(682d) Low-Pressure Hydrogenolysis of Vapor-Phase Glycerol Over Heterogeneous Catalysts | AIChE

(682d) Low-Pressure Hydrogenolysis of Vapor-Phase Glycerol Over Heterogeneous Catalysts

Authors 

Piephoff, D. E. - Presenter, Massachusetts Institute of Technology
Immer, J. G. - Presenter, North Carolina State University
Kelly, M. J. - Presenter, North Carolina State University


The recent increase in biodiesel production has resulted in a global glut of glycerol, the major byproduct of biodiesel transesterification, which has decreased the value of crude glycerol and rendered the product detrimental to biodiesel economics. This study presents a feasible process for the production of value-added products from glycerol via hydrogenolysis of vapor-phase glycerol over various heterogeneous catalysts at atmospheric pressure. Dynamic system behavior was observed via on-line gas chromatography. In order to determine the effect of H2 concentration on catalyst activity and product selectivity, reactions were typically conducted under H2 followed by 10% H2 (balance He) flow. Under all conditions tested, catalyst activity was greater under H2 than 10% H2 flow. Cu catalysts were found to be selective for hydrogenation products, such as 1,2-propanediol (1,2-PDO), under H2 and dehydration products, such as acetol and acrolein, under 10% H2 flow. Acrolein, a known thermal reaction product of glycerol, was produced most selectively when acetol was injected over blank quartz wool and glycerol was dehydrated over blank SiO2. A network of reaction pathways for glycerol hydrogenolysis over Cu catalysts was proposed based on the observed temporal product selectivity behavior. Supported Ni catalysts were found to be highly active for C-C bond hydrogenolysis, generally producing C1 products, such as methanol, more selectively under 10% H2 and C2 products, such as ethylene glycol, more selectively under H2 flow. When reactions were performed over Ni/Al2O3 under 5% H2 flow, methanol was produced with highest selectivity, which is significant because methanol can be reused as a reactant in biodiesel transesterification.

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