Scoville Performance Neverstick - Super Strong Non-Stick. Best Non Stick Pans

*What do we mean by Neverstick 6x Stronger?

In January 2019 we commissioned an independent laboratory to run a series of tests to compare our pans to those of other manufacturers and see how much stronger we really are than some of the new ranges now in the market. Below you’ll find a detailed explanation of what we mean by ‘6 times stronger than other non-sticks’, an explanation of how we selected the sample, the methodology of the testing and the full set of results.

The Sample

To select an appropriate sample, we began by identifying the main players in the cookware market. Based on a market insight report conducted in 2017 by one of the world’s largest market research organisations, the largest brands specific to the cookware market in the UK were Tefal (29.5% market share), followed by Scoville, JML, Salter and Prestige. In addition to this, there are a number of retailer own-brand ranges, like those of Tesco and Debenhams, which together accounted for 50.5%.

It would obviously be impracticable to test every pan by every manufacturer, especially as product ranges undergo changes regularly, but we deliberately selected a wide sample for our tests in an effort to be as accurate as possible.

We selected 35 different pans in total, a (including some pans which are more expensive than ours) to emulate what a typical consumer would experience when buying a new pan. A full list of the pans we tested is below.

In total, we believe that our sample is representative of the cookware market.


The survivability of a coated surface is paramount to the strength and performance of non-stick coated frying pans, with failure of the coating amounting to a loss of non-stick properties.

Throughout its life cycle, a pan comes into close contact with objects, like kitchen utensils and other cooking implements, which can cause a pan’s non-stick capability to deteriorate. Cleaning, stacking and storage alongside other cookware items might also have that effect.

To investigate the coatings’ resistance to these, the independent lab used a scratch test method to determine the strength of each non-stick pan.

Scratch Resistance

A scratch test is a process of measuring a surface’s reaction to a pointed stylus being dragged across it. Testing in this way provides information on a material’s resistance to scratches and abrasions as well as how much force a surface can withstand before the non-stick coating is damaged. By increasing hardness as a function of distance, the point and method of failure can be determined.


The independent lab used a machine called a Teer Coatings ST200 scratch tester with a diamond-tipped probe (angle 120O and radius 0.2 mm) for the test. The initial load for the start of the test was 1 N at a loading rate of 40 N/min and a table speed of 5 mm/min.

Scratch marks were analysed by the lab using an Inspex HD 1080p Digital Microscope from point of continuous metal exposure.

The Results

The ‘failure force’ (measured in Newtons) shown in Figure 1 and Figure 2 represents the force that was required during the test to cause continuous metal exposure of the pan. As such, the higher the force required to cause metal exposure, the stronger the pan is deemed to be.

The ‘Scoville strength ratio’ shown in Figure 2 shows the multiple of how many times more force was needed to cause metal exposure on the Scoville Performance Neverstick+ pan versus each other pan tested. This ratio is simply a more convenient way of comparing how many times stronger the Scoville Performance Neverstick+ pan is versus each other pan tested.

Scoville Neverstick+ Resistance Table
Fig 2 | Scoville


In this lab test, the coating used for Scoville Performance Neverstick+ required at least 6 times more force to cause continuous metal exposure, meaning that it was shown to be at least 6 times as strong as the other pans we tested.


All information is factual at the time of posting, we update the sample as often as we can to give the most accurate data that we can provide.