1. Field
The present invention relates to a stiffener for connecting a prestressed concrete beam and a method of constructing a structure using the same, and more particularly, to a stiffener for connecting a prestressed concrete beam and a method of constructing a structure using the same, capable of facilitating connection of a beam such as a prestressed concrete beam which is covered with concrete with a steel frame or another structure (e.g. a column, a beam, or a target structure) which is covered with concrete, smoothly transmitting a stress, and securing connection constructability and structural safety with respect to the target structure.
2. Description of the Related Art
Particularly,
Since both the column structure 10 and the prestressed concrete beam 20 are covered with concrete, there are many difficulties in the connection thereof without separate connecting means.
As such, one lateral face of the column structure 10 made of reinforced concrete in the related art is cut out to form a cavity S, and a bottom face of one end of the prestressed concrete beam 20 is placed on a bottom face of the cut cavity S. Thereby, both are connected to each other.
However, because the cut cavity S should be separately formed in the lateral face of the column structure 10, this connecting method is accompanied with much inconvenience in that this should be taken into consideration when the column structure is made.
Since the prestressed concrete beam 20 is placed in the cut cavity S, a stress transmitted from the beam due to a dead load of the beam is concentrated on the column structure. For this reason, there is a possibility of cracks being generated from the concrete around the cavity, and thus it is necessary to separately reinforce the cavity.
Further, it is impossible to sufficiently secure connectability of the column structure 10 and the prestressed concrete beam 20, and thus structural safety is not guaranteed.
In order to solve the problems, the present invention is directed to a stiffener for connecting a prestressed concrete beam and a method of constructing a structure using the same, capable of providing efficient stress transmission and promoting constructability of the connection with another structure.
According to an exemplary aspect, there is provided a stiffener for connecting a prestressed concrete beam, which includes: a buried stiffener that is installed on an end face of the prestressed concrete beam covered with concrete so as to protrude inwards from the end face of the prestressed concrete beam to transmit a stress transmitted from the prestressed concrete beam; an end face stiffener that is connected to a front face of the buried stiffener and is installed so as to be in contact with the end face of the prestressed concrete beam; and a joint stiffener that protrudes from a front face of the end face stiffener in a lengthwise direction of the prestressed concrete beam, thereby allowing the prestressed concrete beam to be connected to a target structure in a simple manner
Thus, the stiffener of the present invention allows a stress caused by weight to be more smoothly transmitted by the buried stiffener, and facilitates connection to the target structure due to the end face stiffener connected with the joint stiffener.
The end face stiffener may be formed on top, bottom, and opposite lateral faces of the prestressed concrete beam, so that the stiffener of the present invention allows a stress acting on an end of the prestressed concrete beam to be more effectively transmitted to the target structure and is allowed to be reinforced along with the end of the prestressed concrete beam.
A connecting member may be installed on the target structure so as to be able to be connected with the prestressed concrete beam connecting stiffener of the present invention, wherein the connecting member makes it easy to secure constructability and connectability, for instance, by mechanical fastening such as bolt and nut fastening to the joint stiffener having bolt holes.
A building structure may be constructed using the aforementioned prestressed concrete beam connecting stiffener. Thereby, the building structure can be more rapidly constructed.
The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this specification, illustrate exemplary embodiments of the invention, and together with the description serve to explain the aspects of the invention.
a, 2b, 2c, 2d and 2e illustrate embodiments of a prestressed concrete beam connecting stiffener of the present invention; and
The invention is described more fully hereinafter with reference to the accompanying drawings, in which exemplary embodiments of the invention are shown. This invention may, however, be embodied in many different forms and should not be construed as limited to the exemplary embodiments set forth herein. Rather, these exemplary embodiments are provided so that this disclosure is thorough, and will fully convey the scope of the invention to those skilled in the art.
a, 2b, 2c, 2d and 2e illustrate embodiments (first to fifth embodiments) of the present invention in connection with a stiffener 100 for connecting a prestressed concrete beam.
First Embodiment
Referring to
The buried stiffener 110 extends from approximately a middle of one end face of a prestressed concrete beam (including a precast reinforced concrete beam) 200 so as to be buried in the prestressed concrete beam 200. That is, the buried stiffener 110 is installed so as to be buried in the prestressed concrete beam 200.
Typically, the buried stiffener 110 may be made of a steel plate, and has a quadrilateral shape as in
Furthermore, a buried depth of the buried stiffener 110 may be decided in consideration of a cross-sectional size, etc. of the prestressed concrete beam 200.
Further, the buried stiffener 110 may be additionally provided with studs 111, shear connectors, on opposite sides thereof. The studs 111 are buried in the prestressed concrete beam 200, so that the prestressed concrete beam connecting stiffener 100 of the present invention is also able to be effectively merged (integrated) into the prestressed concrete beam 200.
This buried stiffener 110 functions to distribute and transmit stress, which is generated by load acting on the prestressed concrete beam 200, to the end face stiffener 120 and the joint stiffener 130, both of which will be described below.
Further, the buried stiffener 110 is buried in the end of the prestressed concrete beam 200, and also serves to reinforce the end of the prestressed concrete beam 200.
The end face stiffener 120 is connected to a front face of the buried stiffener 110 so as to be in contact with one end face of the prestressed concrete beam 200.
In detail, the end face stiffener 120 is installed to cover one end face of the prestressed concrete beam 200 and to be integrally connected with the front face of the buried stiffener 110 in approximately a middle of the rear face thereof
This end face stiffener 120 may also be made of a steel plate, and has a quadrilateral shape as in
The end face stiffener 120 functions to receive the stress transmitted from the buried stiffener 110 and to transmit it to a target structure 300 via the joint stiffener 130 that will be described below.
Further, the end face stiffener 120 serves as an anchorage plate such that tendons 210 such as prestressing (PS) strands disposed in the prestressed concrete beam 200 as in
The end face stiffener 120 is also additionally provided with studs 111, shear connectors, on the rear face thereof. The studs 111 are buried in the prestressed concrete beam 200, so that the prestressed concrete beam connecting stiffener 100 of the present invention is also able to be effectively merged (integrated) into the prestressed concrete beam 200.
The joint stiffener 130 protrudes from the front face of the end face stiffener 120 so as to be symmetrical with the buried stiffener 110, which is connected to the rear face of the end face stiffener 120, about the end face stiffener 120.
The joint stiffener 130 may also be made of a steel plate, and has a quadrilateral shape as in
This joint stiffener 130 is provided with a plurality of bolt holes, which are used for fasteners made up of bolts and nuts. The bolt holes are preferably formed in an elliptical slot shape so as to be able to adjust a fastening position of each fastener.
Further, the joint stiffener 130 basically functions to receive the stress transmitted from the buried stiffener 110 and the end face stiffener 120 and to transmit it to the target structure 300.
In addition, the joint stiffener 130 serves as a member for directly connecting the prestressed concrete beam 200 with a connecting member 400 of the target structure 300.
The prestressed concrete beam connecting stiffener 100 made up of the buried stiffener 110, the end face stiffener 120, and the joint stiffener 130 discussed above is prefabricated so as to be set to the end face of the prestressed concrete beam 200, so that it can be installed along with the prestressed concrete beam 200 when the prestressed concrete beam 200 is fabricated by arranging reinforcements and pouring and curing concrete.
Accordingly, it can be found that the prestressed concrete beam connecting stiffener 100 is previously mounted on one or opposite end faces of the prestressed concrete beam 200.
Second Embodiment
The prestressed concrete beam connecting stiffener 100 of the present invention as illustrated in
The bottom face stiffener 121 is installed on a lower end of the end face stiffener 120 such that its lower face formed on the same plane as a lower face (bottom face) of the prestressed concrete beam 200 is exposed, and may also be made of a steel plate.
The bottom face stiffener 121 may be integrally fabricated with the end face stiffener 120 when the end face stiffener 120 is fabricated.
The bottom face stiffener 121 functions to more effectively transmit the stress, which is transmitted from the prestressed concrete beam 200, to the target structure along with the end face stiffener 120, and to support a bottom face of the end of the prestressed concrete beam 200.
Thus, it can be found that the bottom face stiffener 121 is very effective for reinforcement of the end of the prestressed concrete beam 200.
The bottom face stiffener 121 is also additionally provided with studs 111, shear connectors, on a top face thereof. The studs 111 are buried in the prestressed concrete beam 200, so that the prestressed concrete beam connecting stiffener 100 of the present invention is also able to be effectively merged (integrated) into the prestressed concrete beam 200.
Third Embodiment
The prestressed concrete beam connecting stiffener 100 of the present invention as illustrated in
The top face stiffener 122 is installed on an upper end of the end face stiffener 120 such that its top face formed on the same plane as a top face of the prestressed concrete beam 200 is exposed, and may also be made of a steel plate.
The top face stiffener 122 may be integrally fabricated with the end face stiffener 120 along with the bottom face stiffener 121 when the end face stiffener 120 is fabricated.
The top face stiffener 122 more effectively transmits the stress, which is transmitted from the prestressed concrete beam 200, to the target structure along with the end face stiffener 120 and the bottom face stiffener 121, and encloses the end of the prestressed concrete beam 200 along with the bottom face stiffener 121.
Thus, it can be found that the top face stiffener 122 is still more effective for reinforcement of the end of the prestressed concrete beam 200 due to an effect of restricting the end of the prestressed concrete beam 200.
The top face stiffener 122 is also additionally provided with studs 111, shear connectors, on a bottom face thereof. The studs 111 are buried in the prestressed concrete beam 200, so that the prestressed concrete beam connecting stiffener 100 of the present invention is also able to be effectively merged (integrated) into the prestressed concrete beam 200.
Fourth Embodiment
The prestressed concrete beam connecting stiffener 100 of the present invention as illustrated in
The lateral face stiffeners 123 and 124 are installed on opposite sides of the end face stiffener 120 such that their lateral faces formed on the same plane as opposite lateral faces of the prestressed concrete beam 200 are exposed, and may also be made of a steel plate.
The lateral face stiffeners 123 and 124 may be integrally fabricated with the end face stiffener 120 when the end face stiffener 120 is fabricated.
The lateral face stiffeners 123 and 124 function to more effectively transmit the stress, which is transmitted from the prestressed concrete beam 200, to the target structure along with the end face stiffener 120, and to support opposite lateral faces of the end of the prestressed concrete beam 200.
Thus, it can be found that the lateral face stiffeners 123 and 124 are effective for reinforcement of the end of the prestressed concrete beam 200.
Each of the lateral face stiffeners 123 and 124 is also additionally provided with studs 111, shear connectors, on an inner lateral face thereof. The studs 111 are buried in the prestressed concrete beam 200, so that the prestressed concrete beam connecting stiffener 100 of the present invention is also able to be effectively merged (integrated) into the prestressed concrete beam 200.
Furthermore, the embodiment of
In other words, the prestressed concrete beam connecting stiffener 100 of the present invention may be configured so that the lateral face stiffeners 123 and 124 are installed on the bottom face stiffener 121 and/or the top face stiffener 122, and that the lateral face stiffeners 123 and 124 are installed on both or one of the lateral faces of the end of the prestressed concrete beam 200.
Fifth Embodiment
The prestressed concrete beam connecting stiffener 100 of the present invention as is illustrated in
In detail, the angled stiffeners 125 and 126 function as a hook, and extend from respective ends of the lateral face stiffeners 123 and 124 into the prestressed concrete beam 200, so that they serve to complement attachability, particularly, when the lateral face stiffeners 123 and 124 are installed independently.
The angled stiffeners 125 and 126 are made of a steel plate, and may be integrally formed with the lateral face stiffeners.
Furthermore, the angled stiffeners 125 and 126 may be installed on the top and bottom face stiffeners 121 and 122.
Method of Constructing the Prestressed Concrete Beam Connecting Stiffener 100 According to the Target Structure 300
Furthermore, the prestressed concrete beam connecting stiffener 100 according to the second to fifth embodiments may be used. However, the following description will be made on the basis of the first embodiment.
First, a steel column is installed as a column structure, and then a connecting member 400 is installed on a flange of the steel column.
The connecting member 400 is fabricated in a shape similar to the joint stiffener 130 of the prestressed concrete beam connecting stiffener 100 according to the first embodiment.
That is, the connecting member 400 uses a steel plate in which bolt holes 410 are formed as elliptical slots.
The connecting member 400 and the joint stiffener 130 are mechanically fastened to each other by overlapping with each other, inserting bolts into the communicating bolt holes 131 and 410, and securing the bolts using nuts (fasteners). Thereby, it can be found that both are easily connected.
Since the bolt holes are elliptical slots, the connecting member 400 and the joint stiffener 130 are able to undergo positional adjustment when connected, so that constructability can be prevented from being degraded by an error in installation.
Furthermore, the joint stiffener 130 may be mechanically fastened to the connecting member 400 using only some of the bolt holes, and then both may be connected by welding.
Both of the joint stiffener 130 and the connecting member 400 may be connected by welding without using the bolt holes. This ultimately need only be understood as the purpose of eliminating the mismatch between the bolt hole and the fastener caused by an error in construction.
However, the following description will be merely made on the basis of the mechanical fastening using the bolt holes.
Further, in the case of the steel column 310, a steel stiffener may be additionally installed between the flanges of the steel column 310 that is a place where the connecting member 400 is installed in order to support the stress of the connecting member 400 transmitted from the joint stiffener 130.
In the case of the SRC column structure 130 covered with the concrete, the steel stiffener, the connecting member 400, and the joint stiffener 130 fastened to the connecting member 400 may be previously installed on the steel column 310, and then the joint stiffener 130 may be welded to the end face stiffener 120 of the present invention.
Next, the prestressed concrete beam 200 having the prestressed concrete beam connecting stiffener 100 of the present invention is installed on the target structure 300. In this state, a floor slab for constructing a building is formed. Thereby, the construction of the building can be finally completed.
The prestressed concrete beam connecting stiffener 100 according to the second to fifth io embodiments may also be used. However, the following description will be made on the basis of the first embodiment.
First, a ring type stiffener 500 such as a steel ring, which is installed so as to surround a place where the prestressed concrete beam 200 is to be connected, is set for the RC column structure or the PC column structure 330, and the connecting member 400 is installed on the ring type stiffener 500 as in
The connecting member 400 and the joint stiffener 130 of the present invention are mechanically fastened to each other by overlapping with each other, inserting bolts into the communicating bolt holes 131 and 410, and securing the bolts using nuts.
First,
Furthermore, the prestressed concrete beam connecting stiffener 100 according to the second to fifth embodiments may also be used. However, the following description will be made on the basis of the first embodiment.
First, circumference reinforcing plates 710 are installed on lateral and bottom faces of the PC or RC girder 610 so as to surround a place where the prestressed concrete beam 200 is to be connected, and a vertical reinforcing plate 720 is installed between the circumference reinforcing plates across the PC or RC girder 610. Thereby, the stress transmitted from the prestressed concrete beam 200 is effectively supported.
Next, the connecting member 400 is installed on the circumference reinforcing plate such that the joint stiffener 130 of the prestressed concrete beam 200 can also be connected to the connecting member 400 by bolts and nuts.
That is, the embodiment of
The connecting member 400 is installed on the circumference reinforcing plate 710 such that the joint stiffener 130 of the prestressed concrete beam 200 can also be connected to the connecting member 400 by bolts and nuts.
Here, circumference reinforcing plates 710 are installed on lateral faces of the PC or RC girder 610 so as to surround a place where the prestressed concrete beam 200 is to be connected, but no circumference reinforcing plate 710 is installed on a bottom face of the PC or RC girder 610. Further, a vertical reinforcing plate 720 is installed between the circumference reinforcing plates across the PC or RC girder 610. Thereby, the stress transmitted from the prestressed concrete beam 200 is effectively supported.
The connecting member 400 is installed on the circumference reinforcing plate 710 such that the joint stiffener 130 of the prestressed concrete beam 200 can also be connected to the is connecting member 400 by bolts and nuts.
Here, circumference reinforcing plates 710 are installed on lateral faces of the PC or RC girder 610 so as to surround a place where the prestressed concrete beam 200 is to be connected, but no circumference reinforcing plate 710 is installed on a bottom face of the PC or RC girder 610. Further, a vertical reinforcing plate 720 is installed between the circumference reinforcing plates across the PC or RC girder 610 at a different height.
The connecting member 400 is installed on the circumference reinforcing plate 710 such that the joint stiffener 130 of the prestressed concrete beam 200 can also be connected to the connecting member 400 by bolts and nuts.
Here, the steel girder 620 is provided with a vertical plate 810 on one side of a web thereof and a joint vertical plate 820 as a connecting member in which elliptical slots 821 are formed and which is formed at a place where it is connected with the prestressed concrete beam 200.
The joint stiffener 130 of the prestressed concrete beam 200 is also connected to the joint vertical plate 820 by bolts and nuts.
In the present invention, the circumference reinforcing plate 710, the vertical reinforcing plate 720, the vertical plate 810, and the joint vertical plate 820 are commonly called connecting members 710, 720, 810, and 820. It can be found that the circumference reinforcing plate 710, the vertical reinforcing plate 720, the vertical plate 810, and the joint vertical plate 820 are formed on a surface (circumferential surface) or in the interior of the girder or the column structure.
Accordingly, in the present invention, the target structure is generally divided into the column structure and the girder. However, the target structure includes a structure on which another connector, which is not described in the present invention, is mounted.
According to the present invention, a conventional prestressed concrete beam can be more easily connected to a target structure. A structure can be safely constructed by smooth transmission of an applied load. It is possible to promote connectability as well as reinforce an end of the prestressed concrete beam, so that very effective prestressed concrete beam connecting work and structure construction using the same are made possible.
The embodiments of the invention described above and illustrated in the drawings should not be interpreted as limiting for the technical spirit of the invention. It will be understood by those skilled in the art that the scope of the present invention should be limited by the following claims only, and various changes and modifications can be made within the technical spirit of the present invention. Accordingly, the changes and modifications fall within the scope of the present invention as long as they are apparent to those skilled in the art.
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WO2009/142416 | 11/26/2009 | WO | A |
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