Behavior of curved steel trapezoidal box girders during construction

Topkaya, Cem

28 August 2008

Not available / text

Box beams

Girders

Bridges--Design and construction

Steel, Structural

Dynamic response of skeived girder bridges to moving loads.

Eka, U. J. U.

January 1971

No description available.

Girders

Bridges -- Design and construction.

Bridges -- Models.

Bridges -- Live loads

Acceptance criteria for fiber-reinforced polymeric bridge deck panels

Engindeniz, Murat

05 1900

No description available.

Bridges Materials

Bridges Testing

Bridges Design and construction

Fiber reinforced plastics

Behavior of open web precast bridge girders : analytical study

Tschanz, T.

January 1974

No description available.

Girders.

Box beams.

Bridges -- Design and construction.

Finite element method.

Static and free vibration analysis of curved box bridges.

Fam, Adel Refaat Metyas.

January 1972

No description available.

Bridges, Arched -- Vibration.

Development of FRP-Glulam Panel for Bridge Deck Replacement

Xu, Han

January 2001

No description available.

Fiber reinforced plastics

Laminated wood

Cable stayed bridges : nonlinear elastic dimensional analysis

Janzen, Walter F.

January 1988

Cable stayed bridges are the state of the art in long span bridges. Developments in cable response analysis and computer hardware and software have allowed engineers to design and build many cable stayed bridges. Bridges of many different configurations with longer and longer spans are being built. With the long spans and high axial loads in the deck, the stability of cable stayed bridges becomes a growing concern. Current analysis procedures use a parabolic approximation to the true catenary response of cables, which is quite accurate for tight cables; however, for near instability conditions with the accompanying large deflections and consequently loose cables, a catenary model is called for. Herein, a study is conducted on the elastic stability of cable stayed bridges utilizing a true catenary model of cable response. A dimensional analysis of cable stayed bridge stability is undertaken as well as deck maximum deflection and moment under service load conditions. A computer program written by this author is the analysis tool used in this work. The program is given the acronym ULA which stands for Ultimate Load Analysis. ULA is a nonlinear plane frame program with catenary cable elements and an interactive graphics interface. The dimensional analysis is carried out by comparing the computer model of a cable stayed bridge to the theoretical model of a beam on an elastic foundation. Two preliminary simplified cable stayed bridge backspan models are studied first in order to develop the dimensionless ratios that are applicable to the bridge response and to gain an insight into the cable stayed bridge behaviour. The final model is that of an entire cable stayed bridge. Because of the multitude of parameters governing cable stayed bridge behaviour it is not possible to describe all cable stayed bridges. Instead, the dimensionless behaviour of a standard model is examined and the sensitivity of this standard to various parameter variations is given in the form of dimensionless charts. Finally, a preliminary design and analysis aid is developed from the dimensionless charts and is then applied to two existing bridge designs. / Applied Science, Faculty of / Civil Engineering, Department of / Graduate

Elastic analysis (Engineering)

Numerical Modeling and Analyses of Steel Bridge Gusset Plate Connections

Kay, Thomas Sidney

01 January 2011

Gusset plate connections are commonly used in steel truss bridges to connect individual members together at a node. Many of these bridges are classified as non-load-path-redundant bridges, meaning a failure of a single truss member or connection could lead to collapse. Current gusset plated design philosophy is based upon experimental work from simplified, small-scale connections which are seldom representative of bridge connections. This makes development of a refined methodology for conducting high-fidelity strength capacity evaluations for existing bridge connections a highly desirable goal. The primary goal of this research effort is to develop an analytical model capable of evaluating gusset plate stresses and ultimate strength limit states. A connection-level gusset connection model was developed in parallel with an experimental testing program at Oregon State University. Data was collected on elastic stress distributions and ultimate buckling capacity. The analytical model compared different bolt modeling techniques on their effectiveness in predicting buckling loads and stress distributions. Analytical tensile capacity was compared to the current bridge gusset plate design equations for block shear. Results from the elastic stress analysis showed no significant differences between the bolt modeling techniques examined, and moderate correlation between analytical and experimental values. Results from the analytical model predicted experimental buckling capacity within 10% for most of the bolt modeling techniques examined. Tensile capacity was within 7% of the calculated tensile nominal capacity for all bolt modeling techniques examined. A preliminary parametric study was conducted to investigate the effects of member flexural stiffness and length on gusset plate buckling capacity, and showed an increase in member length or decrease in member flexural stiffness resulted in diminished gusset plate buckling capacity.

Gusset plates

Finite element method

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.

Static and free vibration analysis of curved box bridges.

Fam, Adel Refaat Metyas.

January 1972

No description available.

Bridges, Arched -- Vibration.