• Title/Summary/Keyword: Clean petrochemistry

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Diesel Desulfurization Reactor Design for Fuel Cell by Computational Fluid Dynamics (CFD 모델링을 통한 연료전지용 디젤의 흡착탈황 반응기 디자인)

  • Kwon, Sang Gu;Liu, Jay;Im, Do Jin
    • Clean Technology
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    • v.21 no.4
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    • pp.229-234
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    • 2015
  • Recently, there are increasing numbers of study regarding hydrogen fuels but researches on desulfurization of diesel are rare. In this study, we performed diesel desulfurization reactor design by computation fluid dynamics simulation. By analyzing the change in flow and sulfur concentration at the outlet according to the changes in flow rate, reactor length, and reactor diameter, we have found the minimum catalyst performance for the given flow rate condition and the relation between the reactor performance and the reactor size and shape. We also studied the effects of permeability of the packed bed on the flow and sulfur concentration distribution. The present work can be utilized to design a diesel desulfurization reactor for a fuel cell used in ships. Furthermore, the present work also can be used to design low sulfur diesel supply in oil refineries and therefore contribute to the development of clean petrochemical technology.

Numerical Simulation of Catalyst Regeneration Process for Desulfurization Reactor (수치해석을 통한 탈황반응기용 촉매의 재생공정 분석)

  • Choi, Chang Yong;Kwon, Sang Gu;Liu, Jay;Im, Do Jin
    • Clean Technology
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    • v.23 no.2
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    • pp.140-147
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    • 2017
  • In this study, we performed numerical simulation for the catalyst regeneration process of diesel desulfurization reactor. We analyzed the changes in regeneration process according to purge gas flow rate, catalyst permeability, reactor size, and heat loss of reactor. We have found that the regeneration process is very much affected by temperature changes whereas it is hardly affected by catalyst permeability and porosity. We also estimated the regeneration time according to purge gas flow rate and initial temperatures and have found that increasing purge gas temperature is more effect for fast regeneration. The present results can be utilized to design a regeneration process of diesel desulfurization reactor for a fuel cell used in ships. Furthermore, the present work also can be used to design low sulfur diesel supply in oil refineries and therefore contribute to the development of clean petrochemical technology.

The Manufacture of Absorbents and Removal Characteristics of VOCs by Essential Oil and Photocatalyst (식물정유와 광촉매를 이용한 흡수제 제조 및 VOCs 제거특성에 관한 연구)

  • Jeong, Hae-Eun;Yang, Kyeong-Soon;Kang, Min-Kyoung;Cho, Joon-Hyung;Oh, Kwang-Joong
    • Clean Technology
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    • v.23 no.1
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    • pp.54-63
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    • 2017
  • Volatile organic compounds (VOCs) are widely used in both industrial and domestic activities. VOCs are one of the most unpleasant, frequently complaint-rousing factors of pollution around the world. It is now necessary to research and develop an alternative technology that could overcome the problems of the existing odor-control and VOC-eliminating techniques. In this study, essential oil and photocatalytic process was applied in the removal of benzene and toluene, typical VOCs in petrochemistry plant. therefore, this study conducted experiments on the selection of appropriate essential oil, photodegradation, hydroxyl radical generation capacity. The removal efficiency and reaction rate were performed to selecte the type and concentration of essential oil. As a result, removal efficiency of Hinoki Cypress oil was approximately 70% and reaction rate of Hinoki Cypress was high. The results of photolysis experiment, photocatalytic oxidation process showed that the decomposition efficiency of VOCs increased considerably with increasing UV lamp power. In addition, the conversion of VOCs was increased up to $0.1gL^{-1}$ photocatalysts. The hydroxyl radicals measure was performed to determine the ability to generate hydroxyl radicals. The analytical result showed that high $TiO_2$ concentration and lamp power was produced many hydroxyl radical. Experiments of the removal efficiency and reaction rate were performed using essential oil and photooxidation. As a result, the removal efficiency showed that the removal efficiency was increased high temperature and reaction time. The activation energy was calculated from the reaction rate equation at various temperature condition. Activation energy was approximately $18kJmol^{-1}$.