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MEMBRANE

Membrane can be described as a thin layer of material that is capable of separating materials as a function of their physical and chemical properties when a driving force is applied across the membranes. Physically membrane could be solid or liquid.  In membrane separation processes, the influent to the membrane module is known as the feed stream (also known as the feed water), the liquid that passes through the semipermeable membrane is known as permeate (also known as the product stream or permeating stream) and the liquid containing the retained constituents is known as the concentrate also known as retained phase. 

MEMBRANE PROCESS CLASSIFICATION 

Membrane processes can be classified in a number of different ways :  

  • The type of material from which the membrane is made 
  • The nature of the driving force 
  • The separation mechanism 
  • The nominal size of the separation achieved 

Table 3.11.1. General characteristics of membrane processes 

Water Pollution Control By Membrane Based Technologies | Environmental Engineering - Civil Engineering (CE)

Water Pollution Control By Membrane Based Technologies | Environmental Engineering - Civil Engineering (CE)

Water Pollution Control By Membrane Based Technologies | Environmental Engineering - Civil Engineering (CE)

Water Pollution Control By Membrane Based Technologies | Environmental Engineering - Civil Engineering (CE)

Water Pollution Control By Membrane Based Technologies | Environmental Engineering - Civil Engineering (CE)

Table 3.11.2. Advantages & disadvantages of membrane technologies 

 Advantages Disadvantages 
Microfiltration and ultrafiltration 
  • Can reduce the amount of treatment chemicals 
  • Smaller space requirements (footprint); membrane equipment requires 50 to 80 percent less space than conventional plants 
  • Reduced labour requirements; can be automated easily 
  • New membrane design allows use of lower pressures; system cost may be competitive with conventional wastewater-treatment processes 
  • Remove protozoan cysts, oocysts, and helminth ova; may also remove limited amounts of bacteria and viruses 
  • Uses more electricity; high-pressure systems can be energy-intensive 
  • May need pretreatment to prevent fouling; pretreatment facilities increase space needs and overall costs 
  • May require residuals handling and disposal of concentrate 
  • Require replacement of membranes about every 3 to 5 years 
  • Scale formation can be a serious problem. Scale-forming potential difficult to predict without field testing 
  • Flux rate (the rate of feedwater flow through the membrane) gradually declines over time. Recovery rates may be considerably less than 100 percent 
  • Lack of a reliable low-cost method of monitoring performance 
Reverse osmosis 
  •  Can remove dissolved constituents
  •  Can disinfect treated water
  • Can remove NDMA and other related organic compounds 
  • Can remove natural organic matter (a disinfection by-product precursor) and inorganic matter 
  •  Works best on ground water or low solids surface water or pretreated wastewater effluent
  • Lack of a reliable low-cost method of monitoring performance
  • May require residuals handling and disposal of concentrate 
  • Expensive compared to conventional treatment  

 

MEMBRANE MATERIALS & CONFIGURATIONS 

  • Membranes can be made from a number of different organic and inorganic materials. The membranes used for wastewater treatment are typically organic. The principle types of membranes used include polypropylene, cellulose acetate, aromatic polyamides, and thinfilm composite (TFC).  
  • Membranes used for the treatment of water and wastewater typically consist of a thin skin having a thickness of about 0.20 to 0.25 µm supported by a more porous structure of about 100 µm in thickness.
  • Term ‘module’ is used to describe a complete unit comprised of the membranes, the pressure support structure for the membranes, the feed inlet and outlet permeate and retentate ports, and an overall support structure.  
  • The principle types of membrane modules used for wastewater treatment are
     1) tubular, 2) spiral wound, 3) hollw fibre,4) flat. 


Table 3.11.3. Comparison of different membrane configurations  

Water Pollution Control By Membrane Based Technologies | Environmental Engineering - Civil Engineering (CE)
Water Pollution Control By Membrane Based Technologies | Environmental Engineering - Civil Engineering (CE)

MEMBRANE FOULING 

Membranes can be seen as sieves retaining part of the feed. As a consequence, deposits of the retained material will accumulate at the feed side of the membrane. In time this might hamper the selectivity and productivity of the separation process. This process is called fouling. koros et al gave the definition of fouling as “The process resulting in loss of performance of a membrane due to deposition of suspended or dissolved substances on its external surfaces, at its pore openings, or within its pores”. Membrane fouling is an important consideration in the design and operation of membrane systems as it affects pretreatment needs, cleaning requirements, operating conditions, cost, and performance. 

Three approaches are used to control membrane fouling:  

1) Pretreatment of the feed water: pretreatment is used to reduce the TSS and bacterial content of the feed water 

2) Membrane backflushing: to eliminate the accumulated material from the membrane surface with water and/or air. 

3) Chemical cleaning of the membranes: Chemical treatment is used to remove constituents that are not removed during conventional backwashing. Chemical precipitates can be removed by altering the chemistry of the feed water and by chemical treatment.

The document Water Pollution Control By Membrane Based Technologies | Environmental Engineering - Civil Engineering (CE) is a part of the Civil Engineering (CE) Course Environmental Engineering.
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FAQs on Water Pollution Control By Membrane Based Technologies - Environmental Engineering - Civil Engineering (CE)

1. What are membrane-based technologies for water pollution control?
Ans. Membrane-based technologies for water pollution control refer to the use of membranes, such as reverse osmosis, ultrafiltration, and nanofiltration, to separate pollutants and impurities from water. These technologies work by applying pressure to force water through the membrane while leaving behind contaminants.
2. How do membrane-based technologies help in water pollution control?
Ans. Membrane-based technologies help in water pollution control by effectively removing various pollutants and impurities from water. The membranes act as barriers, allowing only clean water molecules to pass through while blocking contaminants such as bacteria, viruses, heavy metals, and organic compounds. This results in the production of clean and safe water.
3. What are the advantages of using membrane-based technologies for water pollution control?
Ans. Some advantages of using membrane-based technologies for water pollution control include high efficiency in pollutant removal, versatility in treating different types of pollutants, compact system design, and the ability to operate at low energy consumption. These technologies are also capable of removing small particles and dissolved substances that traditional treatment methods may not effectively eliminate.
4. Are membrane-based technologies cost-effective for water pollution control?
Ans. While membrane-based technologies may have higher initial costs compared to traditional water treatment methods, they can be cost-effective in the long run. The efficiency and effectiveness of these technologies result in reduced chemical and energy requirements, lower maintenance costs, and a smaller footprint. Additionally, the production of clean water through membrane filtration can have economic benefits in terms of improved public health and reduced healthcare costs.
5. Can membrane-based technologies be used for large-scale water pollution control?
Ans. Yes, membrane-based technologies can be used for large-scale water pollution control. These technologies are scalable and can be implemented in various applications, including municipal water treatment plants, industrial wastewater treatment facilities, and desalination plants. With advancements in membrane technology and system design, large-scale water purification using membranes is becoming increasingly feasible and practical.
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