This award is funded under the American Recovery and Reinvestment Act of 2009 (Public Law 111-5).
This Small Business Technology Transfer Phase II project will change the paradigm that two-phase chemical reactions must use mechanical mixing to be commercially effective. The innovative Fiber Reactor (TM) offers two orders of magnitude change in efficiency for chemical and biochemical manufacturing. This project will focus on biodiesel transesterification reactions. Biodiesel plants convert fats/oils to biodiesel with multiple reactor stages and centrifuge stages. Complexity is due to poor mass transfer, poor reaction conversion, and poor phase separations due to by-product soap. Improving mass transfer and eliminating soap dispersions will reduce the cost of manufacturing biodiesel. In Phase I experiments, the Fiber Reactor was 3-100 times faster than commercial biodiesel processes with superior conversion. Advanced Materials and Processes has found an unconventional way to improve mass transfer and simultaneously solve phase separation problems in biodiesel processes. Use of a Fiber Reactor will reduce complexity, size, capital, energy consumption, and water pollution by dramatically improving mass transfer and eliminating dispersions. Phase I proved feasibility of energy savings and process intensification in biodiesel manufacturing. Phase II will use Phase I models and CHEMCAD models to design and operate a pilot reactor using the high throughput continuous static Fiber Reactor and wash processes.
Biodiesel capacity could increase 10 times by 2015 and improve U.S. energy security. Two hurdles remain - produce the triglyceride needed and match petroleum economics. A new industry and networks are being developed to supply enough algae oil. Fiber Reactors will reduce capital and operating cost for producing biodiesel by 50% and use low cost crude oils/fats. Phase I developed basic transesterification chemistry for Fiber Reactors. Phase II will develop chemistry/engineering data for scale up. Fiber technology will apply to pharmaceutical and specialty chemical manufacturing with similar benefits. This project will integrate research and education by training students in organic chemistry, fibers, materials, processes, pilot operations, fractionation, analysis, organic synthesis, and quality control. Students use wet chemistry, GPC, HPLC and LC/MS for identification/quantification of raw materials and reaction products. Texas State University graduated 46 chemistry/biochemistry majors in 2008. Enrollment in 2009 included 329 chemistry/biochemistry majors. The 37 graduate students were 35% minority and 48% women. IEIS has provided research assistantships/employment to over 100 students of whom 62% were women or minorities. This project will have a positive impact on the research capabilities of academic departments and IEIS; and help women and minorities to improve their training in industrial chemistry.
processes using fiber reactor technology. The fiber processes can use any available triglyceride or fatty acid feedstock to make biodiesel. This combination will reduce the cost of producing biodiesel. Cost of producing biodiesel will be reduced because feedstock costs and capital to build plants are reduced. Operating costs and maintenance costs are also reduced. Biofuels have much lower carbon dioxide footprint. This project represents potentially transformative research because it is leading to a transformation of our understanding of how to perform two phase chemical reactions without dispersing one phase in the other. This Small Business Technology Transfer Phase II project will change the paradigm that two-phase chemical reactions must use mechanical mixing to be commercially effective. The innovative FiberReactor™ offers two orders of magnitude change in efficiency for chemical and biochemical manufacturing. This project focused on biodiesel manufacturing processes. Current biodiesel plants convert fats and/or vegetable oils to biodiesel with multiple reactor stages and centrifuge stages. Complexity is due to poor mass transfer, poor reaction conversion, and poor phase separations due to by-product soap. Improving mass transfer and eliminating soap dispersions will reduce the cost of manufacturing biodiesel. The FiberReactor was 3-100 times faster than commercial biodiesel processes with superior conversion. Advanced Materials and Processes has found an unconventional way to improve mass transfer and simultaneously solve phase separation problems in biodiesel processes. Use of a Fiber Reactor will reduce complexity, size, capital, energy consumption, and water pollution by dramatically improving mass transfer and eliminating dispersions. This project is proving feasibility of energy savings and process intensification in biodiesel manufacturing. Biodiesel capacity could increase 10 times by 2020. Two hurdles remain – grow the triglyceride needed and match petroleum economics. A new industry and networks are being developed to supply enough algae oil. Fiber Reactors will reduce capital and operating cost for producing biodiesel by 50% and use low cost crude vegetable oils and fats. This project has developed basic transesterification chemistry for Fiber Reactors and chemistry/engineering data for scale up. Fiber technology will apply to pharmaceutical, specialty chemical manufacturing, and the mining industry with similar benefits.