1. Field of the Invention
The present invention is related to a design of a girder for a bridge or for use in construction, and more particularly, to a method for designing and fabricating a multi-step tension prestressed girder to increase a load bearing force of a bridge, when necessary, by adjusting tension step by step during construction.
2. Description of the Related Art
When loss of tension occurs by lapse of time in the stress distribution state of line 2, prestress is reduced so that the distribution of stress moves to a line 3. That is, tensile stress decreases by Δσ1 in the upper margin and compresion stress decreases by Δσ2 in the lower margin.
Here, when the additional dead load moment Md2 and the live load M1 are introduced, the distribution of stress becomes as shown by a line 4 of
Required profile coefficients Z1 and Z2 with respect to the upper margin and the lower margin of the profile of a girder having the above stress distribution should satisfy the following Equations 1 and 2.
In
All problems generated in a bridge can be solved by adjusting the tension of the girder used therefor. Thus, the present invention provides a solution which is simple and inexpensive.
To solve the above problems, it is an object of the present invention to provide a method for designing and fabricating a multi-step tension prestressed girder for a bridge in which, considering that loads are applied step by step during construction of a bridge, tension is introduced step by step to a prestressed concrete girder according to an increase of the load.
In the present invention, by adopting the multi-step tension type design method, designing a bridge with a small profile having a span much longer than that according to conventional technology is possible.
To achieve the above object, a girder having a built-in steel wire which can be adjusted according to the present invention includes at least one steel wire installed in a lower flange of the girder in a lengthwise direction. Thus, by increasing the tension in the steel wire, a load bearing force of the girder can be improved.
According to one aspect of the present invention, there is provided a method for designing a multi-step tension prestressed girder, in which prestress is appropriately introduced with respect to a relationship between a load and stress for each step of construction, so that the height of a profile of the girder can be reduced.
According to another aspect of the present invention, there is provided a method for fabricating a multi-step tension prestressed girder, wherein prestress is appropriately introduced with respect to a relationship between a load and stress for each step of construction, so that the height of a profile of the girder can be reduced.
It is preferable in the present invention that the construction steps are divided into those of a non-synthesis profile and those of a synthesis profile according to whether or not the girder is to be synthesized with a bottom concrete plate.
Also, it is preferable in the present invention that primary tension is applied at the initial stage in which a girder mold is solidified and a secondary tension is applied after the bottom concrete plate is installed.
The present invention can be applied to various types of girders regardless of whether the shape of the profile of the girder is that of an I-type girder or a bulb T-type girder or some other shapes. Since a slab is considered to be a girder of a rectangular profile having a unit width, the following preferred embodiment of the present invention will be described with respect to an I-type girder.
The above objective(s) and advantages of the present invention will become more apparent by describing in detail a preferred embodiment thereof with reference to the attached drawings in which:
Referring to
A girder 21 of the present invention, as shown in
Also, one steel wire 23 of the steel wires 22 and 23 is preferably installed inside the lower flange 25 in a lengthwise direction to be symmetric with respect to the center of the profile. In view of the profile of the girder 21, the upper flange 24 is installed horizontally at the upper portion of the body 26 and an upper plate of a bridge is installed on the upper flange 24. In view of the profile of the girder 21, the lower flange 25 is installed horizontally at the lower margin of the body 26 and the bottom surface thereof is supported by piers.
The steel wires 22 and 23 distributed mainly at the lower end of the girder 21, as shown in
When additional steel wires are arranged outside the girder 21, appropriate anchoring devices should be installed at both end portions of the girder so that these steel wires can be anchored at both end portions of the girder. Since a latitudinal beam installed at both end portions of the existing girder is not designed to bear tension generated by a tension member, an additional anchoring device 27 is installed or the latitudinal beam at both end portions of the girder is appropriately reinforced to bear the tension.
In the girder 21 according to the present invention, when a crack or excess sag is generated due to a long-term load, the steel wire 22 installed inside or outside the girder 21 is additionally tightened for reinforcement of the girder 21. Here, the additional tightening of the steel wire 22 is performed by using a hydraulic jack.
The design method of the present invention will be described according to a multi-step tension member introduction principle.
As long as a conventional method is used to design a long-span bridge with PSC I-type girders, there is a limit in a profile coefficient regardless of the stress withstanding efficiency of the profile. As a countermeasure for overcoming disadvantages in the conventional design method for the PSC I-type girder, a method of introducing prestress according to each step of construction is suggested. In the steps of construction, a non-synthesis profile and a synthesis profile are separately applied according to whether the bottom concrete plate and the girder are synthesized or not.
Non-Synthesis Step
When prestress by a post-tension method is appropriately introduced according to the state of stress for each construction step, a design span can be increased while maintaining the same profile height. Also, while maintaining the same span, the height can be reduced more than when designing a member by the conventional design method.
Here, Pi1 is a primary tension, Ag is an area of the profile of the girder, e1 is an eccentric distance of the primary tension, that is, the distance from the geometric center of the primary tension, Md1 is a bending moment due to the self-weight, and Zgt and Zgb are coefficients of the profile of the girder with respect to the upper margin and the lower margin.
The stress calculated by Equations 3 should be a value between an allowed tensile stress σti and an allowed compression stress σci of concrete shortly after tension is introduced. Here, when the eccentric distance of a tension member is adjusted by appropriately lowering the height of the profile, generation of tensile stress in the upper margin of the girder can be avoided. That is, the girder can be designed such that the compression stress can act on the entire profile.
A line 2 indicates the distribution of stress in the profile shortly after a bottom concrete plate is installed. Since the eccentric distance and centroid distance, which is the distance from the center of mass, are shortened if the height of the profile is lowered, unlike
Shortly after the installation, the bottom concrete plate does not perform a structural function but acts as a load. As a result, the stress in this step is a value which is obtained by adding the bending stress due to the inactive moment Md2 of the bottom concrete plate to σg2 obtained from Equations 3. Thus, the stress σg2 of the profile shortly after the installation of the bottom plate can be calculated by the following Equations 4.
As indicated by the line 2, in the improved design method, the installation of the bottom plate only makes the stress in the lower margin of the girder approach the allowed tensile stress of the concrete and the upper stress approach the allowed compression stress of the concrete. At this stage, since the girder cannot bear the load any more, additional tension is introduced to decrease the tensile stress in the lower margin of the girder and the upper compression stress in the girder. Here, the stress σg3 in the profile synthesized with prestress by the secondary tension is obtained by the following Equations 5.
Here, Pi2 is additional secondary tension, and e2 is the eccentric distance of the secondary tension.
A line 3 indicates the distribution of stress in the profile calculated by Equations 5. Since the upper and lower margins of the girder can secure allowance with respect to the allowed stress by the prestress due to the secondary tension, the bending stress due to the dead load and live load of the bridge surface can be endured.
Synthesis Step
Given that an effective rate of tension with respect to the total long-term loss is R, the remaining amount of tension introduced twice will be (1+R)(Pi1+Pi2)/2. Here, it is assumed that there is no time difference between loss of the primary tension and the secondary tension. Thus, the stress in the girder is distributed as indicated by a line 4 of
The stress state of the upper and lower margins of the girder indicated by the line 4 can be obtained by the following Equations 6.
Here, egp is the eccentric distance with respect to the distribution of all tension members.
Also, the stress in the bottom concrete plate changes slightly due to the reduction of the tension. The stress σs4 in the upper margin of the bottom concrete plate can be obtained by the following Equation 7.
Here, eep is the eccentric distance of the tension member with respect to the synthesis profile and Zst is the coefficient of the profile with respect to the upper margin of the bottom plate at the synthesis profile.
In the step of the line 4, when the bending stress generated by the bending moment Md3 due to the dead load of the bridge surface such as pavement, curbstones and guide fences, is synthesized, the distribution of stress in the synthesis profile is the same as a line 5 indicates. Here, the stress in the upper and lower margins of the girder can be calculated as shown in the following Equations 8.
Here, Zct is a coefficient of the upper margin of the synthesis profile and Zcb is a coefficient of the lower margin of the synthesis profile.
Also, the stress in the upper margin of the bottom plate is shown in the following Equation 9.
When it is assumed that the loss of tension by lapse of time has been completed just before the live load is applied, after the installation of a bridge has been completed, the compression stress in the lower margin of the girder is slightly reduced due to the final loss of the tension and the compression stress of the upper margin of the girder slightly increases. The distribution of stress at this stage is shown by a line 6 of
Also, the stress in the upper margin of the bottom plate is shown in the following Equation 11.
In a step in which the overall design live load including an impact is applied, as indicated by a line 7, a sufficient prestress has been introduced. Accordingly, even if an overload is applied, the member is not tensilely destroyed. That is, there are an over tension beam and a less tension beam according to whether the tensile stress of the power portion of the girder remains at a compression side or tensile stress is generated. The above case can be said to be a less tension beam. The stress in the upper and lower margins of the girder is obtained by the following Equations 12.
Here, M(I+i) is a design live load moment including an impact.
Also, the stress in the upper margin of the bottom concrete plate is shown in the following Equations 13.
As a result, as long as an excess load is not applied, in a step of using a bridge, the stress in the profile of the middle portion of the member exists between line 6 and line 7.
To summarize the above-described improved design method, primary tension is introduced to the girder having a low frame height. Since prestress by the primary tension supports only the bending moment due to the self-weight of the girder and the bottom plate, the cross-sectional area and height of the member are reduced, compared to the conventional design, so that dead load can be remarkably reduced. Secondary tension applied shortly after the installation of the bottom plate contributes to the introduction of prestress which enables the girder to withstand the dead load of the bridge surface and the live load moment. Consequently, it is a basic principle of the improved design method according to the present invention that prestress is introduced by an appropriate amount with respect to the load-stress relationship in each construction step, without introducing the prestress all at a time, so that the height of the profile can be reduced.
In general, as the span of girders of a bridge is lengthened, the portion of the bending moment due to the dead load becomes greater than the portion of the bending moment due to the live load in the overall design load. In the conventional design method in which prestress is introduced one time only, the ratio of the dead load moment to the live load moment for a span of 30 m or less is about 2–2.5. For a span of 50 m, the ratio increases to 3.5–4.0. This is because, as the span increases, the required eccentric distance capable of resisting a greater bending moment sharply increases so that the size of the profile increases. In the improved design method, while reducing the size of the profile of the member and the height of the member, such disadvantages of the conventional design method are compensated for.
The present invention may be used for a method of designing and fabricating a girder in a bridge. In particular, the present invention may be used for designing and fabricating a multi-step tension prestressed girder so that, as the span of a girder increases, a phenomenon that the portion of the bending moment due to the dead load is greater than that of the bending moment due to the live load in the overall design load is reduced.
Number | Date | Country | Kind |
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1999/43513 | Oct 1999 | KR | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/KR00/01117 | 10/7/2000 | WO | 00 | 4/5/2002 |
Publishing Document | Publishing Date | Country | Kind |
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WO01/27406 | 4/19/2001 | WO | A |
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