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| Author | : Jessica Bechara |
| Publisher | : |
| Total Pages | : 42 |
| Release | : 2016 |
| Genre | : Dissertations, Academic |
| ISBN | : |
| Author | : Nawal Fares |
| Publisher | : |
| Total Pages | : 82 |
| Release | : 2014 |
| Genre | : Dissertations, Academic |
| ISBN | : |
| Author | : R. Narayanan |
| Publisher | : CRC Press |
| Total Pages | : 274 |
| Release | : 1983-12-01 |
| Genre | : Architecture |
| ISBN | : 0853342180 |
This book discusses various aspects of the design of a plate girder and focuses on the associated stability problems in shear. It deals with stability problems in compression, such as those met in box girder flanges and ship hulls, and is helpful for structural designers and post-graduate students.
| Author | : Agnieszka Bedynek |
| Publisher | : |
| Total Pages | : 112 |
| Release | : 2014 |
| Genre | : |
| ISBN | : |
Tapered plate girders often form part of large-scale structures such as long continuous bridges or industrial buildings where due to considerable loads the higher resistance is required. There are several important reasons choosing non-prismatic girders. First of all, their tapered shape with gradually changing inertia allows for more effective stress distribution inside the web-panel and contributes to steel reduction and thereby to decrease the overall cost of the structure. Trapezoidal shape of such panels also may be desirable in structures with non-standard shape for example where pre-formed service openings are needed. Although rectangular plate girders were studied in many occasions in last few decades, the latest investigations have shown that the structural behaviour of tapered panels is more complex and different distribution of the internal forces takes place. Due to a lack of design rules for assessment of ultimate shear resistance of tapered plate structures with considerable angle of a slope (> 10 degrees), this research is focused on searching for a solution of the problem. The main body of the thesis is composed of four independent publications where each of them summarizes different phase of the research. The most relevant issues related to tapered panels discussed in the papers were: the critical shear load in tapered simple-supported plates, the influence of geometrical and structural imperfections, the optimal position of the longitudinal stiffener, the Resal effect, and finally the ultimate shear resistance of stiffened and unstiffened tapered plate girders. Nevertheless, the main objective of this work was the development of a reliable design tool to assess of the ultimate shear resistance of non-prismatic plate girders. The methodology applied in the research consists of the following stages: study of the bibliography and initial theoretical research, development of a numerical model, execution of two experimental programs, development of a wide parametric study, analysis of the experimental and numerical results, comparing them with those obtained according to EN 1993-1-5, and finally - development of a new design proposal for the assessment of the ultimate shear resistance for tapered steel plate girders. The PhD research was supported by two experimental programs focused on the structural behaviour of tapered plate girders. In the first program, transversally stiffened members subjected to shear and shear-bending interaction were tested. The second experimental program was focused on longitudinally stiffened tapered plate girders under shear. Results obtained from the experimental tests were used for the verification of the numerical model. Plate girders reveal tendency to possess a significant post-buckling resistance. This phenomenon can be observed as a diagonal tension field developing within the web-panel. In both experimental tests and numerical analyses, this characteristic behaviour was observed. Using verified the numerical model, a wide parametric study for a large number of tapered plate girders was carried out. All numerical results presented in this research were compared with those obtained according to EN 1993-1-5 and discussed. Finally, a new design method for the assessment of the ultimate shear resistance of tapered steel plate girders was presented. The new design proposal is based on the currently valid - Rotated Stress Field Method. The procedure maintains its simplicity and improves considerably results obtained for non-prismatic panels. This new reliable design tool, valid for any geometry and any typology of tapered steel plate girders, provides a solution of the main objective defined in this research.
| Author | : Isamu Hiroi |
| Publisher | : |
| Total Pages | : 156 |
| Release | : 1893 |
| Genre | : Girders |
| ISBN | : |
| Author | : Nigel Cooke |
| Publisher | : |
| Total Pages | : 212 |
| Release | : 1978 |
| Genre | : Flexure |
| ISBN | : |
| Author | : Firas Assoodani |
| Publisher | : LAP Lambert Academic Publishing |
| Total Pages | : 696 |
| Release | : 2015-11-16 |
| Genre | : |
| ISBN | : 9783659784538 |
The main objective of this work is to study shear behaviour and strength of retrofitted steel structures, especially: Steel Plate Girders (SPGs) and Composite Plate Girders (CPGs) retrofitted by CFRP composites bonded adhesively to web plates and loaded primarily in shear. After reviewing the existing literature, an extensive experimental programme was designed and performed in four phases, to test (I) 36 direct-tension specimens, (II) 7 reduced-scale SPGs, (III) 6 full-scale SPGs and (IV) 6 full-scale CPGs. Then, theoretical investigations were performed to analysis both steel and composite plate girders. The proposed models were verified by case studies, and then invested into analytical parametric studies. Practical design issues were discussed, including the optimum retrofitting scheme, and new design equations were proposed. The results of the experimental programme are very promising in light of increasing the ultimate load of the reference girders as high as 232%, and the ductility investigations showed that retrofitted girders are still ductile. All retrofitted specimens exhibited an increase in elastic stiffness, but with different ratios.
| Author | : |
| Publisher | : |
| Total Pages | : 178 |
| Release | : 2005 |
| Genre | : Plate girder bridges |
| ISBN | : |
| Author | : |
| Publisher | : |
| Total Pages | : 339 |
| Release | : 2002 |
| Genre | : Steel structures |
| ISBN | : 9789289431088 |
| Author | : Anwer Al-Kaimakchi |
| Publisher | : |
| Total Pages | : 0 |
| Release | : 2020 |
| Genre | : Civil engineering |
| ISBN | : |
Prestressed concrete is used in structures because of its versatility, adaptability, and durability. Durability of prestressed concrete bridges in extremely aggressive environments is of increasing concern because of corrosion of the carbon steel strands that are typically used for prestressing. Concrete is a permeable material where chloride ions can penetrate through and reach the internal reinforcement and carbon steel strands are highly susceptible to corrosion. Thus, prestressed concrete bridges located in areas with high exposure to environmental factors (e.g., marine environments) deteriorate due to corrosion of carbon steel strands. For example, Florida has a long coastline, with many concrete bridges over coastal water. Among the 12,518 bridges in Florida, 6,303 are prestressed concrete, and almost half of them are older than 40 years. One solution to overcome the early deterioration of coastal bridges is to use corrosion-resistant strands, such as Duplex High-Strength Stainless Steel (HSSS) strands.HSSS strands have high corrosion resistance and are an alternative to carbon steel strands in concrete bridges in extremely aggressive environments. The growing interest in using stainless steel strands has led to the development of the ASTM A1114. In 2020, ASTM A1114 was released as a standard specification for low-relaxation, seven-wire, Grade 240, stainless steel strands for prestressed concrete. Stainless steel is made from different alloys compared to carbon steel, and thus the mechanical properties of stainless steel strands are fundamentally different than those of carbon steel strands. The most significant difference is in the guaranteed ultimate strain: the value for stainless steel strands is only 1.4%. Several departments of transportation (DOTs) have already used or allowed the use of HSSS strands in prestressed piles. As of 2020, a total of 17 projects have used stainless steel strands, a majority of them in piles. Those projects are in areas with high exposure to environmental factors. The use of HSSS strands in flexural members has been hindered by the lack of full-scale test results, structural design approaches, and/or design guidelines. The main concern in using HSSS strands in flexural members is their low ductility. Concrete members prestressed with HSSS strands, if not properly designed, might fail suddenly without adequate warning. There have been no attempts to address this problem in full-scale research studies. The goals of this research project were to investigate the use of HSSS strands in flexural members and to develop design guidelines that could be used by bridge engineers. A total of thirteen (13) 42-ft-long AASHTO Type II girders were designed, fabricated, and tested in flexure or shear. Ten (10) girders were prestressed with HSSS strands, while the other three (3) were prestressed with carbon steel strands and served as control girders. This research program included experimental activities to determine the mechanical and bond strength characteristics, prestress losses, and transfer length of 0.6-in-diameter HSSS strands. Twenty HSSS strands from two spools were tested in direct tension. A stress-strain equation is proposed for the 0.6-in.-diameter HSSS strands, which satisfied all ASTM A1114 requirements. The minimum and average bond strengths, following ASTM A1081, of six 0.6-in.-diameter HSSS strands were 15.8 kips and 17.9 kips, respectively. The minimum and average experimental ASTM A1081 bond strengths were 23.4% and 19.8% greater than the recommended values by PCI Strand Bond Task Group. The maximum measured transfer length of 0.6-in.-diameter HSSS strands was 21.5 inches, which was less than the value predicted by AASHTO LRFD Bridge Design Specifications' equation for carbon steel strands. Experimental flexural and shear results showed that the post-cracking behavior of girders prestressed with HSSS strands continued to increase up to failure with no discernible plateau. The behavior is attributed to the stress-strain behavior of the HSSS strands. Also, flexural results revealed that, although HSSS strands have low ductility and all composite girders failed due to rupture of strands, the girders exhibited large reserve deflection and strength beyond the cracking load and provided significant and substantial warning through large deflection, as well as well-distributed and extensive flexural cracking, before failure. A non-linear analytical model and an iterative numerical model were developed to predict the flexural behavior of concrete members prestressed with HSSS strands. Although the analytical model gave better predictions, the iterative numerical approach is slightly conservative and is easier to use for design - designers prefer to use an equation type of approach to perform preliminary designs. Numerical equations were developed to calculate the nominal flexural resistance for flexural members prestressed with HSSS strands. The proposed equations are only valid for rectangular sections. In the case of flanged sections, iterative numerical approaches were also introduced. Because HSSS strand is a brittle material, the design must consider the strain capacity of the strand and must be balanced between flexural strength and ductility. Based on the flexural design philosophy for using carbon steel strands in prestressed concrete girders, along with experimentally-observed behaviors and analytical results for concrete members prestressed with HSSS strands, flexural design guidelines were developed for the use of HSSS strands in flexural members. For I-girders, rupture of strands failure mode is recommended by assuring that concrete in the extreme compression fiber reaches considerable inelastic stresses, at least 0.7f_c^'. For slab beams (e.g. Florida Slab Beam), crushing of concrete failure mode is recommended by assuring that the net tensile strain in the HSSS strand is greater than 0.005. The recommended maximum allowable jacking stress and stress immediately prior to transfer are 75% and 70%, respectively. A resistance factor of 0.75 is recommended for both rupture of strand and crushing of concrete failure modes. AASHTO equations conservatively estimated the measured transfer length and prestress losses of 0.6-inches-diameter HSSS strands. The ACI 318-19 and AASHTO LRFD conservatively predicted the shear capacity of concrete girders prestressed with HSSS strands.
