SBIR-STTR Award

The fluorocarbon industry in the United States currently generates over 1,200,000 pounds of spent antimony fluorocarbon catalyst annually in producing 1,190 million pounds of fluorocarbons (CIFCS, HCFCS, BFCS). 'Mis spent catalyst is a mixture of halogenated organic compounds (HOCs), antimony, and arsenic halides. It is extremely hazardous, toxic, and corrosive. It contains at least eight listed "characteristic" wastes (e.g., CHC4, CCI,, C2CI,,, CCI). @cally, as ozone-damaging, fully halogenated chlorofluorocarbons (CFCs) are replaced by their less damaging or benign cousins, HCFCs and BFCS, spent catalyst generation will increase, since more catalyst is consumed in the production of these replacement species. This material is currently processed in the United States for antimony pentachloride recovery and recycle at an off-site facility. The proposed Phase I work is aimed at demonstrating a procedure for the on-site handling of the catalyst that will permit the recycling of a major portion of the HOCs as well as the antimony catalyst itself back to the fluorocarbon process. It also incorporates the in-process use of the other contained HOCs and the isolation for sale of perchloroethylene, a byproduct of the process. In this fashion the HOCs that ultimately would constitute an incinerable waste are reduced to only 20% of that separated and incinerated using current technology. 'ne process has the potential for reducing waste generation at the source of one-third that currentiy achievable using the best current off-site recovery and recycling technology.

Annually the fluorocarbon industry in the United States produces about 1,000 million pounds of various fluorocarbons (CFCs, HCFCs, HFCs) which in turn generate more the 1 million pounds of deactivated antimony pentachloride (SbCl5) production catalyst. The spent catalyst is an extremely toxic and corrosive mixture of antimony and arsenic halides and EPA regulated halogenated organic compounds (HOCs) (e.g., CHCl3, CCl4, C2Cl6, C6Cl6) ù The majority of U.S. fluorocarbon manufacturers ship the mixture to Chemical and Metal Industries (C&MI) where pure catalyst is reclaimed and returned.In Phase I, C&MI developed a process which allows manufacturers to reclaim the catalysts themselves. On-site reclamation both minimizes hazardous material shipping and encourages HOC recycling to fluorocarbon production feed streams. Phase I mass balance estimates indicate that C&MI's process has the potential to decrease hazardous waste generation by 95% over present reclamation technology.The goal of the Phase II research is to refine the proposed process on a pilot plant scale. After construction of the pilot facility, most research will involve evaluation of the process using several industrial spent catalysts. A detailed economic analysis of required capital investment and operating costs will be derived from market research and pilot plant information. A comparison between the economics of the proposed process versus C&MI's current handling methods will permit assessment of the commercialization potential.