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Vapor-liquid equilibrium

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Heat and Mass Transfer

Definition

Vapor-liquid equilibrium (VLE) is the condition where a vapor and its corresponding liquid phase coexist at a specific temperature and pressure. At this point, the rate of evaporation of the liquid equals the rate of condensation of the vapor, resulting in stable concentrations of both phases. This balance is essential in processes involving absorption and stripping, as it governs how substances transfer between phases and influences overall system efficiency.

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5 Must Know Facts For Your Next Test

  1. In vapor-liquid equilibrium, the composition of the vapor phase and the liquid phase can be different due to differences in volatility.
  2. VLE plays a critical role in separation processes, such as distillation, where components are separated based on their boiling points and vapor pressures.
  3. The concept of VLE is fundamental to designing equipment like absorbers and strippers, ensuring optimal mass transfer between phases.
  4. Temperature and pressure changes can shift the equilibrium position, impacting how effectively a substance can be absorbed or stripped from a mixture.
  5. Understanding VLE is essential for predicting how mixtures behave during thermal processes, enabling better control and efficiency in industrial applications.

Review Questions

  • How does vapor-liquid equilibrium influence mass transfer in absorption processes?
    • Vapor-liquid equilibrium directly affects mass transfer rates during absorption by determining how readily a gas can dissolve into a liquid. When the equilibrium is established, it allows for optimal contact between phases, facilitating effective absorption. If the conditions shift away from VLE, it can hinder absorption efficiency, as either excess gas or insufficient solvent may lead to unbalanced phase interactions.
  • Discuss how changes in temperature and pressure affect vapor-liquid equilibrium and its implications for stripping operations.
    • Changes in temperature and pressure alter the vapor-liquid equilibrium, shifting the balance between phases. For example, increasing temperature typically increases vapor pressure and can drive off more volatile components during stripping. Conversely, reducing pressure might enhance mass transfer rates by lowering boiling points. Understanding these effects is crucial for optimizing stripping operations to achieve desired separation efficiencies.
  • Evaluate the role of Raoult's Law and Henry's Law in understanding vapor-liquid equilibrium in complex mixtures during absorption and stripping.
    • Raoult's Law and Henry's Law are fundamental for analyzing vapor-liquid equilibrium in complex mixtures. Raoult's Law helps predict how individual components behave based on their pure component properties and concentrations, guiding design choices in absorption. Meanwhile, Henry's Law provides insight into gas solubility dynamics under varying pressures, which is vital for effective stripping. Together, these laws enable engineers to model phase behavior accurately, optimize operational parameters, and improve overall process efficiency.
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