화학공학소재연구정보센터
Journal of the Korean Industrial and Engineering Chemistry, Vol.7, No.1, 18-25, February, 1996
교반조에서 경사 및 2단 Impeller의 교반소요동력에 관한 연구
Power Input of Pitched and Double-Stage Paddle Impeller in a Agitated Vessel
초록
교반소요동력은 장치의 설계상 중요할 뿐만 아니라 교반 프로세스를 평가, 검토하는 데 매우 중요하다. 특히 실험실 레벨에서 플랜트로의 스케일업은 주로 동력기준으로 행해지기 때문에 장치형상의 선택과 동력의 설정이 교반효과를 결정한다. 따라서 본 연구에서는 난류역 완전방해판 조건하에서 경사 임펠러 및 2단 패들 임펠러의 적절한 동력상관식을 제시한다. Np(pitch)=(θ/90°) Np(90°) 또한 임펠러 사이의 거리에 따른 동력수의 추산식을 제시한다. Np=7.09(np)0.7(b(double)/d)(H/D)0.18, np0.7(b(double)/d)<2
Np=8.73(np)0.7(b(double)/d)0.7(H/D)0.18,np0.7(b(double)/d)>2
Power input in stirred vessel is especially important in the design of mixers, as well as the evaluation of mixing processes. A type of baffles in mechanically agitated vessels and power employed are major factors that determine the stirring efficiency in a large scale, multi-step processes. In the present study, power input in the totally baffled agitated vesseles was compared systematically in connection with several previous studies and adequate power input correlation was found to be : Np(pich)=(θ/90°) Np(90°) Power number correlation was dependent upon the distance of among the impeller in the agitated vesseles, as follows : Np=7.09(np)0.7(b(double)/d)(H/D)0.18, np0.7(b(double)/d)<2
Np=8.73(np)0.7(b(double)/d)0.7(H/D)0.18,np0.7(b(double)/d)>2
  1. Nagata S, "Mixing Principles and Application," Koudansha LTD, Tokyo (1975)
  2. Bates RL, Fondy PL, Corpstein RR, Ind. Eng. Chem. Process Des. Dev., 2, 310 (1963) 
  3. Takeda K, Hoshino T, Taguchi H, Hujii T, Kagaku Kogaku, 32, 376 (1968)
  4. Komori S, Murakami Y, AIChE J., 34, 932 (1988) 
  5. Mochizuki M, Sato K, Kag. Kog. Ronbunshu, 10, 49 (1984)
  6. Kamei N, Hiraoka S, Kato T, Tada Y, Kuwabara S, Lee YS, Tamaguchi T, Koh ST, Kag. Kog. Ronbunshu, 20, 595 (1994)
  7. Hiraoka S, Tamada I, Mizoguchi K, J. Chem. Eng. Jpn., 11, 487 (1978)
  8. Hiraoka S, Tamada I, Aragaki T, Nishiki H, Sato A, Tagaki T, J. Chem. Eng. Jpn., 21, 79 (1988)
  9. Sano Y, Usui H, J. Chem. Eng. Jpn., 18, 47 (1985)
  10. Hirose T, Murakami Y, J. Chem. Eng. Jpn., 19, 568 (1986)
  11. Rushton JH, Costich EW, Everett HJ, Chem. Eng. Prog., 46, 394 (1950)
  12. Rushton JH, Costich EW, Everett HJ, Chem. Eng. Prog., 46, 467 (1950)
  13. Lee YS, Lee SK, Kim JS, HWAHAK KONGHAK, 33(1), 46 (1995)
  14. Oldshue JY, "Fluid Mixing Technology," (a), 32, Chemical Engineering, McGraw-Hill, New York (1983)
  15. Chudacek MW, Ind. Eng. Chem. Fundam., 35, 391 (1986) 
  16. Hiraoka S, Yamada I, Mizoguchi K, J. Chem. Eng. Jpn., 11, 224 (1988)
  17. O'Conell FP, Mack DE, Chem. Eng. Prog., 46, 358 (1950)
  18. Tatterson GB, Ali AM, Yuan HH, Dickey DS, Chem. Eng. Commun., 10, 205 (1981)