Metal Recovery via Automated Sortation

Yu, Hao

17 April 2014

Each year, millions of tons of non-ferrous scrap metal are discarded in the US. This metal is wasted due to a lack of proper recovery methods. Recent developments in spectroscopic technology have made it possible to identify the waste composition of scrap metal in real-time. This has opened the door for high-speed automated metal sortation and recovery, especially for the recovery of high value precious metals, such as titanium, nickel, cobalt, molybdenum and tantalum. Automated sortation systems typically consist of three main phases: (i) Feeding of material, (ii) Composition identification, and (iii) Physical separation. Due to their low volume and industry fragmentation, high-strength precious metal chips usually come in the form of chips smaller than 10 mm. Therefore it is extremely difficult to feed metal chips individually into the sorting system. At CR3, a new feeding mechanism was invented and developed in order to provide single layer feeding of small metal chips. A laboratory-scale prototype was built and proven to be feasible, scalable and reliable. A model was developed to predict the output of feeding variables based on initial input parameters. An operation window of the process was also defined for various metal chip resources. These will be presented, reviewed and discussed in the following paper.

DEM Simulation

Critical Metals

Feeding Technique

Scrap Recovery

A Study on Technological Innovation for High-Performance Engineering Plastic Scrap Recovery Industry

Lin, Cheng-Hsiang

04 July 2010

Abstract In general, plastic materials can be classified into two categories: "thermoplastic" and "thermosetting plastic", the former is usually recyclable, when the latter isn¡¦t, and which results the solid waste problem. In the same way in thermoplastic divided into: generic plastic, generic engineering plastic, high-performance engineering plastic three categories. As technology advances, a variety of industries flourish as the world trend, various products are gradually moves forward. To improve performance, high-performance engineering plastic is more widely used and occupied part of the product cost. However, all the using of high-performance engineering plastic in Taiwan relies on imports, as any discarded after use like bury or burn in the landfill and incinerator results waste of resources and pollution problems. Therefore, recycling has become an important tool to make full use of limited resources. In literature review, we discuss the theory of technological innovation, according to the data of high-performance engineering plastic scrap recovery industry, using the AHP model to identify key success factors, as a supplementary tool for corporate decision-making to reduce costs and increase product competitiveness. After the AHP analysis, this study found that high-performance engineering plastic scrap recovery industry in the technology innovation process should emphasize the principles according to the order of (1) Technology Innovation Strategy (2) Technology Innovation Investment (3) Sources of Technology Innovation (4) Organization Design and Culture, and found the indicators to access each of these four principles. Which allows us to create higher value, to maximize corporate profits, and lower raw material costs of manufacturing, to achieve great competitive in the market share when countries around the world are now confronted with the rising pressure of increasing oil prices and actively promoting the environmental protection, energy conservation, and carbon reduction.

plastic scrap recovery

the key success factors

AHP

technology innovation

engineering plastic