Panting fatigue of AL-6XN stainless steel box girders /

Paterson, Duncan,

January 2004

Thesis (Ph. D.)--Lehigh University, 2004. / Includes vita. Includes bibliographical references.

Analysis of a thin-walled curved rectangular beam with five degrees of freedom

Moghal, Khurram Zeshan.

January 2003

Thesis (M.S.)--Mississippi State University. Department of Mechanical Engineering. / Title from title screen. Includes bibliographical references.

Thin-walled box beam finite elements for static analysis of curved haunched and skew multicell box girder bridges.

Li, Hangang, Carleton University. Dissertation. Engineering, Civil.

January 1992

Thesis (Ph. D.)--Carleton University, 1992. / Also available in electronic format on the Internet.

Behavior of open web precast bridge girders : analytical study

Tschanz, T.

January 1974

No description available.

Bridges -- Design and construction.

Girders.

Finite element method.

Box beams.

Forensic Investigation of Prestressed Concrete Box Beams from LIC-310 Bridge

Gulistani, Aziz A.

16 April 2010

No description available.

Civil Engineering

Prestressed concrete

chloride

forensic investigation

strands

box-beams

A finite element meshing method for the analysis of posttensioned concrete box girder bridges

Bausch, Ulrich Karl

12 1900

No description available.

Box beams

Finite element method

Engineering mathematics

Dynamic Behavior of Composite Adjacent Pre-Stressed Concrete Box Beams Bridges

Ali, Hajir A.

23 May 2022

No description available.

Engineering

Adjacent Box Beams

Dynamic Load Allowance (DLA)

Moving Load Analysis

Field Assessment

Finite Element Analysis

Optimization of composite box-beam structures including effects of subcomponent interaction

Ragon, Scott Alan

16 June 2009

Minimum mass designs are obtained for a simple box beam structure subject to bending, torque and combined bending/torque load cases. These designs are obtained subject to point strain and linear buckling constraints. The present work differs from previous efforts in that special attention is payed to including the effects of subcomponent panel interaction in the optimal design process. Two different approaches are used to impose the buckling constraints. When the global approach is used, buckling constraints are imposed on the global structure via a linear eigenvalue analysis. This approach allows the subcomponent panels to interact in a realistic manner. The results obtained using this approach are compared to results obtained using a traditional, less expensive approach, called the local approach. When the local approach is used, in-plane loads are extracted from the global model and used to impose buckling constraints on each subcomponent panel individually. In the global cases, it is found that there can be significant interaction between skin, spar, and rib design variables. This coupling is weak or nonexistent in the local designs. It is determined that weight savings of up to 7% may be obtained by using the global approach instead of the local approach to design these structures. Several of the designs obtained using the linear buckling analysis are subjected to a geometrically nonlinear analysis. For the designs which were subjected to bending loads, the innermost rib panel begins to collapse at less than half the intended design load and in a mode different from that predicted by linear analysis. The discrepancy between the predicted linear and nonlinear responses is attributed to the effects of the nonlinear rib crushing load, and the parameter which controls this rib collapse failure mode is shown to be the rib thickness. The rib collapse failure mode may be avoided by increasing the rib thickness above the value obtained from the (linear analysis based) optimizer. It is concluded that it would be necessary to include geometric nonlinearities in the design optimization process if the true optimum in this case were to be found. / Master of Science

LD5655.V855 1994.R346

Box beams -- Design and construction

Composite construction

Finite Element Modeling of the Load Transfer Mechanism in Adjacent Prestressed Concrete Box-Beams

Giraldo-Londono, Oliver

10 June 2014

No description available.

Engineering

Adjacent Box-Beams

Bridge Modeling

Finite Element Modeling

Transverse Post-tensioning

Temperature Gradients

Analytical Investigation of Adjacent Box Beam Ultra-High Performance ConcreteConnections

Ubbing, John Lawrence

24 September 2014

No description available.

Civil Engineering

Ultra-High Performance Concrete

Box Beams

Shear key

Dowel Bars

Finite Element Modeling