1.24k likes | 3.96k Views
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
E N D
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 • Usually two distinct phases formed • Usual purpose, to either purify the • Raffinate, or • Solute
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:
Example Industrial Processes Seader & Henley (2006)
Typical LL Extraction Process Seader & Henley (2006)
Equipment Examples Treybal (1980) Seader & Henley (2006)
Spray Columns: Seader & Henley (2006)
Packed-bed Column Seader & Henley (2006) Light liquid - dispersed phase Treybal (1980)
Sieve-tray Extraction Column: light phase dispersed Treybal (1980)
Oldshue-Rushton (MixcoLightninCMContactor) column Scheibel column Seader & Henley (2006)
Podbielniak Extractor Treybal (1980)
Equipment Seader & Henley (2006)
Equipment Examples Seader & Henley (2006)
Equilateral Triangular Diagrams [a] Overall material balance: Component material balance (on a): [b] [s] Rearrange: Lever principle: [s] [b]
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)
Distribution Curves [a] [a] [b] [b] [s] [s] Type I Type II
Distribution Curves [a] [a] [b] [b] [s] [s] Type I Type II
Distribution Curves [a] [a] [b] [b] [s] [s] Type I Type II
Effect of Temperature (and Pressure) Treybal (1980)
Effect of Temperature (and Pressure) Treybal (1980)
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
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:
Mixer – Settler (single stage extraction) given: find: [a] Component material balance (on a in feeds): [b] [s] Component material balance (on a in products):
Mixer – Settler (single stage extraction) Minimum Solvent (rate): [a] [b] [s] Maximum Solvent (rate):
Cross-Current (multi-stage extraction) Final Extract [a] Stage 1 Stage 2 Stage 3 Feed Final Raffinate Solvent Solvent Solvent [b] [s] Final Extract:
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.
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]
Continuous Multistage CountercurrentExtraction [a] Feed Raffinate 1 N 2 N-1 Extract Solvent Now step off to find number of equilibrium stages: [b] [s]