 14 using a so-called shear wrench, and the reinforcing plate 14 is pressed against the deck plate 11 via the washer 15a. It is fixed.
When a predetermined axial force is applied to the stud bolt 13 when the nut 15 is tightened, the pin tail 13b is broken to manage the axial force.

FIG. 2 shows a reinforcing structure 10 for a steel slab according to the second embodiment. In this embodiment, a crack generated in the rib welded portion 12c propagates to the inside of the deck plate 11, and a damaged portion 11b. Is configured.
Hereinafter, detailed description of the same configuration as the first embodiment will be omitted.
At the time of reinforcement, a U-shaped part is cut out from the side panel 12b to the bottom panel 12a of the U rib 12 located immediately below the damaged part 11b to form a notch.

As shown in the figure, the reinforcing plate 14 is formed by connecting the branching portions 14c that hang obliquely from the plate surface of the flat reinforcing plate main body by welding or the like.
A stud bolt 13 is also welded in the vicinity of the lower end of the branching portion 14 c of the reinforcing plate 14.
Stud bolts welded to the bottom surface of the deck plate 11 with the reinforcing plate body abutting against the bottom surface of the deck plate 11 and the branching portion 14c positioned so as to form the same plane as the side panel 12b of the U rib 12 A nut 15 is screwed into 13. Thereby, the reinforcing plate 14 is fixed to the deck plate 11.

A U-shaped piece 16 is fitted into a part of the notch portion of the U rib 12. The cutout portion of the U rib 12 is almost completely closed by the branch portion 14 c of the reinforcing plate 14 and the U-shaped piece 16. Since the internal space of the U rib 12 is closed by the U-shaped piece 16 in this way, the operation of fixing the reinforcing plate body to the deck plate 11 in the internal space of the U-rib 12 is performed using the U-shaped piece 16. It is necessary to do it before the installation work.
The U-shaped piece 16 has a bottom portion 16a and a side portion 16b rising from both sides of the bottom portion 16a and has a U-shaped cross section as a whole.
A stud bolt 13 is also welded in the vicinity of the upper ends of both side portions 16 b of the U-shaped piece 16.

An attachment plate 17 is stretched over the stud bolt 13 on one side portion 16b of the U-shaped piece 16 and the stud bolt 13 on the side panel 12b of the U rib 12, and a nut 15 is screwed. Thereby, the U-shaped piece 16 is fixed to the U-rib 12.
Further, an attachment plate 17 is bridged between the stud bolt 13 on the other side portion 16b of the U-shaped piece 16 and the stud bolt 13 on the branch portion 14c of the reinforcing plate 14, and a nut 15 is screwed. Thereby, the U-shaped piece 16 is fixed to the reinforcing plate 14. As a result, the U-shaped piece 16 is integrated with the branch portion 14 c of the reinforcing plate 14.

  It should be considered that the embodiments disclosed herein are illustrative and non-restrictive in every respect. The scope of the present invention is defined by the terms of the claims, and is intended to include any modifications and variations within the scope and meaning equivalent to the terms of the claims.

In the embodiment, the shape of the spot facing portion 14b is a cylindrical shape, but the shape is not limited to this as long as the bolt welded portion 13a can be accommodated, and may be a hemispherical shape, an elliptical column shape, or the like. The counterbore 14b can also be omitted.
Moreover, what is not a Torcia type | mold can also be used for the stud bolt 13. FIG.

The vertical rib is not limited to the U-rib 12 of the embodiment, and may be, for example, a rib having an I-shaped cross section, and the reinforcing plate 14 correspondingly does not form a notch in the rib. Those that bend in an L-shape and those that branch into a T-shape can be used when a notch is formed in the rib.
Further, in the present embodiment, only the case where damage occurs from the welded portion between the vertical rib and the deck plate 11 is illustrated, but also when the welded portion between the horizontal rib and the deck plate 11 is damaged, the reinforcement of the present invention. Of course, the structure can be applied.

DESCRIPTION OF SYMBOLS 10 Reinforcement structure 11 of steel floor slab Deck plate 11a Pavement part 11b Damaged part 12 U rib 12a Bottom panel 12b Side panel 12c Rib welded part 12d Damaged part 13 Stud bolt 13a Bolt welded part 13b Pin tail 14 Reinforcement plate 14a Bolt insertion hole 14b Counterbore part 14c Branching part 15 Nut 15a Washer 16 U-shaped piece 16a Bottom part 16b Side part 17 Attached plate

Claims (4)

A steel deck plate,
A steel rib disposed below the deck plate;
A stud bolt connected to at least the lower surface of the deck plate among the lower surface of the deck plate and the side surface of the rib via a welded portion;
A steel reinforcing plate having a bolt insertion hole penetrating in the thickness direction, the stud bolt being inserted into the bolt insertion hole, and an upper surface of which is in contact with the lower surface of the deck plate;
A nut screwed into the stud bolt and fixing the reinforcing plate to the lower surface of the deck plate,
The rib has a notch,
A plurality of the stud bolts are connected to the lower surface of the deck plate via a welded portion with a notch portion of the rib interposed therebetween,
The reinforcing plate is in contact with the lower surface of the deck plate through the notch,
A steel floor slab reinforcement structure in which the plurality of stud bolts are respectively inserted into a plurality of bolt insertion holes of the reinforcing plate . The reinforcing plate has a counterbore portion communicating with the bolt insertion hole on a contact surface with the deck plate,
The diameter of the bolt insertion hole is smaller than the diameter of the welded portion of the stud bolt,
The steel floor slab reinforcement structure according to claim 1, wherein a diameter of the spot facing portion is larger than a diameter of a welded portion of the stud bolt. The steel plate slab reinforcement structure according to claim 1 or 2, wherein the reinforcing plate has a branching portion that hangs down from the plate surface, and the branching portion closes a notch of the rib. 4. The steel deck reinforced structure according to claim 1 , wherein the stud bolt is a torcia-type bolt whose pin tail is broken when a predetermined axial force is applied. 5.

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