Global ETD Search

1	Determining the transfer length in prestressed concrete railroad ties produced in the United States Murphy, Robert Lawrence January 1900 (has links) Master of Science / Department of Civil Engineering / Robert J. Peterman / This thesis presents results from transfer length measurements on prestressed concrete railroad ties. Results are shown from the four main producers of concrete ties in the United States. Six prestressed concrete tie plants were visited by the research team to measure transfer length on ties with various mix designs and prestressing reinforcement. After all plants had been visited, a total of nine concrete-mix designs and 10 reinforcement variations were tested. Overall, 220 transfer length measurements were conducted on prestressed concrete railroad ties during the duration of this research project. This was the first coordinated effort to measure transfer lengths in concrete railroad ties ever conducted in the industry. Concrete strains were monitored using the standard Whittemore gage, as well as a non-contact procedure called laser-speckle imaging (LSI). This method to measure transfer lengths has been developed at Kansas State University (KSU). Ties measured using the Whittemore gage were sent back to the civil engineering structural laboratory at KSU so the long-term transfer lengths could be monitored. After a certain period of time, the ties were load-tested according to the American Railway Engineering and Maintenance-of-Way Association (AREMA) loading specifications of the rail-seat positive moment test. Transfer length Prestressed concrete railroad ties Civil Engineering (0543)
2	Precast prestressed ties on bridge girders : analytical and experimental load distribution studies Igwemezie, Jude O. January 1983 (has links) No description available. Railroad bridges. Prestressed concrete -- Testing. Concrete railroad ties -- Testing.
3	Dynamic response and impact effects in precast, prestressed concrete bridge ties Igwemezie, Jude O. January 1987 (has links) No description available. Concrete railroad ties. Railroad bridges. Bridges, Concrete -- Testing. Prestressed concrete.
4	Precast prestressed ties on bridge girders : experimental response and design review Igwe, Obi R. January 1983 (has links) No description available. Railroad bridges. Prestressed concrete -- Testing. Concrete railroad ties -- Testing.
5	Dynamic response and impact effects in precast, prestressed concrete bridge ties Igwemezie, Jude O. January 1987 (has links) No description available. Railroad bridges. Bridges, Concrete -- Testing. Prestressed concrete. Concrete railroad ties.
6	Precast prestressed ties on bridge girders : analytical and experimental load distribution studies Igwemezie, Jude O. January 1983 (has links) No description available. Prestressed concrete -- Testing. Railroad bridges. Concrete railroad ties -- Testing.
7	Precast prestressed ties on bridge girders : experimental response and design review Igwe, Obi R. January 1983 (has links) No description available. Prestressed concrete -- Testing. Railroad bridges. Concrete railroad ties -- Testing.
8	Un-tensioned pullout tests to predict the bond quality of different prestressing reinforcements used in concrete railroad ties Arnold, Matthew Lukas January 1900 (has links) Master of Science / Department of Civil Engineering / Robert J. Peterman / An experimental testing program was conducted at Kansas State University (KSU) to test the bond characteristics of various 5.32-mm-diameter steel wires and smaller diameter (less than 0.5 in.) strands used in prestressed concrete railroad ties. A total of 13 wires and six strands produced by seven different steel manufacturers were used during this testing. Since no wire bond pullout test currently exists, one was developed and its validity tested. This un-tensioned pullout test could serve as a quality control test similar to the standard test for strand bond (ASTM A1081) that has been developed for pretensioned strands. This strand test is currently not verified for strands less than 0.5-in. in diameter, so the procedure was also scrutinized using strands common in the concrete railroad tie industry. Some of the wires and strands contained surface indentations. It is generally accepted that indentations in the reinforcements improve the bond between the steel and concrete. To further complicate the issue, reinforcements with different surface conditions (rust, oils, lubricants) are allowed to be used in the concrete ties which further affects the bond quality of the reinforcements. However, no standardized indentation patterns (shape, size, depth of indent, etc.) or surface conditions (degree of rusting, amount of surface lubricants, etc.) are utilized by all wire and strand manufacturers. Thus, the corresponding bond behavior of these different reinforcements when placed in various concrete mixtures, in terms of average transfer lengths and typical variations, is essentially unknown. The purpose of this testing program was to develop (in the case of wires) or verify/develop (in the case of strands) a pullout testing procedure predictive of the reinforcement’s bond performance in a prestressed application. The test should be relatively inexpensive, demonstrably repeatable, and easily reproducible. Results from the un-tensioned pullout tests were compared to transfer length measurements from accompanying pretensioned concrete prisms in the lab. Additionally, pullout tests and transfer length measurements were obtained at an actual concrete railroad tie manufacturing plant. The obtained data was compared to the lab data and analyzed to further understand the relationship between un-tensioned pullout tests and pretensioned concrete members. Pullout test Transfer length Bond Concrete railroad ties Quality control Prestress Civil Engineering (0543)
9	Quality by design: improving pre-stressed reinforcement for concrete railroad ties via geometrical dimensioning and tolerancing Haynes, Mark Davis January 1900 (has links) Doctor of Philosophy / Department of Industrial & Manufacturing Systems Engineering / Chih-Hang John Wu / Quality is a result of product design and production control. Product design must maximize the ability to function across variations in production and environment. Production control must monitor and maintain the key design characteristics necessary for the intended function. Failure to do so results in premature part failure and increased costs. This has occurred in the production of modern cross ties. By designing quality into the product and production process, performance is maximized. This research presents a methodology for incorporating quality into the product design and production process. For product design, a relationship between product performance and design parameters is established by modeling techniques. These models provide a means to redesign the product to maximize performance and to understand the sensitivity of the design to fluctuation in production and environment. These models also establish the key design parameters that are critical for sustaining quality. For production, a method of monitoring the key design parameters is presented that provides an affordable means of automated inspection. Automated inspection removes operator error from the inspection process and allows for greater sampling rates to be achieved. The methodology presented allows for a potential of 100% inspection to be achieved with minimal impact to production costs. The research is applied to the analysis and quality control of pre-stressing steel reinforcement for concrete cross-ties. This application provides an opportunity to test and verify the research findings on a real world problem. Novel automated 3D spatial analysis algorithms are presented. This research furthers the state of the art of performing Geometrical Dimensioning and Tolerancing (GD&T). A cost effective method of non-contact surface profiling was developed with high resolution and high density surface profiles. The combined research findings present a methodology of achieving quality by design. Geometrical Dimensioning and Tolerancing Concrete Railroad Ties Prestressing Steel Reinforcement Wire Non-contact 3D scanning and inspection Metrology Quality Control Civil Engineering (0543) Engineering (0537) Industrial Engineering (0546)

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