중첩 방전 반응기에 의한 NOx의 분해 특성

The Characteristics of Decomposition of NOx by Superposing Discharge Plasma Reactor

  • 발행 : 1999.11.01

초록

본 연구에서는 연소공정에서 발생하는 NOx를 제거하기 위해 연면방전과 AC Corona 방전을 중첩해서 특수설계 제작된 중첩방전 반응기의 방전분해 특성을 연구하였다. 실험은 SPCP, Corona Discharge 및 중첩방전에 대한 NOx의 분해율을 비교 측정하였다. 실험변수는 방전형태, 가스의 농도, 방전주파수, 가스의 유량 등에 대하여 측정하였다. 실험결과 중첩방전에 의한 NOx의 분해율은 SPCP방전고 Corona방전에 의한 분해율보다 10∼15[%] 증가하였고 소모전력도 10[%] 정도 작게 소모되었다. 중첩방전시 상부전극의 주파수의 영향은 주파수가 작을수록 NOx의 분해율이 높았고 하부전극의 SPCP만의 방전시에는 주파수가 높을수록 NOx의 분해율이 증가하였다. 방전형태에 대한 NOx의 최대분해율은 SPCP일 때 방전전력 18[W]에서 80[%] 이었고 AC코로나 방전일 때 방전전력 805[W]에서 10[%] 이었으나 중첩방전의 경우는 14[W]에서 90[%]로 중첩방전의 효과는 10[%]이상 증가하였다.

The superposing effect of SPCP(Surfoce Induced Plasma Chemical Process) and corona discharge has been studied for rerroval of NOx from industrial flue gases. NOx rermval rates by SPCP, corona discharge and superposing discharge were monitored and compared. Parameters were the concentration and the flow rate of gas, frequency and the type of discharge. Experirrental results showed that NOx removal rate by sUIffPOSing discharge was 10-15[%] higher than that by the other two modes. The higher NOx. rermval rate was observed with the lower frequency of upper electrode in the combined reactor and with the higher frequency of lower electrode. 'The maximum obtainable NOx. rerroval rate by SPCP (18 [W]) and corona discharge (8.5 [W]) was 80[%] and 10[%], respectively. With the combination of the two modes, however, 90[%] of NOx removal rate was observed with the discharge power of 14 [W].14 [W].

키워드

참고문헌

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