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탈휘발 과정과 촤가스화 과정에서 목질계 바이오매스의 타르발생 특성
문지홍(Jihong Moon),이은도(Uendo Lee),류창국(Changkook Ryu),이영만(Younman Lee),배우근(Wookeun Bae) 한국연소학회 2011 한국연소학회지 Vol.16 No.1
Biomass gasification is a promising technology in terms of clean energy and flexible options for end use such as heat, steam, electricity, gaseous or liquid fuels. In a gasification process, reduction of tar is very important because it can cause any mechanical problems and small tar implies high energy efficiency. However, generation and conversion mechanisms of tar have not been fully understood due to its complex nature. In this study, characteristics of tar generated from different gasification stages were investigated. Korean pine woodchip was used as feedstock and tar was sampled in a separate way during devolatilization and char gasification stage, investigated. As a result, more various kinds of hydro carbon compounds were identified in the devolatilization stage than char gasification stage because primary tar compounds are released mostly from pyrolysis of cellulose and hemicellulose. When the reaction temperature increased up to 900℃, tar composition becomes simplified into about 10 aromatic compounds mostly with 1-4 rings without substitution up to phenanthrene. The sampled tar in the char gasification stage mostly contains 5-7 simple aromatic compounds.
미이용 바이오매스의 이산화탄소 활성화를 통한 바이오카본 생산: 포름알데하이드 및 아세트알데하이드 제거 특성
김종수(JongSu Kim),최석천(SeukCheun Choi),이은도(Uendo Lee),박은석(EunSeuk Park),정수화(Soohwa Jeong) 한국청정기술학회 2021 청정기술 Vol.27 No.4
본 연구에서는 미이용 바이오매스인 3급 목재펠렛 및 커피박을 이용하여 바이오카본을 생산하고 이를 통하여 저분자 극성 휘발성 유기화합물인 포름알데하이드 및 아세트알데하이드 제거 성능 실험을 수행하였다. 바이오카본 생산 실험은 이산화탄소를 활성화제로 사용하여 고정층 반응기에서 수행하였다. 활성화 실험 시 반응온도 900 ℃ 및 이산화탄소 1 L min<SUP>-1</SUP>으로 반응조건을 고정하여 진행하였다. 활성화 실험 결과 1급 목재펠렛으로부터 생산한 바이오카본의 BET 비표면적이 약 788 ㎡ g<SUP>-1</SUP>으로 가장 높음을 알 수 있었고 커피박으로부터 생산한 바이오카본이 약 544 ㎡ g<SUP>-1</SUP>으로 가장 낮게 나타났다. 본 실험을 통해 생산된 바이오카본은 대부분 마이크로 기공을 가진 것으로 나타났다. 바이오매스 원료 내 회분의 함량이 낮을수록 바이오카본의 비표면적이 높아지는 것으로 나타났다. 포름알데하이드 및 아세트알데하이드 제거 실험 결과 1급 및 3급 목재펠렛으로부터 생산한 바이오카본에 비해 커피박으로부터 생산한 바이오카본이 더욱 우수한 흡착 성능을 보여주었다. 추가적으로 상용 첨착 활성탄과 커피박으로부터 생산한 바이오카본의 비교 실험을 진행하였다. 포름알데하이드 제거 성능은 상용 첨착 활성탄이 우수한 반면 아세트알데하이드 제거에는 커피박으로부터 생산한 바이오카본이 우수한 것으로 나타났다. In this study, bio-carbons were produced by activation process from unused biomass (Grade 3 wood pellet and spent coffee grounds) to determine the removal performance of formaldehyde and acetaldehyde. The activation experiments were conducted in a fixed bed reactor using CO₂ as an activation agent. The temperature of the activation reactor and input of CO₂ were 900 ℃ and 1 L min<SUP>-1</SUP> for all the experiments. The maximum BET surface area of about 788 ㎡ g<SUP>-1</SUP> was obtained for bio-carbon produced from Grade 1 wood pellet, whereas about 544 ㎡ g<SUP>-1</SUP> was achieved with bio-carbon produced from spent coffee grounds. In all the experiments, the bio-carbons produced were mainly found to have micro-porous nature. A lower ash amount in raw material was favored for the high surface area of bio-carbons. In the removal test of formaldehyde and acetaldehyde, the bio-carbon produced from spent coffee grounds showed excellent adsorption performance compared with woody biomass (Grade 1 wood pellet and Grade 3 wood pellet). In addition, the comparative experiment of commercial impregnated activated carbon and bio-carbon produced from spent coffee grounds was conducted. In terms of formaldehyde removal performance, the commercial impregnated bio-carbon was excellent, while bio-carbon produced from spent coffee grounds was excellent in acetaldehyde removal.