Recycling technologies for

Schaumburg, II., 14th-16th June 1993, p.73-81. 8(13) ADVANCED RECYCLING TECHNOLOGIES FOR PLASTICS... 

Proponents of a technology that converts plastics into chemical feedstocks for use as new resin or fuel, are optimistic that it will eventually be accepted as recycling. The technologies and targets vary, but, according to representatives, the conversion of plastics into feedstocks is a feasible recycling technology for wastes that do not... 

RECYCLING TECHNOLOGY FOR LAMINATES COMPOSED OF THERMOPLASTIC POLYOLEFIN ELASTOMER AND CROSSLINKED POLYPROPYLENE FOAM... 

The multi-layer structure of cartons continues to be an environmental issue. However, much has been done to develop recyclable technology for drinks cartons. One output uses a chipboard-effect material of the type used to make furniture at the other end of the lifecycle is incineration with reclaimed heat. 

New pathways in plastics recycling and the current status of plastics recycling has been recently highlighted by Kaminsky et al. [28]. The development of different viable recycling technologies for plastic waste materials is becoming increasingly important. The... 

M. W. Meszaros, Advanced recycling technologies for plastics. In Conversion and Utilization of Waste Materials, M. R. Khan (ed.), Taylor Francis, Washington D.C., 1996. 

A recycling technology for NiMH batteries is now under development. Ni, Co and Fe are used for stainless steel products. There are now 8 recyclers in Japan, but they... 

A closed loop recycling technology for components that contain brominated flame retardants has been specifically developed by Fuji Xerox, in conjunction with the resin manufacturer Ube Cycon, by purchasing cmshed and granulated waste components, decontaminating, re-compounding and... 

ICI Polyurethanes is working on development of a split-phase glycolysis chemical recycling technology for polyurethane, and plans to build a full-scale plant in Britain to recycle polyurethane foam from mattresses, furniture, and automotive seat cushioning. 

In situ generation of performic and peracetic acids has an important application in producing epoxidised soya bean oil (ESBO), a plasticiser and stabiliser. Acetic acid is often recycled. Technology for manufacture of propylene oxide [15] and of epichlorhydrin [16] using internal recycle systems for peracetic or perpropionic acids was developed, but for these products the costs have not been quite competitive with current routes, up to now. 

FIGURE 23.14 Umicore battery recycling technology. (For color version of this figure, the reader is referred to the online version of this book.)... 

Pickering S J (2006), Recycling technologies for thermoset composite materials - current status . Compos Appl Sci Manuf 37, 1206-1215. 

Boks, C.B. and Tempelman, E. (1997) Delphi Study on fixture disassembly and recycling technology for the electronics and automotive Industries. Internal document code K370, Faculty of Industrial Design Engineering, Delft University of Technology. 

Chapter 2 of the book describes in detail the use of recycled polymers in blends, composites and nanocomposites. Different types of recycled polymers and their respective composites/nanocomposites are summarised in this chapter, with more emphasis on their thermal and morphological properties. Figure 1.6 summarises some of the recycling technologies for composite waste [6]. 

Figure 1.6 Recycling technologies for composite waste. Reproduced with permission from C. Morin, A. Loppinet-Serani, F. Cansell and C. Aymonier, Journal of Supercritical Fluids, 2012, 66, 232. 2012, Elsevier [6]...

The recycling technologies for CFRP are generally classed into three categories which are primary, secondary and tertiary recycling approaches. Each of these approaches has their own advantages and disadvantages. 

Pickering, S.J. (2006) Recycling technologies for thermoset composite materials-current status. Composites Part A, 37 (8), 1206-1215. 

Our data indicate that the proportion of water benign inventions in the total of corporate inventive activities is higher in the field of end-of-pipe technologies than in the field of recycling technologies for Henkel, and in particular for Solvay (see table 4, column 5 and 6). 

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