Cut Resistant Gloves
Cut resistant gloves are gloves designed to protect the wearer's hands from cuts while working with sharp tools. They can be divided into metal mesh gloves, cut and sewn, and seamless knitted gloves.
When it comes to cut-resistance ratings on personal protective equipment (PPE), all Level 5s are not created equal. There is significant confusion in global markets because many glove manufacturers misrepresent how they test their gloves, and the standard doesn't provide clear direction.
In the European market, gloves are evaluated according to EN388, the mandatory performance standard for all gloves as standardized and regulated by the CEN. The cut-test method, called the Coup test, uses a constant weight on a counter-rotating circular blade that is moved back and forth across a sample by the test machine. Ironically, this test, designed to measure cut resistance, is not suitable for materials that have a high degree of cut resistance as the materials that contribute to cut resistance (glass fibers, steel or hard guard plates) tend to dull the blade and overestimate the real world protection provided by such gloves.
The United States uses a different standard developed by ASTM: method F1790-04. This standard is similar to the ISO (13997) test. This test involves the interpretation of data obtained from putting varying pressure (weights) on a standardized razor-type blade and recording the distance the blade travels (at a constant speed) before cutting through. The ISO 13997 or the ASTM F1790-04 tests are the recommended methods by the EN388 standard to calibrate the cut resistance of high cut-resistant materials. In fact, it is noted in the EN388 documentation that the standard EN388 test is not applicable to gloves made from very hard materials (i.e., glass fibers, fibers mixed with steel, etc.). It further is noted that the alternative test method for high cut-resistant materials is described in ISO 13997.
If test results of various products identified as CE Level 5 products are taken and normalized on the ISO or ASTM test, you can see the relative test results of various types of products (see Figure 1 below). You will note that there are two bars on the graph for the CE 5 rating. This is because in tests by respected manufacturers, we find that CE Level 5 gloves offer a wide array of performance ranges. Some of these gloves score as low as 1,000 grams (10 newtons), qualifying them barely for a Level 3 on the ASTM/ISEA scale. Note that the force required to cut through is expressed as grams in the ASTM test and in newtons in the ISO test. These numbers can be converted for comparing the results on these tests (100 grams = .98 newtons).
100 PERCENT VARIABILITY IN CE 5 SCORES?
When normalized, we see that the scores of gloves claiming to be CE Level 5 gloves vary quite a bit. Why is this? There are several reasons for the variability, including testing consistency, operator variability and material variability. However, the single largest factor is this: While the EN388 standard suggests that the Coup test is not appropriate for materials that abrade the cutting wheel, the standard doesn't require the alternative ISO testing method be used.
Section 6.2 of the standard merely states that the test is not appropriate for hard materials like chain mail, but doesn't contemplate other hard materials like fiberglass. So some manufacturers, while knowing the test is not appropriate, use it anyway to get the higher score (and sell more gloves).
This is very common in gloves that are blended with fiberglass, as the fiberglass “fools” the Coup test by dulling the blade. The range of performance that gloves can score and still qualify for a Level 5 is so varied that the CEN body is going to require gloves to not only list their cut level, but to note their average newton force.
Why would they do this? Because they recognize that worker safety requires a better understanding of the real cut protection a glove is providing.
We can now conclude that all Level 5 gloves are not created equal. There is significant confusion in global markets because many glove manufacturers misrepresent how they test their gloves, and the standard doesn't provide clear direction.
HOW CAN YOU PROVIDE THE BEST PPE?
In our field studies of injuries and the corresponding hand protection worn, we see that many injuries can happen with PPE rated in the range below ASTM/ISEA Level 5 of 3,569 grams (35 Newtons). This easily can be demonstrated with a razor blade (simulating sharp metal or glass) and how easily typical CE 5 gloves will cut. As a result, many end users have adopted standards for their own organizations, specifying a minimum cut at a certain number such as 3,000 or 3,500 grams, a Level 4 or 5 ASTM. Keep in mind the standard is a guide; the profile of the hazard and actual use conditions are paramount. We always encourage conducting a safe test in actual situations such as adding new gloves, utilizing used gloves, saturating gloves with oils and fluids, etc.
MANY CUTS BEGIN WITH A PUNCTURE
Cut-resistance tests are just one element of what needs to be considered. Often punctures are misreported as cuts. A sharp edge, corner, burr or other protruding hazard can penetrate the glove and scrape or cut skin. With knit gloves, the hazard actually can poke through the open knit and cut the skin without cutting the glove.
So how does this happen? Depending on the density of the knit and gauge of the glove (the measure of the number of knitting needles per inch) and the thickness of the fibers, a glove may “window,” with the knit spreading apart, thus allowing a sharp point or blade to cut the hand. Plating with small guard plates can reduce this effect as the plates shield the knit structure from the hazards. The plates also lock in the knit and don't allow the knit to window.
Abrasion resistance also is a critical factor in preventing hand injuries. In fact, if a glove fails too early due to wearing through from an abrasive hazard, the skin quickly is exposed to cut hazards. So, the higher the abrasion level, the higher the level of protection from not just abrasion, but from cut and punctures. Other factors include:
Stability - Evaluate the performance of a new glove versus a glove that has been worn for a day. Look for products that don't degrade when exposed or used. Some products are affected when subject to abrasion, laundering or are exposed to UV light.
Wind-up risk - Some materials can be caught in machine parts such as rotating grinding wheels or drills and sanding materials. This can pull the hand or finger into the equipment and cause severe injury to tendons, muscles and ligaments and even amputation of fingers, hands and arms. Protective gloves that prevent or reduce windup risks are available and can be used where risks are present.
Fit - Gloves that are too tight may be cut more easily, as many of the fibers used for cut resistance use a rolling action to increase cut resistance. When these fibers cannot roll, such as when they are stretched from an ill-fitting or wrongly sized glove, they can “lose” some of their cut resistance. Take an example from the kitchen and do this simple experiment: Put a cucumber on a cutting board and take a very sharp knife. Try to cut the cucumber with a sawing motion without holding the cucumber. It just rolls and doesn't cut. Now hold that cucumber and do the same thing. It cuts very easily. So, tight fitting gloves can perform like the immobilized cucumber. Make sure your glove program accounts for proper sizing and employees know what to look for when picking gloves.
Coating - Coating impacts cut-resistant gloves that use cut-resistant fibers. Once the coating is applied, the rolling and twisting that helps the fiber achieve its cut resistance can be reduced. Most coated gloves have a higher cut-resistance on the back of the hand than on the palm because the fibers are not coated. Keep this in mind as you select your hand protection.
Grip - Using grip that isn't appropriate for the job can lead to higher injury rates as objects with sharp edges slip, causing slicing motion on the gloves.
EVALUATING GLOVE CHOICES
With all of this confusion (what tests are relevant today, what performance factors to consider) in the PPE market, what can be done to make sure that as safety professionals, we pick the best gloves for the job?
The ISO and ASTM tests offer a better approximation of what you are going to find in a real-world work situation. That combined with an assessment of “other factors” mentioned above is what you need for picking the correct PPE.
Heat Resistant Gloves
Are your hands constantly exposed to extreme temperatures at your workplace? Wouldn’t you like to know for a fact that you’re wearing the best heat-resistant work gloves for the risks you’re being exposed to? We want you to always have the peace of mind that you won’t get burnt while you’re on the job. However, since there are so many different types of heat-resistant gloves available on the market, we know that selecting the right pair can prove to be a bit of a challenge. So, to make the choice much easier for you, here are 5 expert tips to help you ensure that you’re wearing the best heat-resistant work gloves for your needs – whether you’re handling red hot glass or molten aluminum.
1. Measure the temperature of the object you’re going to be handling with an Infrared thermometer.
I can’t stress how critical this step is; if you don’t do this, you’ll choose the wrong glove without a doubt. These thermometers only cost $20 on Amazon—which, in my opinion, is well worth the cost of preventing second- or third-degree burns. Often we will visit a manufacturer who claims that they need a glove to handle a part that is 1500 degrees F. However, when we actually get on the floor and measure the part, often the temperature is 50% less than what they’ve estimated. One of the major problems with this is that a glove that can handle 1500 degrees F is much bulkier and more expensive than a glove that can handle 800 degrees F; to improve the level of safety and keep the cost down, it’s crucial that you choose a glove based on the correct temperature. Wow, look at that – you’ve gotten your investment in your $20 infrared thermometer back already! Conversely, you can imagine what the detriment is when you under-estimate the temperature of the objects being handled.
2. Ensure your gloves have the right level of insulation.
Heat-resistant gloves should always be tested to ASTM F1060-87, which is called Conductive Heat Resistance Classification (also known as C.H.A.R.). Simply put, this test tells you the maximum temperature at which you can hold an object for more than four seconds before feeling pain, and for more than 15 seconds before getting a second-degree burn. I’ve foolishly tried this myself, and the test results are shockingly accurate. Prioritize insulation: protect those digits!
3. Double check the C.H.A.R. temperature of the outer material.
Sometimes you can choose a glove with adequate insulation for a given temperature, but the outer material won’t stand the heat over the long term and start to char and break down. This not only puts you at a much higher risk of getting burned, but the money you’ve spent on the wrong pair of gloves will also be wasted.
Here is a list of approximate C.H.A.R. temperatures for common glove materials. Refer to this chart to ensure that you’re wearing gloves made of an appropriate material for the level of heat you’ll be coming into contact with!
4. Don’t forget about dexterity!
Once you’ve narrowed down your selection, choose the glove that not only fits the best, but that will provide you with the most dexterity. Can you handle the tools required for the job as you normally would with the glove you’ve chosen? Do you have a good grip? If not, the job itself may require some re-engineering, since you obviously don’t want to skimp on the heat insulation required to protect your hands!
5. Consider all of the hazards – not just the heat.
Are there other hazards besides extreme temperatures in your workplace? For example, if you’re handling molten metal, you’ll want a glove with an aluminized back to reduce radiant heat transfer and better protect you and your clothing from metal splash. Are you dealing with hot oils and a fryer? You’ll need a glove that is liquid proof. Are there serious cut hazards involved?