Potential of hydrogen production in-situ catalytic absorption gasification system

Abrar I., . and Mohamad Taufiq A., . and Calvin C., . and Mas Fatiha M., . and Zakir K., . and Anita R., . and Suzana Y., . and Murni Melati A., . and Sharifah Shahidah A., . (2014) Potential of hydrogen production in-situ catalytic absorption gasification system. [Proceedings Paper]

The demand for sustainable process is increasing to support the commitment to reduce pollutant gases in the atmosphere. Current gasoline and gas production from fossil fuels are not sustainable since these sources are non-renewable and the combustion of these fuels will lead to the emissions of pollutant gases. Various alternatives of renewable energies and technologies have emerged to counteract the alarming global warming problem and also the scarcity of our primary sources of energy. One of these alternatives is through the production of renewable fuels from agricultural sources such as hydrogen H2 from biomass. This paper highlights the conversion of biomass to H2 via catalytic gasification process. Twelve types of biomass have been characterized and pre-treated. Palm kernel shell PKS is found to be the most suitable biomass for the gasification process. In addition the research also covers the development of catalyst to effectively elevate the H2 production and reduces tar formation. The catalytic activity of the monometallic and bimetallic catalysts has been performed in a high-throughput micro reactor HTMR system. It is found that both monometallic and bimetallic catalysts show favourable performances to produce H2 in a range of 68-70 vol via steam gasification ofPKS. The pilot biomass gasifier system consists of a fluidized bed gasifier a biomass feeding systems gas cleaning unit that consists of a high temperature micro filter guard bed reactor and tar cracker to remove dust and reduce tar sulfur and metals content. The highest H2 composition achieved is 82.1 vol . Based on the results palm kernel shell can be a valuable feedstock for H2 production via catalytic steam gasification.

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Abstract

The demand for sustainable process is increasing to support the commitment to reduce pollutant gases in the atmosphere. Current gasoline and gas production from fossil fuels are not sustainable since these sources are non-renewable and the combustion of these fuels will lead to the emissions of pollutant gases. Various alternatives of renewable energies and technologies have emerged to counteract the alarming global warming problem and also the scarcity of our primary sources of energy. One of these alternatives is through the production of renewable fuels from agricultural sources such as hydrogen H2 from biomass. This paper highlights the conversion of biomass to H2 via catalytic gasification process. Twelve types of biomass have been characterized and pre-treated. Palm kernel shell PKS is found to be the most suitable biomass for the gasification process. In addition the research also covers the development of catalyst to effectively elevate the H2 production and reduces tar formation. The catalytic activity of the monometallic and bimetallic catalysts has been performed in a high-throughput micro reactor HTMR system. It is found that both monometallic and bimetallic catalysts show favourable performances to produce H2 in a range of 68-70 vol via steam gasification ofPKS. The pilot biomass gasifier system consists of a fluidized bed gasifier a biomass feeding systems gas cleaning unit that consists of a high temperature micro filter guard bed reactor and tar cracker to remove dust and reduce tar sulfur and metals content. The highest H2 composition achieved is 82.1 vol . Based on the results palm kernel shell can be a valuable feedstock for H2 production via catalytic steam gasification.

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Item Type:	Proceedings Paper
Additional Information:	Available at Perpustakaan Sultan Abdul Samad Universiti Putra Malaysia 43400 UPM Serdang Selangor Malaysia TP339 B615 Call Number
AGROVOC Term:	Hydrogen
AGROVOC Term:	Catalytic activity
AGROVOC Term:	Biomass
AGROVOC Term:	Gasification
AGROVOC Term:	Adsorption
AGROVOC Term:	Atmospheric pollution
AGROVOC Term:	Fuels
AGROVOC Term:	Global warming
AGROVOC Term:	Energy
AGROVOC Term:	Palm kernels
Geographical Term:	MALAYSIA
Depositing User:	Ms. Suzila Mohamad Kasim
Last Modified:	24 Apr 2025 05:14
URI:	http://webagris.upm.edu.my/id/eprint/12100

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