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Using Separations in Chemical Processing

Using Separations in Chemical Processing. 1. reactor. separator. 4. 2. 5. 6. 3. raw materials. products. r ecycle stream. Where are separations needed?. Purification of reactor feeds Purification of products for sale Purification of waste for safe disposal.

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Using Separations in Chemical Processing

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  1. Using Separations in Chemical Processing 1 reactor separator 4 2 5 6 3 raw materials products recycle stream

  2. Where are separations needed? • Purification of reactor feeds • Purification of products for sale • Purification of waste for safe disposal

  3. Separations as Unit Operations • The specific design of the separator depends on the chemical composition of the feed, and the desired purity of the product • However, the general design principals are independent of the chemistry

  4. Column distillation At an oil refinery, fractional distillation columns separate hydrocarbons into separate streams, cuts or fractions A multi-purpose distillation column for mineral oils and chemicals  40 trays with multiple feed entry options, capacity: up to 45 mt/h mode: vacuum, atmospheric or pressure up to 3 bar temperature: up to 320°C

  5. Flash vaporization Water desalination plant in Cyprus Multistage flash distillation Flash drum for hydrocarbon vapor recovery

  6. Absorption and stripping A steam stripping column removes H2S and CO2 to regenerate the amine A column filled with an amine solution is used to absorb H2S and CO2 from “sour” natural gas

  7. Liquid-liquid extraction Mixer-settlers used for continuous, counter-current liquid-liquid extraction of rare-earth ions

  8. Leaching Cyanide leaching of gold ore, Nevada

  9. Sublimation Sublimation of HgI2 for use in semiconductor manufacturing, as well as in detectors for X-ray and g-ray imaging

  10. Crystallization Multiple-Effect Crystallizer for Sodium Sulfate (Na2SO4) Refining Crystallizer for Salt (NaCl)

  11. Chromatography Chromatography columns

  12. Membrane filtration Water Treatment Plant.Each white vessel contains seven spiral-wound membrane units.

  13. Why is good design important for separations? • Separations equipment can be 50-90 % of the capital investment in a chemical plant • Separations can also represent 40-70 % of operating costs • Purity requirements depend on market tolerance • High separations costs tolerated for high value-added products

  14. Examples 1. Petroleum refining crude oil  gasoline, diesel, jet fuel, fuel oil, waxes, coke, asphalt 2. Pharmaceuticals sub-ppm level of metal catalyst required for human consumption 3. Semiconductors SiO2 SiCl4 Si Metallurgical grade (97%) for alloying with steel and Al: $1/kg Solar grade for photovoltaics(99.99 %): $80/kg 4. Water treatment Industrial wastewater vs. potable water Some impurities ok (Ca2+); others not (Hg2+)

  15. Process Diagram for Ethylene hydration: C2H4 + H2O  C2H5OH

  16. Why do separations cost a lot? • “unmixing” causes reduction in entropy • this is not spontaneous • achieve by adding an external separating agent • Energy (distillation) • Material (e.g. extraction) • Barrier (e.g. membrane) • Gradient (e.g. electrophoresis)

  17. Table 1. Separation Unit Operations based on Phase Creation or Addition vertical drum horizontal drum valve column with trays (stages) heat exchangers condensor reboilers

  18. Table 1, cont. Separation Unit Operations Based on Phase Creation or Addition heater

  19. Table 1, cont. Separation Unit Operations Based on Phase Creation or Addition

  20. Table 2. Separation Unit Operations based on a Solid Separating Agent

  21. Table 3. Separation Unit Operations Based on the Presence of a Barrier

  22. Table 4. Separation Unit Operations Based on an Applied Field or Gradient

  23. Equilibrium-staged separations • Make use of thermodynamics to achieve spontaneous separation • But thermodynamics also dictates the limits of the separation

  24. Definitions of equilibrium thermal equilibrium: Tliq = Tvap vapor mechanical equilibrium: Pliq = Pvap liquid chemical equilibrium: mliq = mvap (chemical potential) Equilibrium is dynamic: molecules continue to vaporize and condense, but at equal rates, so there is no net change in either phase. Rate of approach to equilibrium depends on:(1) rate of mass transfer proportional to (a) mass transfer coefficients Ki = f(T), and (b) interfacial area (2) concentration gradient becomes very small as equilibrium is approached, ∞ time required to achieve

  25. Consider a single equilibrium stage • V and L are in equilibrium with each other; they are streams leaving the same equilibrium stage. • V and L are not in equilibrium with F, • i.e., miL= miV≠miF vapor product flow rate V T, P composition yi T, P vapor feed flow rate F TF, PF composition zi liquid liquid product flow rate L T, P composition xi • if > 1 chemical species present, then xi ≠ yi • therefore separation has occurred • vapor-liquid equilibrium (VLE) limits the amount of separation that can be achieved

  26. Cascade of equilibrium stages What if we need more separation than one equilibrium stage can provide? Feed one of the two product streams (e.g., L) to another equilibrium stage V 1 stage 1 F V2 stage 2 V3 L 1 stage 2 L2 L3 • Creates many vapor streams with different compositions • If we combine (mix) them, we destroy some of the separation we created • If we discard them, our yield is low.

  27. Better Alternative: Counter-current cascade F F V1 V1 1 1 Variable pressure cascade P1 > P2 > P3 L1 L1 V2 V2 compressor • replace by • replace by 2 2 L2 L2 V3 V3 Variable temperature cascade T1 > T2 > T3 3 3 L3 L3

  28. An even better alternative F V1 Integrate the heat exchangers: allow contact between condensing vapor and vaporizing liquid streams F V1 1 1 V2 liquid L1 V2 downcomer 2 V3 2 L1 weir 3 L2 V3 L2 perforated tray vapor 3 L3 L3 • integrated column is isobaric and non-isothermal • promotes mixing of liquid and vapor phases

  29. Thermodynamic considerations • Perfect separation requires an infinite number of equilibrium stages • The engineer specifies the number of stages required for an acceptable degree of separation • Equilibrium is not achieved on each stage in a finite time • theoretical stage: assume equilibrium is achieved • actual stage: equilibrium is not achieved (< 100 % efficiency) • We always need more than the theoretical number of stages to achieve the desired separation • The engineer’s role is to decide how many more

  30. General design procedure for equilibrium-staged separations • Obtain relevant equilibrium data (where?) • Determine no. of theoretical stages required • Determine no. of actual stages required (requires knowledge of stage efficiency) • Size equipment, based on expected flow rates F, V, L * * Focus of this course.

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