1 / 33

Liquid-Liquid Extraction Lecture 23

Liquid-Liquid Extraction Lecture 23. 26 Nov 2012. Overview. Liquid-Liquid Extraction (solvent extraction). Pioneered during 1940’s (uranium purification) Alternative to distillation, absorption/stripping Energy savings Sometimes easier separation Lower temperatures

aman
Download Presentation

Liquid-Liquid Extraction Lecture 23

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript


  1. Liquid-Liquid Extraction Lecture 23 26 Nov 2012

  2. Overview • Liquid-Liquid Extraction • (solvent extraction) • Pioneered during 1940’s (uranium purification) • Alternative to distillation, absorption/stripping • Energy savings • Sometimes easier separation • Lower temperatures • Usually two distinct phases formed • Usual purpose, to either purify the • Raffinate, or • Solute

  3. Liquid-Liquid Extraction Extract • Separation accomplished by chemical differences • Usually in two phase • - light phase • - heavy phase • Usually coupled with another separation technique Feed [s + a] (+b) [a+b] a = solute b = diluent s = solvent Extractor Separator could be: column w/ stages or packing column with moving internals single stage mixer/settler equilibrium stage(s) Solvent Raffinate [b] (+ a & s) [s] let:

  4. Example Industrial Processes Seader & Henley (2006)

  5. Typical LL Extraction Process Seader & Henley (2006)

  6. Equipment Examples Treybal (1980) Seader & Henley (2006)

  7. Spray Columns: Seader & Henley (2006)

  8. Packed-bed Column Seader & Henley (2006) Light liquid - dispersed phase Treybal (1980)

  9. Sieve-tray Extraction Column: light phase dispersed Treybal (1980)

  10. Oldshue-Rushton (MixcoLightninCMContactor) column Scheibel column Seader & Henley (2006)

  11. Seader & Henley (2006)

  12. Podbielniak Extractor Treybal (1980)

  13. Equipment Seader & Henley (2006)

  14. Equipment Examples Seader & Henley (2006)

  15. Equilateral Triangular Diagrams [a] Overall material balance: Component material balance (on a): [b] [s] Rearrange: Lever principle: [s] [b]

  16. Equilateral Triangular Diagrams [a] [a] [b] [b] [s] [s] Type I Type II • Examples: • water (b), ethylene glycol (a), furfural (s) • water (b), acetone (a), chloroform (s) • Example: • n-heptane (b), methylcyclohexane (a), aniline (s)

  17. Distribution Curves [a] [a] [b] [b] [s] [s] Type I Type II

  18. Distribution Curves [a] [a] [b] [b] [s] [s] Type I Type II

  19. Distribution Curves [a] [a] [b] [b] [s] [s] Type I Type II

  20. Effect of Temperature (and Pressure) Treybal (1980)

  21. Effect of Temperature (and Pressure) Treybal (1980)

  22. Choice of Solvent • Selectivity separation factor • Distribution Coefficient better if • Insolubility of Solvent better if less soluble in R phase • Solvent Recoverability should be easy to separate solvent from E and R • Density large density differences between the two phases is desired • Interfacial Tension would like large for easier coalescence of dispersed phase • Others: • solvent stable, inert, nontoxic, nonflammable, low cost • low viscosity • low vapor pressure • low freezing point

  23. Mixer – Settler (single stage extraction) Purified Raffinate [a] Raffinate Feed Purified Extract Solvent settler mixer New Solvent Extract Recycled Solvent solvent recovery solvent recovery [b] [s] Raffinate Feed 1 stage Black Box: Solvent Extract Material balance:

  24. Mixer – Settler (single stage extraction) given: find: [a] Component material balance (on a in feeds): [b] [s] Component material balance (on a in products):

  25. Mixer – Settler (single stage extraction) Minimum Solvent (rate): [a] [b] [s] Maximum Solvent (rate):

  26. Cross-Current (multi-stage extraction) Final Extract [a] Stage 1 Stage 2 Stage 3 Feed Final Raffinate Solvent Solvent Solvent [b] [s] Final Extract:

  27. Continuous Multistage CountercurrentExtraction [a] Feed Raffinate 1 N 2 N-1 Extract Solvent Total MB: [b] [s] Total MB on a: If known (specified), then flowrates can be found.

  28. Continuous Multistage CountercurrentExtraction [a] Feed Raffinate 1 N 2 N-1 Extract Solvent Total MB: Operating Point: MB from feed to N-1 stage: [b] [s]

  29. Continuous Multistage CountercurrentExtraction [a] Feed Raffinate 1 N 2 N-1 Extract Solvent Now step off to find number of equilibrium stages: [b] [s]

  30. Questions?

More Related