Catalytic dehydration of Bio-ethanol to hydrocarbons : oxides of P, Sb, and Bi

Abstract

HZSM-5 has been known as a potential catalyst for the dehydration of ethanol to gasoline (ETG) because of its acid property and shape selectivity. Moreover, HZSM-5 had been used as the support of phosphorus oxide, antimony oxide, and bismuth oxide for ethanol dehydration, which resulted mainly in the production of oil in the gasoline range. It can be noticed that the moderate pore size of HZSM-5 limits the production of heavier oils in the kerosene and gas oil ranges. Therefore, in this work, the large pore size zeolites, HY and HBeta, were expected to produce larger hydrocarbon molecules. Then, bio-ethanol dehydration using HY and HBeta doped with P-, Sb-, and Bi- oxides was investigated, aiming to improve the production of valuable and distillate-range products. Moreover, channel structure is one of parameters that can affect to the product distribution. HZSM-11, which has straight pore channel structure, was investigated in order to compare with a zigzag channel structure of HZSM-5 in ethanol dehydration. As a result, large petroleum cuts tend to be produced by HY, and HBeta; but the contents were also limited by some factors such as channel structure, cage size, and contact time. Moderate pore size zeolite (HZSM-5) tends to have the highest activity by giving a large content of oil, C9 and C10+ aromatics. P-, Sb-, and Bi- oxide supported HZSM-5, HBeta, and HY helped to yield more kerosene and gas oil with the decrease in gasoline, related to the increase of C10+ aromatic products. In addition, HZSM-11 showed the less activity than HZSM-5 by producing the lower oil contents. The use of P-, Sb-, and Bi- oxide modified HZSM-11 did not improve oil yields significantly; on the other hand, C6-C8 were increased in conjunction with the decreases in C9 and C10+ aromatics products.