Due to overconsumption, fossil reserves are rapidly being depleted and various sources predict that they will not last until the end of 21st century. Moreover, the increase in the rate of global warming and the polluting matter emitted by the vehicles consuming fossil fuels has increased the search for renewable and clean energy sources. Alcohols and ethers, which contain fewer pollutants and have better burning properties, are commonly thought among clean fuel alternatives. Among the potential clean energy sources, dimethyl-ether is already in use in the automotive industries of many countries such as China and Japan, due to its low NOx and CO2 emissions, high cetane rating and efficient combustion characteristics, especially in diesel engines.
In this work, dimethyl-ether synthesis is achieved using methanol dehydration reaction over solid acid catalysts. For this purpose, three different mesoporous MCM-41 type aluminum silicates have been synthesized with direct hydrothermal synthesis method and aluminum is added to the synthesized SBA-15 catalyst using impregnation method. Apart from the catalysts synthesized, different commercial catalysts such as aluminum oxide in different forms (& / #945 / and & / #947 / ), Nafion NR-50 and Nafion SAC-13 have also been tested in this reaction. These materials were characterized by methods such as XRD, EDS, SEM, and N2 physical adsorption and DRIFTS were also investigated in terms of paramters such as the conversion of methanol to products, selectivity and yield.
The analyses have shown that AlSi1 is the most active of all the aluminum silicates synthesized in both 0.136 and 0.27 s.g/cm3 space times, with up to 80% methanol conversion in all temperatures tested. AlSi1 also has low by-product formation and similar to other aluminum silicates, its dimethyl-ether selectivity approaches 1 at 4000C. Among all synthesized catalysts, the dimethyl-ether yield was seen to be the highest for Al-SBA-15, which approaches 0.5 at 4000C for both space times. For all aluminum silicates synthesized, about 40% dimethyl-ether yield was obtained at the same temperature and space times. Among the aluminum oxides, & / #945 / -alumina was seen to be superior to others in & / #947 / forms in terms of conversion selectivity and yield, especially at low temperatures. As to Nafion catalysts, due to its much higher surface area and high Bronsted acidity, Nafion SAC-13 has shown higher activity compared to Nafion NR-50 for all temperatures and space times tested.
Identifer | oai:union.ndltd.org:METU/oai:etd.lib.metu.edu.tr:http://etd.lib.metu.edu.tr/upload/3/12609817/index.pdf |
Date | 01 August 2008 |
Creators | Tokay, Kenan Cem |
Contributors | Dogu, Timur |
Publisher | METU |
Source Sets | Middle East Technical Univ. |
Language | English |
Detected Language | English |
Type | M.S. Thesis |
Format | text/pdf |
Rights | To liberate the content for public access |
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