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The science of cut-resistant gloves


When you hear the words “cut-resistant gloves,” what comes to mind? If you picture thick, chainmail gloves, you’re not alone.To get more news about chain mail gloves, you can visit boegger.net official website.

However, many of today’s most cut-resistant gloves are just the opposite – thin, form-fitting and very comfortable. Yet, they can still repel blades. How is that possible?To understand the science behind cut resistance, picture a triangle with each point representing one element of cut-resistant technology: strength, hardness and rolling action. These three elements form the basis of cut-resistant technology.

On their own, each provides a base level of cut resistance, but once you start combining them, that’s when the cut resistance truly starts to add up.

To combine cut-resistant elements, you have to start at the very beginning – the yarn. Looking closely at a cut-resistant string-knit glove, it will appear to be made with only one yarn, but it’s actually a three-ply yarn that has been engineered to combine several elements into one.

Let’s take a look at how each element contributes to the overall cut resistance of the whole glove.The strength element refers to the inherent strength of the material used to produce the yarn. In terms of protective gloves, both para-aramid and high-performance poly ethylene (HPPE) are considered very strong fibers.

If those names sound strange, you’re probably more familiar with their brand names, such as Kevlar (para aramid) and Dyneema (HPPE). Although these fibers are extremely strong, on their own they typically produce gloves with an ANSI Cut Level 2, which is not very cut resistant; however, when combined with other elements from the cut-resistance triangle, they can produce yarn that offers the highest levels of cut resistance.