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TACT Considerations for Cleaning Membranes Correctly

Care needs to be taken during membrane cleaning to avoid damage such as stress-cracking the polymeric membrane layer or modifying the surface permeability.

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By: Food & Beverage | July 1, 2021 | Reading time: 3 minutes

Membranes are often made of very thin layers of plastic measuring less than the thickness of a sheet of paper. Care needs to be taken during cleaning to avoid damage such as stress-cracking the polymeric membrane layer or modifying the surface permeability. 

Successful membrane cleaning relies on the effectiveness of the cleaning compounds as well as their application. When designing membrane cleaning guidelines, the principles of TACT (time, action, chemical, temperature) should be followed and parameters adjusted to meet specific requirements.

Time

Time strategies can be used when cleaning membranes as it is one of the parameters that can be easily changed.  For example, wash solutions can be left in contact longer or wash steps repeated several times to gradually remove a soil. You can also switch back and forth from acid type cleans to alkaline or enzymatic cleans. Membrane cleaning procedures will typically take upwards of 4 hours to complete.

Action 

When cleaning membrane systems, the flow across the membranes is determined by the stage or cross-flow pump. The mechanical action cannot change without changing the pumps. Please follow the pump manufacturer's recommendations.

Chemical Concentration 

The type and concentration of chemicals that can be used to clean membranes is limited. The product and concentration will be determined by the materials used in the membrane and the manufacturer's recommendations. It is critical to know what type of membrane is being cleaned to ensure the correct procedure is being used. 

Typically, when faced with a difficult cleaning problem, our first thought is to increase the caustic concentration to 2-3%. High caustic is not an option for membranes cleaning due to the limits placed on pH by membrane elements manufacturers. 

Defoamers should never be used when cleaning membranes or used with products being processed through membranes. Almost all defoamers will stick to polymeric membranes causing them to foul and not permeate. It is also extremely difficult to remove defoamers from a membrane surface. 

Thin Film Composite (TFC) membranes are made with a very thin layer of polyamide laid over a polysulfone membrane. While chlorine is used to clean polysulfone membranes all the time, polyamide cannot tolerate chlorine, even at very low levels. In this instance, enzyme cleaners are the only option to remove protein from a TFC reverse osmosis membrane. 

Most of the membranes used in dairy applications are made of plastics. Plastic presents many challenges when it comes to cleaning: surfactants may induce stress-cracking and solvent-type cleaners can dissolve the glues used to hold membranes together. Most plastic membranes can tolerate a pH in the range of 1-12, but it is recommended to stay within a pH of 1.8 - 11.5. 

When confusion exists around selecting the appropriate cleaning chemistry, it is recommended to consult with both the membrane manufacturer and a reputable cleaning company. 

Temperature 

Temperature can be very limiting when cleaning membranes. Polymeric or plastic membranes are generally limited to 135?F (57?C) and most element manufacturers recommend a cleaning temperature at or below 125?F (50?C).

The removal of fats and oils from a membrane is also impacted by temperature. To saponify fats with caustic you need temperature above 150?F (65?C) but polymeric membranes cannot tolerate temperatures this high. A limited amount of caustic with a buffered pH, combined with the right surfactants, will help to remove fatty residues.

Surfactants are used to remove fats and oils from membranes due to their ionization behavior. When added to water, surfactants ionize and have a specific charge adhering to the fats and oils and enabling them to dissolve in water.  However, if foaming is seen during membrane cleaning, it is a result of the surfactants lowering the surface tension. The selection of the right non-ionic surfactant in the formulation will help lower the surface tension and also reduce foam creation.

Membrane Cleaning Solutions from Diversey

At Diversey, we understand the complexity and sensitivity of membrane cleaning. Our Divos range of cleaners has been formulated specifically for membrane systems and are designed to meet the specific soil and membrane demands.

We utilise a well-established internal database of membrane cleaning expertise and have a Membrane Trustee Group which meets regularly to discuss membrane cleaning issues and direct our product development process.

We have also packaged our expertise into a dedicated Hygiene Academy eLearning course which covers:

  • Basic principles of membranes
  • Basic of membrane design
  • Different types of membrane installations
  • Types of membranes available and where they are used
  • Membrane materials available for microfiltration, ultrafiltration, nanofiltration and reverse osmosis
  • Temperature & pH limitations for different membrane designs & components
  • The chemistry of cleaning membranes

Find out more about the course.
 

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Diversey – A Solenis Company

A team of experts and a proven history of developing best practices. We understand what it takes to keep your facilities clean and your products safe. Through our extensive portfolio, our partners have access to chemicals, equipment, Knowledge-based Services (KBS) and training solutions all backed by decades of global experience.