Abstract

Partially hydrogenated fatty acid methyl ester (H-FAME) is conventionally produced through partial hydrogenation under high pressure and elevated temperature in the presence of a catalyst. Herein, a novel green, catalyst-free, non-thermal and atmospheric pressure dielectric barrier discharge (DBD) plasma was employed instead of a conventional method to hydrogenate palm FAME. H-FAME became more saturated with the conversion of C18:2 and C18:3 of 47.4 and 100%, respectively, at 100 W input power, 1 mm gas-filled gap size and 80% H2 in the mixed gas at room temperature for 5 h, causing a reduction of the iodine value from 50.2 to 43.5. Oxidation stability increased from 12.8 to 20 h while a cloud point changed from 13.5 to 16 °C. Interestingly, DBD plasma hydrogenation resulted in no trans-fatty acid formation which provided a positive effect on the cloud point. This green DBD plasma system showed a superior performance to a conventional catalytic reaction. It is an alternative method that is safe from explosion due to the mild operating condition, as well as being highly environmentally friendly by reducing waste and energy utilization from the regeneration process required for a catalytic process. This novel green plasma hydrogenation technique could also be applied to other liquid-based processes.

Highlights

  • Hydrogenated fatty acid methyl ester (H-fatty acid methyl esters (FAMEs)) is conventionally produced through partial hydrogenation under high pressure and elevated temperature in the presence of a catalyst

  • The results revealed that Ni offered desirable results with the increase in oxidation stability of palm FAME from about 4.75 to 10.03 h while the cloud point was not reported

  • The gases used for hydrogenated fatty acid methyl ester (H-FAME) production, ­H2 and He, were of Ultra High Purity (UHP) grade procured from Alternative Chemical Company Ltd., Thailand

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Summary

Introduction

Hydrogenated fatty acid methyl ester (H-FAME) is conventionally produced through partial hydrogenation under high pressure and elevated temperature in the presence of a catalyst.

Results
Conclusion

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