• Title/Summary/Keyword: Pyrolysis-oil

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Study on Pyrolysis Characteristics for Upgrading of Bitumen-Like Heavy Oil Contained in Indonesian Resources (인도네시아산 자원 내에 포함된 역청성 오일의 경질화를 위한 열분해 특성에 관한 연구)

  • Jang, Jung Hee;Han, Gi Bo;Park, Cheon-kyu;Jeon, Cheol-Hwan;Kim, Jae-Kon;Kwak, Hyun
    • Clean Technology
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    • v.22 no.4
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    • pp.292-298
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    • 2016
  • In this study, the pyrolysis process was carried out in order to upgrade of heavy oil contained in the resources from Indonesia. In order to investigate the composition and basic properties of the heavy oil contained in the resources, the various analytical methods was used and then the TGA (thermogravimetric) method was especially used for the thermal degradation characteristics of heavy oil in the pyrolysis. From the results obtained from the various analytical methods, the reaction conditions such as the reaction temperature was collected for the pyrolysis process and the pyrolysis using the resources containing the heavy oil was conducted using the fixed-bed reactor under the various reaction conditions. Consequently, We found that the content of heavy oil contained in the resources was about 35% and the conversion of heavy oil and the recovery efficiency of thermal degradation oil were about 21 and 80%, respectively.

Effects of Reaction Conditions on the Performance of Catalytic Pyrolysis of LDPE in a Semi-Batch Reactor (LDPE 반회분식 촉매열분해에서 조업조건이 반응 특성에 미치는 영향)

  • Na, Jeong-Geol;Leem, Chel-Hyen;Choi, Hwi-Kyoung;Chung, Soo-Hyun
    • 한국신재생에너지학회:학술대회논문집
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    • 2006.11a
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    • pp.79-82
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    • 2006
  • Fueled by ballooning oil prices, waste plastics are now regarded as being cheap and abundant renewable sources, removing their stigma of dirty wastes Catalytic pryolysis of plastics in liquid phase allows recovery of light fuel oil as well as green treatment of polymerics wastes, and therefore significant efforts have been devoted to this research field. In this study, catalytic Pyrolysis of LDPE was carl ied out in semi-batch reactor which equipped a unit of separation and recirculation. The effect of react ion conditions were examined by analyzing liquid oil yield and carbon number distribution of products

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Performance Analysis of a Vacuum Pyrolysis System

  • Ju, Young Min;Oh, Kwang Cheol;Lee, Kang Yol;Kim, Dae Hyun
    • Journal of Biosystems Engineering
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    • v.43 no.1
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    • pp.14-20
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    • 2018
  • Purpose: The purpose of this study was to investigate the performance of a vacuum pyrolysis system, to analyze bio-oil characteristics, and to examine the applicability for farm-scale capacity. Methods: The biomass was pyrolyzed at 450, 480, and $490^{\circ}C$ on an electric heat plate in a vacuum reactor. The waste heat from the heat exchanger of the reactor was recycled to evaporate water from the bio-oil. The chemical composition of the bio-oil was analyzed by gas chromatography-mass spectrometry (GC-MS). Results: According to the analysis, the moisture content (MC) in the bio-oil was approximately 9%, the high heating value (HHV) was approximately 26 MJ/kg, and 29 compounds were identified. These 29 compounds consisted of six series of carbohydrates, 17 series of lignins, and six series of resins. Conclusions: Owing to low water content and the oxygen content, the HHV of the bio-oil produced from the vacuum reactor was higher by about 6 MJ/kg than that of the bio-oil produced from a fluidized bed reactor.

Properties of Products from Slow Pyrolysis of Geodae-Uksae 1 (거대억새의 저속 열분해 생성물 특성 분석)

  • Lee, Yongwoon;Eum, Pu-Reun-Byul;Jung, Jinho;Hyun, Seunghun;Park, Yong-Kwon;Ryu, Changkook
    • 한국연소학회:학술대회논문집
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    • 2012.04a
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    • pp.235-237
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    • 2012
  • Geodae-Uksae 1 is a variety of Miscanthus sacchariflorus recently discovered in Korea. It is being mass-cultivated for use as energy crop due to its superior productivity, as high as 30 ton/ha/yr for the dry mass. This study investigates the method of producing biochar and bio-oil from the crop using slow pyrolysis. Especially, the study focused on assessing the biochar properties for its application to soil to improve soil quality and sequestrate carbon. Using an electrically heated packed bed reactor, the products of slow pyrolysis from Geodae-Uksae 1 were produced over a temperature range of $300-700^{\circ}C$ with a heating rate of $10^{\circ}C/min$. The biochar, condensable vapor (bio-oil) and residual gases were characterized for the physical and chemical properties. It was concluded that the ideal temperature for pyrolysis to produce biochar is $500^{\circ}C$.

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A Study of Microwave Waste Tire Pyrolysis in a Batch Reactor (회분식 반응기에서의 마이크로파 폐타이어 열분해 연구)

  • KIM, SEONG-SOO
    • Journal of Hydrogen and New Energy
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    • v.28 no.5
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    • pp.577-583
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    • 2017
  • A series of microwave waste tire pyrolysis experiments were conducted using a lab-scale batch reactor to delineate the effects of microwave ouput power on the pyrolysis behavior of waste tire. As results of experiments, it was found that as the microwave output power was increased from 1.22 kW/kg to 2.26 kW/kg, the reaction temperature and oil yield increased significantly and the required time and microwave power consumption decreased remarkably, respectively. With increased power consumption, the content of the fixed carbon of pyrolysis residue increased.

Preparation of Porous Graphite Using Magadiite Template (Magadiite 주형을 이용한 다공성 흑연의 합성)

  • Choi, Seok-Hyon;Jeong, Soon-Yong;Kim, Jin-Young;Kwon, Oh-Yun
    • Applied Chemistry for Engineering
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    • v.16 no.4
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    • pp.576-580
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    • 2005
  • Porous graphite was prepared by elimination of the template after pyrolysis of PFO (pyrolized fuel oil) with catalyst Cobalt(II)-ethylhexanoate in interlayer space of magadiite template. Pyrolysis was conducted for 3~24 h at $900{\sim}1100^{\circ}C$. Graphite was well crystallized with increased pyrolysis time and temperature. Specific surface area was $261{\sim}400m^2/g$ depending upon mixing ratios, pyrolysis temperature, and pyrolysis time.

Effect of the Recycling of Non-condensable Gases on the Process of Fast Pyrolysis for Palm Wastes (미응축가스 재순환에 따른 팜 부산물 급속열분해 반응 공정 특성)

  • Oh, Changho;Lee, Jang Hoon
    • Clean Technology
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    • v.24 no.3
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    • pp.233-238
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    • 2018
  • Bio-oil is produced by the fast quenching of hot vapor produced by fast pyrolysis of biomass in an inert atmosphere. Nitrogen is used as carrier gas to control the concentration of oxygen less than 3%. The consumption of nitrogen should be increased with increasing process size, and leading to increasing of facility and operating costs due to nitrogen charge. The effects of the recycling of non-condensable gases on the fast pyrolysis, bio-oil yield and quality, and nitrogen consumption have systematically investigated to see the possibility of these results in fast pyrolysis process of palm residue.

New Technology Development for Production of Alternative Fuel Oil from Thermal Degradation of Plastic Waste (폐플라스틱의 열분해에 의한 대체 오일 생산의 신기술 개발)

  • Lee Kyong-Hwan;Roh Nam-Sun;Shin Dae-Hyun
    • Resources Recycling
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    • v.15 no.1 s.69
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    • pp.37-45
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    • 2006
  • For treating a huge amount of plastic waste with the environment problem, pyrolysis of plastic waste into alternative fuel oil is one or important issue in recycling methods. This study was introduced over the trend or generation of plastic waste, in Korea pyrolysis technology in domestic and foreign countries, basic technology in pyrolysis process and new technology of pyrolysis developed in KIER (Korea Institute of Energy research). The characteristics of process developed in KIER are the continuous loading treatment or mixed plastic waste with an automatic control system, the minimization of wax production by circulation pyrolysis system in non-catalytic reactor, the reuse of gas produced and the oil recovery from sludge generated in pyrolysis plant, which have greatly the advantage economically and environmetally. The experiment result data in 300 ton/yr pilot plant showed about $81\;wt\%$ liquid yield for 3 days continuous reaction time, and also the boiling point distribution of light oil (LO) and heavy oil (HO) produced in distillation tower was a little higher than that of commercial gasoline and diesel, respectively.

New Technology Development for Production of Alternative Fuel Oil from Thermal Degradation of Plastic Waste (폐플라스틱의 열분해에 의한 대체 오일 생산의 신기술 개발)

  • Lee, Kyong-Hwan;Roh, Nam-Sun;Shin, Dae-Hyun
    • Proceedings of the Korean Institute of Resources Recycling Conference
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    • 2005.10a
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    • pp.34-46
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    • 2005
  • For treating a huge amount of plastic waste with the environment problem, pyrolysis of plastic waste into alternative fuel oil is one of important issue in recycling methods. This study was introduced over the trend of generation of plastic waste, pyrolysis technology in domestic and foreign countries, basic technology in pyrolysis process and new technology of pyrolysis developed in KIER (Korea Institute of Energy Research). The characteristics of process developed in KIER are the continuous loading treatment of mixed plastic waste with an automatic control system, the minimization of wax production by circulation pyrolysis system in non-catalytic reactor, the reuse of gas produced and the oil recovery from sludge generated in pyrolysis plant, which have greatly the advantage economically and environmetally. The experiment result data in 300 ton/yr pilot plant showed about 81 wt% liquid yield for 3 days continuous reaction time, and also the boiling point distribution of light oil (LO) and heavy oil (HO) produced in distillation tower was a little higher than that of commercial gasoline and diesel, respectively.

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The Effect of Biomass Torrefaction on the Catalytic Pyrolysis of Korean Cork Oak (굴참나무 촉매열분해에 바이오매스 반탄화가 미치는 영향)

  • Lee, Ji Young;Lee, Hyung Won;Kim, Young-Min;Park, Young-Kwon
    • Applied Chemistry for Engineering
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    • v.29 no.3
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    • pp.350-355
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    • 2018
  • In this study, the effect of biomass torrefaction on the thermal and catalytic pyrolysis of cork oak was investigated. The thermal and catalytic pyrolysis behavior of cork oak (CO) and torrefied CO (TCO) were evaluated by comparing their thermogravimetric (TG) analysis results and product distributions of bio-oils obtained from the fast pyrolysis using a fixed bed reactor. TG and differential TG (DTG) curves of CO and TCO revealed that the elimination amount of hemicellulose in CO increased by applying the higher torrefaction temperature and longer torrefaction time. CO torrefaction also decreased the oil yield but increased that of solid char during the pyrolysis because the contents of cellulose and lignin in CO increased due to the elimination of hemicellulose during torrefaction. Selectivities of the levoglucosan and phenolics in TCO pyrolysis oil were higher than those in CO pyrolysis oil. The content of aromatic hydrocarbons in bio-oil increased by applying the catalytic pyrolysis of CO and TCO over HZSM-5 ($SiO_2/Al_2O_3=30$). Compared to CO, TCO showed the higher efficiency on the formation of aromatic hydrocarbons via the catalytic pyrolysis over HZSM-5 and the efficiency was maximized by applying the higher torrefaction and catalytic pyrolysis reaction temperatures of 280 and $600^{\circ}C$, respectively.