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        검색결과 4

        1.
        2004.03 KCI 등재 구독 인증기관 무료, 개인회원 유료
        영지1호를 비롯한 115개의 영지버섯 수집균주에 대하여 표준균주 G. lucidum G001-1 (A1B1) 및 G. tsugae 1109-16 (A1B1) 단핵 균주와 di-mon 교배를 통하여 화합성을 검정한 결과 G. lucidum 단핵균주는 어떠한 균주와도 clamp가 형성되지 않았으나, G. tsugae 단핵균주는 대부분 G. lucidum이라고 분류된 75개 균주와 clamp가 형성되어 이들 균주에 대한 재검토가 필요하였다. 또한 영지버섯의 di-mon 교배에서 불화합성 균주간에는 뚜렷한 대선을 형성하여 교배확인에 드는 노력을 감소할 수 있었다.
        3,000원
        2.
        2013.11 서비스 종료(열람 제한)
        Prediction method for the long-term chemical leaching amount from by-product/recycled materials such as waste concrete and steel slag and so on is necessary to widely promote their effective utilization and evaluate their environmental safety. Although there are the batch leaching tests and the column leaching test as the testing methods for evaluating the long-term leaching behavior, the leaching mechanism and the testing result compatibility in both tests has insufficiently been clarified yet. Thus, the prediction of the leaching behavior from the by-product/recycled materials used in actual civil works and their environmental safety evaluation are by no means certain. This paper shows the difference between the batch leaching tests and the column leaching tests in the chemical leaching behavior of Cu-slag. The batch leaching tests were conducted under liquid/solid ratio = 10, liquid = distilled water, stirring strength = 0, 30, or 120 rpm. After a certain elapsed time, the leaching solution was exchanged with the pure distilled water and then the stirring was restarted. The elapsed time was set at 1, 2, 4, 8, 16, 32 days. The column leaching tests were also conducted under the same conditions as those of the batch leaching tests in order to evaluate the effects of the pore distribution and the pore flow velocity in the Cu-slag column on the leaching behavior. In the column leaching tests, the effluent passing through the column was circulated as the influent (Fig. 1). The leaching duration in the column tests can be equivalent as that in the batch tests, so that the difference in the leaching behavior between the batch leaching tests and the column leaching tests may be dependent on the pore-scale heterogeneous flow and path generated in porous materials. Figure 2 shows the leaching rate evaluated from the batch leaching tests and the column leaching tests. In the same fluid velocity levels, the leaching rate in the column tests was larger than that in the batch tests. The leaching rate has been considered large with the fluid velocity. Although the fluid velocity generated by the stirring was the same as the flushing velocity on the surface of the Cu-slag in the batch tests, the fluid velocity in the column tests was enhanced because the permeant liquid was concentrated into the limited pore space in the Cu-slag column. Thus, the pore-scale heterogeneous flow and path generated in porous materials should be evaluated in order to clarify the compatibility between the batch leaching tests and the column leaching tests.