| Advanced Wear-Resistant Nanocomposites for Increased Energy Efficiency: CPS Agreement No. 15015 Contributor(s): Harringa, J. L. (Author), Russell, A. M. (Author), Cook, B. a. (Author) |
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ISBN: 1478379936 ISBN-13: 9781478379935 Publisher: Createspace Independent Publishing Platform OUR PRICE: $17.09 Product Type: Paperback Published: August 2012 |
| Additional Information |
| BISAC Categories: - Science | Energy |
| Physical Information: 0.29" H x 8.5" W x 11.02" (0.73 lbs) 136 pages |
| Descriptions, Reviews, Etc. |
| Publisher Description: This report summarizes the work performed by an Ames-led project team under a 4-year DOEITP sponsored project titled, "Advanced Wear-resistant Nanocomposites for Increased Energy Efficiency." The Report serves as the project deliverable for the CPS agreement number 15015. The purpose of this project was to develop and commercialize a family of lightweight, bulk composite materials that are highly resistant to degradation by erosive and abrasive wear. These materials, based on AlMgB14, are projected to save over 30 TBtu of energy per year when fully implemented in industrial applications, with the associated environmental benefits of eliminating the burning of 1.5 M tons/yr of coal and averting the release of 4.2 M tons/yr of CO2 into the air. This program targeted applications in the mining, drilling, machining, and dry erosion applications as key platforms for initial commercialization, which includes some of the most severe wear conditions in industry. Production-scale manufacturing of this technology has begun through a start-up company, NewTech Ceramics (NTC). This project included providing technical support to NTC in order to facilitate cost-effective mass production of the wearresistant boride components. Resolution of issues related to processing scale-up, reduction in energy intensity during processing, and improving the quality and performance of the composites, without adding to the cost of processing were among the primary technical focus areas of this program. Compositional refinements were also investigated in order to achieve the maximum wear resistance. In addition, synthesis of large-scale, single-phase AlMgB14 powder was conducted for use as PVD sputtering targets for nanocoating applications. |