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The origins of recrystallisation textures in batch annealing steels寧華, Ning, Hua. January 1999 (has links)
published_or_final_version / Mechanical Engineering / Doctoral / Doctor of Philosophy
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Development of a plane strain compression test to simulate the hot rolling of carbon manganese plate steelsBanks, Kevin Mark 10 June 2016 (has links)
A dissertation submitted to the Faculty of Engineering, University of the
Witwatersrand, Johannesburg, in fulfilment of the requirements for the degree
of Master of Science in Engineering.
,Department of Metallurgy and Materials Engineering
University of the Witwatersrand
Johannesburg, 1990. / An instrumented hot deformation simulator was desLgned, cons'.:ructedand
commissioned at Iscor's Pilot Plant. A modified servohydraulic machine,
using plane strain compression, simulated industrial plate rolling
schedules. The simulation test included induction heating, multiple pass
plane strain compression and either air cooling or quenching. The
movement of the specimen between the different test stages was computer
controlled. Accurate control of specimen temperature, strain atrain rate
and interpass hold times was achieved by means of sophisticated data
acquds i+Lon equipment. A comput er programme was written to simulate the
hot. rolling of plate in t erms of roll sepa ratIng f.orces, ffiE.\tallurgical
changes during deformation as well as the final microstructure and
mechanical properties of SGa carbon manganese steel. Multiple linear
regression was pe.rformed on the results obtained from mUlti-pass plane
strain compression tests. It was found that themical composition, finish
temperature and finish strain were the most important process parameters
affecting yield strength and impact energy of air cooled place. A
computer model was developed to simulate the temperature distribution in
the deformation zone of a plane strain compressLon specimen at any point
during or after a mUlti-pass test.
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The effects of hydrogen on the fracture behavior of welded carbon steel plateWatson, Thomas January 1983 (has links)
The effects of hydrogen on the fracture behavior of manual SMA welds in carbon steel plate was investigated utilizing modified ½T compact tension specimens. Tests performed on these specimens in the presence of hydrogen were compared to similar tests in helium. These tests showed that hydrogen lowers J<sub>C</sub> in both the heat affected zone and the base metal. In 350 psi helium, the experimental value of J<sub>C</sub> in the heat affected zone (2826 in.-lbs./in.<sup>2</sup>) was greater than that obtained in the base metal (1650 in.-lbs./in.<sup>2</sup>). The tests conducted in 350 psi hydrogen resulted in a reduction in J<sub>C</sub> for both the heat affected zone (1425 in.-lbs./in.<sup>2</sup>) and the base metal (59 in.-lbs./in.<sup>2</sup>). Furthermore, when compared to specimens tested in helium, it was determined that the material tearing modulus for specimens tested in hydrogen was significantly reduced. Slow stable crack growth occurred in all helium tests and in tests performed on the heat affected zone in hydrogen. However, unstable crack growth (fast fracture) was obtained for base metal tests in hydrogen. Fractographic studies revealed that the mechanism for all slow stable crack growth was microvoid coalescence; whereas, the surface of base metal specimens tested in hydrogen showed that fast fracture occurred by cleavage. Optical microscopy revealed that the fracture path for all base metal tests remained in the base metal, but that the fracture path for all heat affected zone tests moved towards the base. These observations, in conjunction with microhardness readings and quantitative metallography, were used to develop explanations for the observed behavior. These explanations include the combined effects of hydrogen, weld defects, residual stresses, grain size, and test variables such as temperature and specimen size and geometry. / M. S.
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