• 한국산림과학회지
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• 제103권3호
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• pp.339-352
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• 2014

백두대간 조침령-신배령 구간 소나무림과 신갈나무림을 대상으로 2012년 4월부터 2013년 8월까지 영구조사구($100m{\times}100m$) 설치하여 조사하였다. 총 50개소의 산림식생조사 자료를 토대로 Z-M식물사회학적 방법에 의해 식생유형 분류를 수행하였던바, 최상위 수준에서 신갈나무군락군이 분류되었으며, 군락단위에서는 물푸레나무군락과 까치박달군락으로 세분되었다. 물푸레나무군락은 군단위에서 소나무군과 가래나무군으로 나누어지며, 소나무군은 다시 회나무소군과 머루소군으로 분류되었고, 까치박달군락은 시닥나무군과 사스래나무군으로 각각 세분되어, 총 5개의 식생단위로 분류되었다. 식생단위별 중요치를 분석한 결과 소나무림에서 소나무와 신갈나무의 중요치가 20%이상으로 높게 나타났으나 소나무가 신갈나무보다 상대피도가 50%이상으로 가장 높게 나타났다. 종간연관 분석결과 크게 4개의 유형으로 구분되었고, 이는 식생단위의 식별종 및 표징종과 일치하는 경향이었다. 또한 소나무림의 흉고직경급별 개체 분포에서 중간직경급에서 개체수가 가장 많은 정규분포를 나타낸 소나무와 이를 제외한 다른 수종은 직경이 커질수록 개체수가 감소하는 역 J자형의 분포유형을 나타내어 소나무림에서 신갈나무림으로 교체될 가능성이 크다 판단된다. 반면 신갈나무림에서는 신갈나무를 포함한 다른 수종 모두 역 J자형의 분포유형을 나타내어 신갈나무림은 당분간 안정된 상태로 지속될 것으로 판단되었다.

• 한국환경과학회지
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• 제23권12호
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• pp.2045-2056
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• 2014

In this study, pressure drop was measured in the pulse jet bag filter without venturi on which 16 numbers of filter bags (Ø$140{\times}850{\ell}$) are installed according to operation condition(filtration velocity, inlet dust concentration, pulse pressure, and pulse interval) using coke dust from steel mill. The obtained 180 pressure drop test data were used to predict pressure drop with multiple regression model so that pressure drop data can be used for effective operation condition and as basic data for economical design. The prediction results showed that when filtration velocity was increased by 1%, pressure drop was increased by 2.2% which indicated that filtration velocity among operation condition was attributed on the pressure drop the most. Pressure was dropped by 1.53% when pulse pressure was increased by 1% which also confirmed that pulse pressure was the major factor affecting on the pressure drop next to filtration velocity. Meanwhile, pressure drops were found increased by 0.3% and 0.37%, respectively when inlet dust concentration and pulse interval were increased by 1% implying that the effects of inlet dust concentration and pulse interval were less as compared with those changes of filtration velocity and pulse pressure. Therefore, the larger effect on the pressure drop the pulse jet bag filter was found in the order of filtration velocity($V_f$), pulse pressure($P_p$), inlet dust concentration($C_i$), pulse interval($P_i$). Also, the prediction result of filtration velocity, inlet dust concentration, pulse pressure, and pulse interval which showed the largest effect on the pressure drop indicated that stable operation can be executed with filtration velocity less than 1.5 m/min and inlet dust concentration less than $4g/m^3$. However, it was regarded that pulse pressure and pulse interval need to be adjusted when inlet dust concentration is higher than $4g/m^3$. When filtration velocity and pulse pressure were examined, operation was possible regardless of changes in pulse pressure if filtration velocity was at 1.5 m/min. If filtration velocity was increased to 2 m/min. operation would be possible only when pulse pressure was set at higher than $5.8kgf/cm^2$. Also, the prediction result of pressure drop with filtration velocity and pulse interval showed that operation with pulse interval less than 50 sec. should be carried out under filtration velocity at 1.5 m/min. While, pulse interval should be set at lower than 11 sec. if filtration velocity was set at 2 m/min. Under the conditions of filtration velocity lower than 1 m/min and high pulse pressure higher than $7kgf/cm^2$, though pressure drop would be less, in this case, economic feasibility would be low due to increased in installation and operation cost since scale of dust collection equipment becomes larger and life of filtration bag becomes shortened due to high pulse pressure.