水環境学会誌 23 巻, 1 号

白色腐朽菌による多環芳香族炭化水素の分解

Approximately 1,000 white rot fungi strains were screened by the ability of degradation of polycyclic aromatic hydrocarbons (PAHs) such as anthracene, pyrene, fluoranthene, benzo [a] pyrene, and dibenzo [a, i] pyrene. Thirty three strains of them had considerably higher degrading ability than the typical white rot fungi, Phanerochaete chrysosporium and Trametes versicolor. Among these strains, two strains showed superior degrading ability and low-specificity in degrading various PAHs. They could degrade PAHs efficiently under nutrient-limited conditions in both liquid phase (low-nitrogen medium) and solid phase (nutrient-poor soil). But those degrading ability was suppressed under nutrient-rich conditions. The purified ligninolytic enzymes such as lignin peroxidase, manganese peroxidase, and laccase could degrade PAHs.

電気分解を利用した糖蜜廃液の脱色処理―糖蜜色素の脱色特性と電解質の種類の影響―

Electrolyte is one of important factors in the electrolysis for decolorization. NaCl was more effective than NaHCO₃ or Na₂SO₄. The decolorization characteristics of melanoidine, caramel and polyphenolic compounds were studied. The decolorization efficiency (DE) of a caramel solution with NaCl was 1,000 to 2,000U · l · kC^-1 although that of a caramel solution decolorized with NaHCO₃ was 30. DE of molasses wastewater from alcohol distillery was the same order as caramel and was different from DE of melanoidine or polyphenolic compounds. The decolorization reaction was mainly occurred on the anode in the experiment separated using a salt bridge. And the effectiveness of NaCl addition was caused by a preferential oxidation against colored compounds and a high efficiency on the oxidation of organic compounds.

有機塩素系溶剤の活性炭吸着―超臨界二酸化炭素抽出処理における減圧, 回収方法

When a chlorinated ethylene solvent such as trichloroethylene (TCE) or tetrachloroethylene (PCE) in aqueous solution is adsorbed on activated carbon and then extracted with supercritical carbon dioxide, unlike steam desorption, the recovered solvent may not contain hydrolyzates or water which lead to problems during recycling. However a solvent with high volatility becomes a problem regarding recovery at low pressure of supercritical carbon dioxide. The recovery of solvent by decompressing and cooling was thus studied. Optimal conditions for extraction were 100kg · cm^-2 pressure at 35°C, and for recovery, 10kg · cm^-2 pressure at -30°C. In the case of TCE, slight dispersion was observed, but carbon dioxide with little dispersed TCE could be compressed and reused for extraction of TCE from activated carbon. For PCE, there was little dispersion. Solvent recovered from activated carbon in aqueous solution contained water. On decompressing the supercritical fluid being passed through a zeolite layer immediately after extraction, solvent having the same IR spectrum as the original solvent spectrum was recovered.

岡山県吉井川、旭川、高梁川の元素を指標とした水質評価

Eleven elemental concentrations (Na, Cr, Mn, Fe, Cu, Zn, As, Se, Cd, Hg, Pb) of water of three river systems (the Yoshii River, the Asahi River and the Takahashi River) in Okayama Prefecture were determined by inductively coupled plasma mass spectrometry (ICP-MS). A difference of each element concentration by river system was identified. In the Yoshii River, the elements (Mn, Fe, Cu, Zn and Cd) were significantly higher than those in other rivers (the Asahi and the Takahashi River). In the Asahi River or the Takahashi River, no element was significantly higher than the other rivers. Different characteristics of elements among the three river systems were recognized. The elements increase according to increase in flow rate. Especially, the coefficient of correlation on relationship between distance from mouth of river and elements (Cr, Cu and As) concentration in river was high. Elemental concentrations of every determined site were not over the water quality criteria concentration of tap water.

じん臓模倣の清浄技術による含油廃水中の油回収と廃水ゼロシステム

In the conventional system of engine lubrication, luburicating oil is renewed with fresh oil after it is used for some period. Accordingly, waste oil is generated in the conventional system. The authors have developed a new technology which makes it possible to use lubricating oil semi-permanently without oil renewal and, therefore, without any waste oil. This technology has been working well in about one thousand marine and cogeneration diesel engines in practical use for many years. The new technology always keeps lubricating oil clean as the kidney of animals always keeps their blood clean. This is why lubricating oil can be used semi-permanently and the new technology is called kidney system. The techology can be used to clean and recycle many kinds of liguids. This paper reports about recycling the lubricating oil mixed in waste water from compressors in a fertilizer company.