• Title/Summary/Keyword: Oil degradation

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Degradation of BTX by Klebsiella gr. 47 in the Biological Wastewater Treatment (Klebsiella gr. 47을 이용한 생물학적 폐수처리에서 BTX 분해 특성)

  • 염승호;최석순
    • Journal of Environmental Science International
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    • v.7 no.3
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    • pp.393-400
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    • 1998
  • A microorganism, Klebsiella gr. 47, capable of degrading BTX(benzene, toluene and xylene) was isolated from oil-contaminated soil and its characteristics of BTX degradation were investigated. When benzene and toluene were fed to Klebstella gr. 47 simulataneously, they showed competitive ingibition. The degradation rate of xylene was enhanced as much as 3 times when xylene was fed with benzene or toluene. Degradation rate of benzene and toluene was also enhanced by cocultured with Alcaligenes xylosoxidans. When benzene-adapted microorganism was used, each BTX compound was degraded efficiently within 5 hours.

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Bioremediation of Crude Oil by White Rot Fungi Polyporus sp. S133

  • Kristanti, Risky Ayu;Hadibarata, Tony;Toyama, Tadashi;Tanaka, Yasuhiro;Mori, Kazuhiro
    • Journal of Microbiology and Biotechnology
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    • v.21 no.9
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    • pp.995-1000
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    • 2011
  • The bioremediation potential of crude oil by Polyporus sp. S133 pre-grown in wood meal was investigated in two separate experiment trials; liquid medium and soil. The effect of three nutrients (glucose, polypeptone, and wood meal), oxygen flow, and some absorbent on the efficiency of the process was also evaluated. Degradation of crude oil in soil was significantly increased with an addition of oxygen flow and some absorbent (kapok and pulp). The highest degradation rate of crude oil was 93% in the soil with an addition of 10% kapok. The present study clearly demonstrates that, if suitably developed, Polyporus sp. S133 could be used to remediate soil contaminated with crude oil.

Effects of Bioremediation Products on the Oil Degradability (생물정화용 제품의 유류분해능 비교)

  • 김상진;신수경
    • Korean Journal of Microbiology
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    • v.33 no.2
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    • pp.157-162
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    • 1997
  • Recently the bioremediation technology has been widely used to recover the oil contaminated environments The application of bioremediation agents to oil polluted environments became common and thus many kinds of commercial products were imported into domestic market. In Korea, howcver. the standardization of bioremediation products quality is not yet established and results of efficacy test .ire scarce. In this study five oil spill bioremediation commercial products including microbial inoculants and en'cyme agents are tested for the oil degradation rate. From the results most products shows the strong oil emulsifying phenomena due to the contained chemical oil dispersant and the low oil degradation rate. Product D inhibited the oil degradability of microorganisms even in the natural sea water. From these results it could be concluded that in the near future the laboratory protocol and standardization of products quality for bioremediarion agents should be prepared to activate the effective application of bioremediation technology in Korea.

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An Assessment of the Feasibility of (I) : Condition of Aerobic (MTBE를 포함한 기타 가솔린 첨가제의 생 분해 적용 가능성 평가(I) : 호기성 조건)

  • Chung, Woo-jin;Chang, Soon-woong
    • Journal of Environmental Science International
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    • v.25 no.6
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    • pp.757-766
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    • 2016
  • MTBE and other gasoline additives contained in gasoline are known to be a refractory substance resistant to biodegradation. As a method of removing these substances, a research of method using native microbes of polluted soil was progressed and among these, bio-degradation possibility under aerobic condition was evaluated. All of the experiments were progressed based on batch experiment of lab scale and analyzed by GC-FID using HS-SPME technique. The result of bio-degradation experiment based on MTBE and other additives(ETBE, TAME) was observed below 1 mg/L, which initial concentration were 100 mg/L for each method. And through production of by-product and CO2, partial mineralization was confirmed. Degradation velocity of each additive was promptly represented in the order of TBA>ETBE>MTBE>TAME. Through this study, bio-degradation possibility of native microbes of oil polluted soil, MTBE and other gasoline additives was confirmed and it was considered that the result could be used for basic experiment data in removing oil pollutants of soil.

Evaluation of Bioremediation Efficiency of Crude Oil Degrading Microorganisms Depending on Temperature (온도에 따른 원유분해미생물의 생물학적 정화효율 평가)

  • Kim, Jong-Sung;Lee, In;Jeong, Tae-Yang;Oh, Seung-Taek;Kim, Guk-Jin
    • Journal of Soil and Groundwater Environment
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    • v.21 no.1
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    • pp.72-79
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    • 2016
  • Bioremediation is one of the most effective ways to remediate TPH-contaminated sites. However, under actual field conditions that are not at the optimum temperature, degradation of microorganisms is generally reduced, which is why the efficiency of biodegradation is known to be significantly affected by the soil temperature. Therefore, in this study, the labscale experiment was conducted using indigenous crude oil degrading microorganisms isolated from crude oil contaminated site to evaluate the remediation efficiency. Crude oil degrading microorganisms were isolated from crude oil contaminated soil and temperature, which is a significant factor affecting the remediation efficiency of land farming, was adjusted to evaluate the microbial crude oil degrading ability, degradation time, and remediation efficiency. In order to assess the field applicability, the remediation efficiency was evaluated using crude oil contaminated soil (average TPH concentration of 10,000 mg/kg or more) from the OO premises. Followed by the application of microorganisms at 30℃, the bioremediation process reduced its initial TPH concentration of 10,812 mg/kg down to 1,890 mg/kg in 56 days, which was about an 83% remediation efficiency. By analyzing the correlation among the total number of cells, the number of effective cells, and TPH concentration, it was found that the number of effective microorganisms drastically increased during the period from 10 to 20 days while there was a sharp decrease in TPH concentration. Therefore, we confirmed the applicability of land farming with isolated microorganisms consortium to crude oil contaminated site, which is also expected to be applicable to bioremediation of other recalcitrant materials.

EFFECTS OF BLOOD-MIXED AND HEAT TREATMENT OF PROTEIN FEEDS ON NITROGEN DIGESTION IN THE RUMEN AND HINDGUT OF SHEEP

  • Yoon, C.S.;Lee, N.H.;Jung, K.K.
    • Asian-Australasian Journal of Animal Sciences
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    • v.3 no.1
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    • pp.39-46
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    • 1990
  • This experiment was conducted to study the effects of blood-mixed and heat-treated protein feeds on protein degradation in the rumen, flow of protein to the abomasums and availability of undegraded protein in the intestine of sheep in a $4{\times}4$ Latin square design. Soybean oil meal, rapeseed meal, and whole soybean were mixed with fresh swine blood and dried at $140^{\circ}C$ for 2 h. Proportionate disappearance of apparently digested OM in the postrumen for the blood and heat treated protein group was ranged from 43.2 to 50.5% as compared with 28.0% for the unheated soybean oil meal diet. The treated protein supplements were resulted in greater total N and NAN flow passing at the abomasums than untreated soybean oil meal diet was fed. The quantities of undegraded feed N passing at the abomasums for the treated protein diets was approximately twice as high as that of the untreated soybean oil meal diet and the estimated amount of undegraded N of the protein supplement itself was 79.1 to 84.2% as compared with 15% of soybean oil meal.

Characterisrics of Dissolved Gas Distribution in Oil with Thermal and Electrical Degradation in Oil Imersed Paper Insulation (유침 절연에서 전기적 및 열적 열화에 따른 유중가스분포특성)

  • Sun, Jong-Ho;Yi, Sang-Hwa;Kim, Kwang-Hwa
    • Journal of the Korean Institute of Illuminating and Electrical Installation Engineers
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    • v.18 no.6
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    • pp.136-144
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    • 2004
  • Dissolved gas in oil analysis has been used for fault diagnosis of oil immersed insulation. In this paper to improve the reliability in deciding the degradation causes of the oil immersed insulation, we carried out electrical and thermal degradations for the insulations, and analyzed the characteristics of dissolved gases distribution on each situation. As a result more reliable faults discrimination is possible if we use the interrelation of factors like key gases and gas compositions of hydrocarbon gases and ratios of CO/$CO_2$.

Phytoremediation potential of indigenous Ghanaian grass and grass-like species grown on used motor oil contaminated soils

  • Akutam, Abednego;Pappoe, Alexander Nii Moi;Armah, Frederick Ato;Enu-Kwesi, Lewis
    • Journal of Ecology and Environment
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    • v.37 no.2
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    • pp.41-51
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    • 2014
  • This study investigated the ability of Bothriochloa bladhii (Retz.) S.T. Blake (Poaceae), Cyperus ligularis L. (Cyperaceae), Commelina erecta L. (Commelinaceae), Mariscus umbellatus (Rottb.) Vahl (Cyperaceae), Fimbistylis miliacea L. (Cyperaceae) and Torulinium odoratum L. (Cyperaceae) to clean up various levels of used motor oil (UMO) contaminated soils. The plants were grown in 2 kg garden soils treated to 0%, 1%, 5% and 10% levels of UMO contamination. The plant growth parameters, chlorophyll contents and dry weight of test plants were measured. The phytoremediation ability of these test plants were assessed by measuring the uptake of hydrocarbons in terms of total hydrocarbon content (THC) as well as their percentage degradation values. There was significant (P < 0.05) reduction in leaf chlorophyll contents and dry weights of the test plant species planted in UMO contaminated soils. THC as well as the percentage uptake (or degradation) of hydrocarbons were both lowest in C. ligularis but highest in T. odoratum in all cases. The phytoremediation potential of test plants was highest in soils contaminated with 5% UMO. Based on the results of this study, all test plants with the exception of C. ligularis were potentially capable of undertaking phytoremediation. However, B. bladhii and T. odoratum proved most effective in the uptake and degradation of UMO.

Biodegradation of Diesel Oil by Microorganisms Isolated from Petroleum Contaminated Site (유류 오염지역으로부터 분리된 균주를 이용만 디젤유의 분해)

  • 박천보;허병기;윤현식
    • KSBB Journal
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    • v.16 no.6
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    • pp.632-637
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    • 2001
  • The cells obtained from diesel contaminated site were tested for diesel degradation by culturing them on the culture medium that contained diesel as the only carbon source. Two strains that grew well in the culture media were separated: one formed white colony and another strain formed yellow colony. When they were cultured together, much higher diesel degradation was obtained compares to that of individual cell culture. Mixed culture of white and yellow colony forming strains grew well with 1%(v/v) diesel and the addition of growth nutrients increased the diesel degradation. Additional nitrogen source was efficient for higher diesel degradation (over 90%) when it was compared with that without nitrogen source. When mixed culture of white and yellow colony forming cells were applied to the soil column system contaminated by diesel, 30 mL/min of air flow rate was found to be sufficient to degrade diesel oil. The diesel degradation did not increase noticeably at higher flow rate. The addition of nitrogen source resulted in the increase in diesel degradability.

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Development of Sensing System for an Engine Oil Deterioration Detection Sensor Integrated with an Oil Filter (오일필터 일체형 엔진오일 퇴화감지센서용 센싱시스템 개발)

  • Chun, Sang-Myung
    • Journal of Sensor Science and Technology
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    • v.20 no.4
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    • pp.243-248
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    • 2011
  • The purpose of this study is to develop a sensing system to measure the capacitance of a pre-developed engine oil deterioration detection sensor integrated with an oil filter. To measure the capacitance of engine oil in the sensor, it is used the way measuring the electric charging time in a capacitor by impressing DC volt. This method has merits on cost and signal stability. The measured capacitance is compensated by comparison with the one measured by an impedance analyzer. Also, using the dielectric constant gained by an impedance analyzer, the calculating equation of the dielectric constant of engine oil related with the currently developed sensor is decided. Finally, the degradation degree of engine oil is estimated according to the change rate of dielectric constant between green oil and used oil. The newly developed personal controller is to control a series of the processes.