폴리설폰 한외여과막 분리막공정을 이용하여 투과유속 상에서의 오존의 효과를 고찰하였다. 처음에는 조제한 페놀용액을 이용해 오존의 농도 10-45 mg/l·min을 가한 후에 분리막내에 막오염 제거를 목적으로 시도하였으며 이후에는 오존과 분리막이 혼합된 연속공정에서 폐수처리를 위해 오존에 의한 통일효과를 고찰하기 위해 시도하였다. 전처리 방법으로는 펜톤 산화법을 이용하여 화학응집을 시도하였고 그 결과 폐수내 용존유기물 제거에 효과가 있는 것으로 나타났다. 실험결과 오존을 이용하게 되면 투과유속이 10% 이상 증가한다는 사실이 조제수와 폐수에 공히 같게 나타났으며 오존과 과산화수소를 이용한 고도처리에서도 투과유속증가에 더욱 효과적이었다. 특히 오존을 이용한 처리수에서는 투과압력이 12% 이상 낮아지는 효과가 나타났으며 분리막 공정에 오존처리는 막오염을 거의 제거하기보다는 막오염을 제한적으로 막는 효과를 얻었다.
기체 막분리공정 기술이 점점 개발되어질수록 막분리의 성능을 이해하려는 필요성이 각 공정에서 증진될 것이며 기체 막분리 성능의 예측능 기술 발전을 위해 계속 시도되어질 것이다. 이러한 추세에 힘입어 현재 석유화학공정 배가스 중 수소를 정제하기 위한 기술 개발을 시도하고 있으며 특히 저농도의 수소를 고농도로 농축시키기 위해 막분리 공정을 적극 검토하고 있다. 본 논문에서 밝혀 본 막분리 공정의 성능 예측과 분석은 향후 공정을 설계하고 제작하는 데 크게 이바지할 뿐만 아니라 석유화학 제반 공정뿐만 아니라 관련 화학공업장치 산업에서 기체 분리를 통한 자원회수와 에너지 절약 측면에서 계속 발전해 나갈 것은 믿어 의심치 않을 것이다.
본 논문에서는 막오염을 일으키는 현상과 원인들을 나름대로 규명하기 위해 고찰 하였고, 이러한 규명은 막오염층 성장모델과 막오염층의 성장요인이 되는 흡착과 대류속도 등으로 나누어서 고찰하였다. 이러한 문제의 근본적인 이해는 막오염의 기초적 이론 지식이 이해되었을 때 막공정의 개발이 향상될 수 있으며 막오염은 농도 분극현상서부터 흡착, 막세공 막힘에 이르기까지 일련의 과정들이 분리돼서 이해될 수 없는 서로의 긴밀하 관계가 유지되므로 종합적인 기초 지식의 열거가 필오하다.
In order to make the best biogas production in the anaerobic fermentation, it is important to be able to compare the raw input materials on the basis of their sustainability, which may include a variety of environmental indicators. This study examined the comparative sustainability of renewable technologies in terms of their life cycle CO2 emissions and embodied energy, using life cycle analysis. The comparative results showed that power generation of bioenergy was associated with 0.96 kWh/m³ biogas and the reduction of CO2 emission is 2.1kg of CO2/kg Biomass. Other environmental indicators should be applied to gain a complete picture of the technologies studied. The generation of electricity is 2.07 kWh/m³ biogas in comparison with theoretical results of 3.09 kWh/m³ (efficiency of generator is 30%) based on the assumption of the removal efficiency 95% of CO2, methane conversion 100%, efficiency of generator 30%. Final results are the production of methane: 250 m³/day, production of electricity: 770kWh/day when used 5 m³/day of waste.
Biogas is a gaseous mixture produced from microbial digestion of organic materials in the absence of oxygen. Raw biogas, depending upon organic materials, digestion time and process conditions, contains about 45-75% methane, 30-50% carbon dioxide, 0.3% of hydrogen sulfide gas and fraction of water vapor. Pure methane has a caloric value of 34,400 kJ/m³, but the lower heating value of raw biogas changes between 13,720 and 27,440 kJ/m³. To achieve the standard composition of the biogas the treatment techniques like absorption must be applied. In this paper the experimental results of the methane purification in simulated biogas mixture consisted of methane, carbon dioxide and hydrogen sulfide were presented. The air-lift reactor is performed with MEA in order to increase the simultaneous purification for the gaseous mixtures of CO2 and H2S which are main components of the biogas. The effects of feed pressures and mixed gas on the separation of CO2-CH4 by membrane are investigated. It was shown that it was possible to achieve the purification of methane from the concentration of 55% up to 99%. The flow cell reactor was used to measure the reaction rate constant and to determine the optimal conditions of process for improving process efficiency.
Several experiments have done to investigate the removal of hydrogen sulfide (H2S) synthetic gas from biogas streams by means of chemical absorption and chemical reaction with 0.1M - 1M Fe/EDTA solution. The hydrogen sulfide of biogas was bubbled through an gas-lift column with Fe/EDTA resulting in the formation of sulfur particles. Wide range of optimal operating conditions were tested for both Fe/EDTA solution and the biogas, and the optimal ratio of Fe/EDTA concentration for efficient removal of hydrogen sulfide was found. The roles of Fe/EDTA were studied to enhance the removal efficiency of hydrogen sulfide because of oxidizing by Fe+3/EDTA. The motivation of this investigation is first to explore the feasibility of enhancing the toxic gas treatment in the biogas facility. The biogas purification strategy affords many advantages. For instance, the process can be performed under mild environmental conditions and at low temperature, and it removes hydrogen sulfide selectively. The end product of separation is elemental sulfur, which is a stable material that can be easily disposed of with minor potential for further pollution. The process to address over 90% removal efficiency of hydrogen sulfide does offer considerable advantages unrealized.
In order to make the best biogas production in the anaerobic fermentation, it is important to be able to compare the raw input materials on the basis of their sustainability, which may include a variety of environmental indicators. This study examined the comparative sustainability of renewable technologies in terms of their life cycle CO2 emissions and embodied energy, using life cycle analysis. The comparative results showed that power generation of bioenergy was associated with 0.96 kWh/m³ biogas and the reduction of CO2 emission is 2.1kg of CO2/kg Biomass. Other environmental indicators should be applied to gain a complete picture of the technologies studied. The generation of electricity is 2.07 kWh/m³ biogas in comparison with theoretical results of 3.09 kWh/m³ (efficiency of generator is 30%) based on the assumption of the removal efficiency 95% of CO2, methane conversion 100%, efficiency of generator 30%. Final results are the production of methane: 250 m³/day, production of electricity: 770kWh/day when used 5m³/day of waste.
This paper reports on the experimental investigation carried out to evaluate the physical optimal conditions in the absorption column to remove odorous hydrogen sulfide gas. Hydrogen sulfide gas, as a highly undesirable contaminant, is most widely emitted from environmental treatment facilities. The absorbent mixed with natural second metabolites extracted from conifer trees and chemical absorbent of 2-aminoethanol was applied to remove it via chemical neutralization. The absorbent of natural second metabolites was achieved by a removal efficiency of 20 - 40% by itself depending on the treatment conditions, but the complex absorbent mixed with 0.1% amine chemical provides the removal efficiency of 98%. The optimal removal efficiencies have been examined against the two major parameters of temperature and pH. This study shows that the aqueous solution by natural second metabolites can be used as an appropriate absorbent in the column absorbed for the removal of hydrogen sulfide gas. Young G.