The Influence of Aluminum and Carbon on the Abrasion Resistance of High Manganese Steels PDF Download
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Author: Samuel August Buckholz Publisher: ISBN: Category : Aluminum alloys Languages : en Pages : 244
Book Description
"Abrasive wear testing of lightweight, austenitic Fe-Mn-AI-C cast steel has been performed in accordance with ASTM G65 using a dry sand, rubber wheel, abrasion testing apparatus. Testing was conducted on a series of Fe-30Mn-XAI-YC-1Si-0.5Mo chemistries containing aluminum levels from 2.9 to 9.5 wt.% and carbon levels from 0.9 to 1.83 wt.%. Solution treated materials having an austenitic microstructure produced the highest wear resistance. Wear resistance decreased with higher aluminum, lower carbon, and higher hardness after age hardening. In the solution treated condition the wear rate was a strong function of the aluminum to carbon ratio and the wear rate increased with a parabolic dependence on the AI/C ratio, which ranged from 1.8 to 10.2. Examination of the surface wear scar revealed a mechanism of plowing during abrasion testing and this method of material removal is sensitive to work hardening rate. Work hardening behavior was determined from tensile tests and also decreased with increasing AI/C ratio and after aging hardening. The loss of wear resistance is related to short range ordering of AI and C in the solution treated materials and K-carbide precipitation in age hardened materials and both contribute to planar slip and lower work hardening rates. A high carbon tool steel (W1) and a bainitic low alloy steel (SAE 8620) were also tested for comparison. A lightweight steel containing 6.5 wt.% AI and 1.2 wt.% C has wear resistance comparable to within 5% of the bainitic SAE 8620 steel forging currently used for the Bradley Fighting Vehicle track shoe and this cast Fe-Mn-AIC steel, at equivalent tensile properties, would be 10% lighter"--Abstract, leaf iii.
Author: Samuel August Buckholz Publisher: ISBN: Category : Aluminum alloys Languages : en Pages : 244
Book Description
"Abrasive wear testing of lightweight, austenitic Fe-Mn-AI-C cast steel has been performed in accordance with ASTM G65 using a dry sand, rubber wheel, abrasion testing apparatus. Testing was conducted on a series of Fe-30Mn-XAI-YC-1Si-0.5Mo chemistries containing aluminum levels from 2.9 to 9.5 wt.% and carbon levels from 0.9 to 1.83 wt.%. Solution treated materials having an austenitic microstructure produced the highest wear resistance. Wear resistance decreased with higher aluminum, lower carbon, and higher hardness after age hardening. In the solution treated condition the wear rate was a strong function of the aluminum to carbon ratio and the wear rate increased with a parabolic dependence on the AI/C ratio, which ranged from 1.8 to 10.2. Examination of the surface wear scar revealed a mechanism of plowing during abrasion testing and this method of material removal is sensitive to work hardening rate. Work hardening behavior was determined from tensile tests and also decreased with increasing AI/C ratio and after aging hardening. The loss of wear resistance is related to short range ordering of AI and C in the solution treated materials and K-carbide precipitation in age hardened materials and both contribute to planar slip and lower work hardening rates. A high carbon tool steel (W1) and a bainitic low alloy steel (SAE 8620) were also tested for comparison. A lightweight steel containing 6.5 wt.% AI and 1.2 wt.% C has wear resistance comparable to within 5% of the bainitic SAE 8620 steel forging currently used for the Bradley Fighting Vehicle track shoe and this cast Fe-Mn-AIC steel, at equivalent tensile properties, would be 10% lighter"--Abstract, leaf iii.
Author: BLAKE KENDALL ZUIDEMA Publisher: ISBN: Category : Languages : en Pages : 181
Book Description
content beyond which both declined. Maximum work-hardening rate was exhibited by an alloy containing nominally 1.75% C, 13.5% Mn, and 1.3% Al. Improved high-stress abrasion resistance was also found in an alloy containing nominally 1.00% C, 13.5% Mn, and 4.00% Al.
Author: K. I. Vashchenko Publisher: ISBN: Category : Languages : en Pages : 11
Book Description
The effect of chromium, aluminum and silicon on the wear of high-alloy chromium steels in abrasive media at high temperatures has been investigated. The steels were melted in high-frequency furnace and cast into specimens 50 mm in diameter and 10 mm thick. The effect of chromium content on the abrasive wear was tested on steel specimens containing 0.35% carbon, 3.1% aluminum, 0.8% silicon, 0.3% manganese and 12--30% chromium. (Author).
Author: J.J. Kalker Publisher: Springer Science & Business Media ISBN: 9780792322634 Category : Mathematics Languages : en Pages : 476
Book Description
This volume presents a collection of papers on the theme of rail integrity, which were presented at a meeting in Delft from 24--26th June, 1992. Rolling contact fatigue is a failure mode which is increasingly being recognised as a threat to the reliability of modern heavy freight and high speed railway systems. These papers describe the current understanding of the problem and what rail steel technology and maintenance procedures have to offer to combat it.
Author: Peter J. Blau Publisher: Elsevier ISBN: 9780080447360 Category : Technology & Engineering Languages : en Pages : 826
Book Description
These proceedings of the 15th International Conference on Wear of Materials focus on the friction and wear of materials in various applications under different environments from the nanometer scale to the meter scale. The conference provides a unique international forum for researchers and practitioners from different disciplines to exchange latest results. Coverage includes: . Wear assessment and monitoring . Wear modeling, mechanisms, mapping and prediction . Wear-corrosion testing and control . Surface engineering for wear and wear-corrosion control . Development of new wear test methods and wear test methodologies . Wear of materials for biomedical applications . Wear of non-equilibrium materials: from atomic dimensions to the micro-scale . Wear of hard and superhard materials . Wear of materials in the earthmoving, minerals processing and mining industries
Author: Samuel August Buckholz
Author: Samuel August Buckholz
Author: BLAKE KENDALL ZUIDEMA
Author: United States. Bureau of Mines
Author: 
Author: University of Michigan. College of Engineering
Author: K. I. Vashchenko
Author: 
Author: 
Author: J.J. Kalker
Author: Peter J. Blau