Water Purification

stripper

Stripping: A Powerful Tool for Clean Water

Stripping is a widely used technology in environmental and water treatment, employed to remove volatile and semi-volatile contaminants from water. This process relies on the principle of mass transfer, where contaminants are transferred from the liquid phase (water) to the gas phase (air).

How Stripping Works:

The basic principle behind stripping is simple. Contaminated water is brought into contact with a gas stream (usually air) that has a lower concentration of the contaminant. Due to the concentration difference, the contaminant vaporizes from the water and dissolves into the air. This process is driven by Henry's Law, which states that the solubility of a gas in a liquid is proportional to the partial pressure of the gas above the liquid.

Key Components of a Stripping System:

  1. Stripping Column: This is the central component of the system where the actual transfer of contaminants occurs. The column is typically filled with packing material (like plastic or ceramic rings) to increase the contact area between the water and the gas.
  2. Air Supply: A blower or compressor provides the air stream used to strip the contaminants from the water.
  3. Liquid Inlet and Outlet: These connections allow the contaminated water to enter the stripping column and the treated water to exit.
  4. Gas Inlet and Outlet: These connections allow the air stream to enter and exit the column, carrying the stripped contaminants.

Types of Stripping:

  • Air Stripping: The most common type, utilizing air as the stripping gas.
  • Steam Stripping: Uses steam as the stripping gas, effective for removing more volatile contaminants.
  • Vacuum Stripping: Reduces pressure within the column, which increases the vapor pressure of the contaminants, facilitating removal.

Applications of Stripping in Water Treatment:

  • Removal of Volatile Organic Compounds (VOCs): Stripping is highly effective in removing VOCs like trichloroethylene (TCE), tetrachloroethylene (PCE), and benzene.
  • Removal of Hydrogen Sulfide (H2S): Stripping is used to remove H2S from water, which can cause unpleasant odors and corrosion.
  • Removal of Ammonia: Stripping can be used to remove ammonia from wastewater, especially in the treatment of industrial effluents.

Advantages of Stripping:

  • Efficient: Stripping is a highly efficient process for removing volatile and semi-volatile contaminants.
  • Cost-effective: Compared to other treatment methods, stripping can be a cost-effective solution.
  • Relatively Simple: Stripping technology is relatively simple to operate and maintain.

Limitations of Stripping:

  • Not Effective for All Contaminants: Stripping is primarily effective for volatile and semi-volatile compounds. It is not suitable for removing non-volatile contaminants or contaminants with low vapor pressure.
  • Potential for Air Emissions: Stripping can release contaminants into the air, which requires proper control measures to mitigate potential environmental impacts.

Conclusion:

Stripping is a valuable tool in environmental and water treatment, effectively removing a wide range of volatile and semi-volatile contaminants from water. Understanding its principles and limitations is crucial for successful implementation and optimizing treatment outcomes for cleaner and safer water resources.

Test Your Knowledge

Quiz: Stripping: A Powerful Tool for Clean Water

Instructions: Choose the best answer for each question.

1. What is the primary principle behind stripping technology?

a) Adsorption

Answer

Incorrect. Adsorption involves the attachment of contaminants to a solid surface.

b) Oxidation

Answer

Incorrect. Oxidation involves the addition of oxygen to a compound.

c) Mass transfer

Answer

Correct! Stripping relies on the transfer of contaminants from the liquid to the gas phase.

d) Chemical precipitation

Answer

Incorrect. Chemical precipitation involves forming solid particles from dissolved substances.

2. Which law governs the solubility of a gas in a liquid during stripping?

a) Dalton's Law

Answer

Incorrect. Dalton's Law deals with partial pressures of gases in a mixture.

b) Henry's Law

Answer

Correct! Henry's Law describes the relationship between gas solubility and partial pressure.

c) Boyle's Law

Answer

Incorrect. Boyle's Law relates pressure and volume of a gas.

d) Charles' Law

Answer

Incorrect. Charles' Law relates volume and temperature of a gas.

3. What is the primary function of packing material in a stripping column?

a) To filter out solid particles

Answer

Incorrect. Filtration is not the primary function of packing material in stripping.

b) To increase the contact area between water and gas

Answer

Correct! The packing increases surface area for efficient mass transfer.

c) To prevent backflow of air

Answer

Incorrect. Backflow prevention is usually handled by other system components.

d) To absorb contaminants

Answer

Incorrect. Stripping does not rely on absorption, but rather on vaporization.

4. Which type of stripping is most commonly used in water treatment?

a) Vacuum stripping

Answer

Incorrect. Vacuum stripping is less common than air stripping.

b) Steam stripping

Answer

Incorrect. Steam stripping is effective but less common than air stripping.

c) Air stripping

Answer

Correct! Air stripping is the most widely used method due to its simplicity and effectiveness.

d) Ozone stripping

Answer

Incorrect. Ozone is used for oxidation, not stripping.

5. What is a potential limitation of stripping technology?

a) It is not effective for removing volatile compounds

Answer

Incorrect. Stripping is specifically effective for volatile compounds.

b) It is expensive compared to other treatment methods

Answer

Incorrect. Stripping is often considered a cost-effective solution.

c) It can potentially release contaminants into the air

Answer

Correct! Proper control measures are needed to mitigate air emissions.

d) It requires complex and specialized equipment

Answer

Incorrect. Stripping technology is relatively simple to operate and maintain.

Exercise: Designing a Stripping System

Task: A small industrial plant discharges wastewater containing 10 ppm of TCE (trichloroethylene). Design a basic stripping system to remove the TCE from the wastewater. Consider the following:

  1. Stripping Column: Choose a suitable packing material and estimate the column height required for achieving a desired TCE removal efficiency (e.g., 90%).
  2. Air Supply: Determine the air flow rate needed to ensure effective stripping.
  3. Control Measures: Propose measures to minimize potential air emissions of TCE.

Exercice Correction

This exercise requires further research and calculations. Here's a general approach:

1. Stripping Column:

  • Packing Material: Common options include plastic or ceramic rings, saddles, or Pall rings. The specific choice depends on factors like TCE concentration, desired efficiency, and available space.
  • Column Height: This is determined by the mass transfer rate and the required contact time between the wastewater and air. The Henry's Law constant for TCE and the desired removal efficiency will help calculate the required height.
  • Additional Considerations: Factors like wastewater flow rate, temperature, and pressure also influence column design.

2. Air Supply:

  • Air Flow Rate: The required air flow rate is related to the wastewater flow rate and the mass transfer coefficient for TCE. Higher flow rates can lead to more efficient stripping.

3. Control Measures:

  • Air Emission Control: Options include:
    • Activated Carbon Adsorption: Capturing TCE before releasing the air into the atmosphere.
    • Condensation: Cooling the air stream to condense and capture TCE.
    • Catalytic Oxidation: Converting TCE into less harmful products.

Note: A complete design requires detailed calculations and simulations, but this exercise aims to illustrate the general considerations involved in designing a stripping system.

Books

  • Water Treatment: Principles and Design by W. Wesley Eckenfelder Jr. and David B. Benefield (This classic covers various water treatment methods, including stripping)
  • Environmental Engineering: A Global Text by C.H.S. Davie, D.G. Linton, and H.R. Hemmings (Covers the fundamentals of environmental engineering, including stripping in wastewater treatment)
  • Handbook of Environmental Engineering edited by L. Theodore (Offers a broader overview of environmental engineering, including sections on stripping and air pollution control)

Articles

  • "Air Stripping for the Removal of Volatile Organic Compounds from Water" by P. C. Singer and R. D. Letterman (A detailed study on the theory and applications of air stripping for VOC removal)
  • "Stripping Technology for the Removal of Volatile Organic Compounds from Wastewater" by T. H. Adams and R. W. Grady Jr. (A comprehensive review of stripping techniques for VOCs in wastewater treatment)
  • "Removal of Ammonia from Wastewater by Air Stripping: A Review" by Y. Yang, J. Zhang, and Y. Li (Focuses specifically on ammonia removal using air stripping in wastewater treatment)

Online Resources

  • US EPA's Tech fact Sheet: Air Stripping (Provides a concise overview of air stripping, including its applications, limitations, and design considerations)
  • Water Environment Federation (WEF): Stripping (A technical resource from WEF, offering information on stripping processes, best practices, and industry standards)
  • USEPA’s Technology Innovation and Field Demonstration (TIFD) Program: Air Stripping (Offers practical guidance on air stripping technology for specific applications and scenarios)

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