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By Ali Green 6 August 2020 3 min read

The humble face mask has become an iconic tool in the global response to the COVID-19 pandemic. Around the world, this critical piece of personal protection equipment (PPE) is helping in the fight against the virus.

Although they may look like a simple apparatus, face masks require significant engineering. This level of engineering is essential to ensure safe, effective and fit-for-purpose use.

So, when it comes to face masks, how do we know they are actually doing what they say they are?

Behind the mask: types of PPE masks

There are many types of masks, here’s a quick breakdown:

  • Surgical masks are generally flat rectangular materials with pleats that stretch across the nose and lower portion of a person’s face and are single-use.
  • P2 masks are cup-shaped masks worn around the nose and mouth. They are sometimes referred to as N95 (US standard) or KN95 (Chinese standard) masks. (Fun fact: ‘95’ means the respirator blocks 95 per cent of very small (0.3 micron) test particles)
  • P2 surgical masks have a similar shape to P2 masks and must satisfy the requirements of both surgical masks and P2 masks.

Most masks available to the public do not undergo standard testing. But a mask used as a medical device requires testing and registration in the ARTG.

Face mask testing: then and now

PPE for medical staff must be tested and then registered in the Australian Register for Therapeutic Goods (ARTG). Previously, the only way of testing face masks or face mask materials was to send them overseas. This process was time-consuming and expensive.

But, in the same way that COVID-19 has driven innovation in other industries, it's also driven a significant improvement in the way we ensure the safety of PPE in Australia.

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Australia's first face mask testing facility

We have opened Australia’s first accredited face mask testing facility for single-use surgical face masks. The facility will assist manufacturers in fast-tracking the supply of masks for hospital staff.

Located in Clayton, Victoria, the facility has accreditation from the National Association of Testing Authorities (NATA). It will allow local manufacturers to quickly and effectively test surgical face masks.

Putting masks to the test

We have developed three key tests for single-use surgical face masks. Basically we're testing to ensure they meet the standards for breathability, blood penetration and bacterial filtration.

Pressure Differential (Pressure drop test)

The Differential Pressure test measures the differential pressure of air on either side of the test material. This test determines whether the wearer will be able to breathe comfortably while wearing it.

©  Nick Pitsas

Synthetic Blood Penetration

The Synthetic Blood Penetration Test determines how well a mask can act as a barrier against blood-borne pathogens. We spray a volume of synthetic blood at the centre of the mask at high velocity. This measures the mask’s ability to stop blood getting through the mask.

©  Nick Pitsas

Bacterial Filtration Efficiency (BFE)

We conduct BFE testing on face masks made to provide protection against biological aerosols. This test determines whether biological organisms can penetrate the filtration fabric used in a mask.

©  Nick Pitsas

Additional screening, or “proxy tests”

In addition to the accredited tests conducted at our new testing facility in Clayton, we also conduct “proxy” screening tests at our Geelong and Clayton laboratories. These indicative tests are specifically for research and development purposes. In short, we're helping Aussie manufacturers to improve their products and processes.

Particle Filtration Efficiency

The particle removal test involves passing an air stream containing extremely fine particles, called aerosol, through the mask material. The test determines the material’s ability to act as a particle barrier while letting clean air pass through. Some tests use a very fine liquid spray instead of solid particles.

Dust Loading

This test determines the product’s capacity to collect particles before the creation of a particle blockage that impacts breathing resistance. This test can also measure the amount of electrostatic charge within inside the filter material.

Pore Size Measurement

Another method to identify filterable particle sizes is to measure the pore size distribution in a material.  We do this by wetting a porous material with a suitable liquid to fill all the pore spaces and then measuring the pressure necessary to expel this liquid. This measurement can help manufacturers fine-tune their materials for filtration of particles.

The future of face masks

Our Clayton testing facility is now fully operational and currently testing masks and mask materials. Visit our website for more information on the facility and booking our testing service.

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