TEGERA Leather Glove 134

Standards and labels

• EN 420:2003+A1:2009

  EN 420:2003+A1:2009 is a European standard that sets out the general requirements for hand protection, including comfort, fit, and dexterity. Performance requirements include resistance to abrasion, cut, tear, puncture, and impact. Test results should show the gloves meet these requirements.

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• EN 388:2016

  EN 388:2016 is a European standard for measuring the performance of protective gloves against mechanical risks (abrasion, cut, tear, and puncture). The standard includes test methods and performance requirements for gloves to be considered compliant. Test results are reported using a series of four numbers, each representing the performance level achieved in one of the tests.

  Test results

  Abrasion Resistance Level 3

  EN 388:2016 is a European standard that provides guidelines for assessing the protection levels of gloves against mechanical risks, such as abrasion, cuts, tears, and puncture. The Abrasion Resistance Level 3 indicates a higher level of protection, signifying that the gloves can resist more intensive wear from rough materials. According to the standard, the abrasion resistance test involves rubbing the glove material against sandpaper under a specified pressure until it is worn through. Level 3 abrasion resistance requires that the gloves withstand 2000 to 7999 cycles of abrasion. This enhanced level of durability is appropriate for tasks involving more frequent or more intense contact with abrasive surfaces, such as construction work, woodworking, and handling building materials. Gloves with Level 3 abrasion resistance offer a robust barrier against wear, extending glove life and providing increased protection for the wearer’s hands, thus reducing the risk of injuries in more demanding work environments.

  Tear Resistance Level 2

  EN 388:2016 is a European standard that sets criteria for testing the mechanical risks for protective gloves, including abrasion, cut, tear, and puncture resistance. The Tear Resistance Level 2 designation indicates that the gloves have a moderate level of resistance to tearing. The test for tear resistance involves subjecting a sample of the glove material to a force until it tears, and the force required to initiate and propagate the tear is measured. Gloves that achieve Level 2 tear resistance can withstand between 25 to 50 Newtons of force. This level of tear resistance is suitable for tasks where gloves might face moderate stresses that could cause tearing, such as general handling and light industrial work where sharp or jagged materials are handled less frequently. These gloves provide reliable protection and durability in scenarios where some degree of mechanical risk is present but not excessively severe.

  Puncture Resistance Level 2

  The standard EN 388:2016 includes an assessment of Puncture Resistance, where Level 2 signifies that the material has met specific criteria for resistance against puncture. The result of Level 2 in puncture resistance means that the protective glove or material can withstand a force of 60 to 100 newtons before being punctured. The test method used involves using a standardized steel puncture probe that is pushed against the material at a specified speed until it pierces through it. In essence, achieving a Level 2 puncture resistance under EN 388:2006 suggests that the protective equipment offers moderate protection against punctures, making it suitable for environments where there is a risk of encountering sharp objects such as needles, but are not excessively sharp or exert very high force.

  Cut Resistance, ISO 13997 Level C

  The EN 388:2016 standard comprehensively addresses the cut resistance of gloves, using the ISO 13997 test method, where achieving Level C indicates that the glove can withstand forces between 10 to 14 newtons during cutting. This level of cut resistance provides an intermediate level of protection against cuts, suitable for handling tasks where there is a significant risk of cuts from sharp objects but where the highest level of cut resistance isn't necessary. The ISO 13997 test itself is a more detailed and clear manner to assess material cut resistance under a straight-edge blade under varying load, unlike the Coup Test used previously, which could blunt the blade. Essentially, Level C gloves are designed for robust hand protection in environments where cut hazards are considerable but not at the most extreme end of the scale, making them suitable for industries like construction and manufacturing where sharp tools and materials are frequently handled.

• EN 1149-2:1997

  EN 1149-2:1997 is a standard for electrical arc protection for protective clothing. It establishes performance requirements for materials and garments used in protective clothing to protect against electrical arcs. The standard includes tests for measuring the arc resistance, material flammability, and garment construction. Possible test results include pass/fail for each of these categories.

  Test results

  Performance Tested

  The EN 1149-2:1997 standard is designed to assess the electrostatic properties of protective clothing, specifically measuring the electrical resistance through a material, referred to as vertical resistance. Evaluating the test result involves determining how well the protective fabric can prevent a build-up of static electricity, which is vital for safety in environments where electrical discharges could pose a fire or explosion risk. The test method includes applying a voltage across a fabric sample while it is sandwiched between two electrodes, and the resistance is measured at both high and low voltage levels to ensure accuracy. Businesses must consider this result when selecting protective clothing for environments with potential electrical hazards, ensuring that the material has adequate resistance to prevent static electricity build-up and provide a safeguard against electrostatic discharges in volatile work conditions.

• EN 407:2004

  EN 407:2004 is a European standard that specifies the safety requirements for protective gloves for thermal risks. It sets rules for the design, construction, and testing of gloves that protect users from heat and fire. Testing includes measurements of contact heat, convective heat, radiant heat, small splashes of molten metal and flame resistance. The standard also includes requirements for labeling and instructions for use. This standard is an updated version of EN 407:1994 and it's intended to protect the users against thermal risks, such as heat and flame, and to help them to choose a suitable glove for their specific application.

  Test results

  Molten Metal Resistance Level X

  EN 407:2004 is a European standard that provides specifications for protective gloves to safeguard against thermal risks, including the exposure to molten metals. The designation Molten Metal Resistance Level X indicates that the gloves have not been tested for this specific risk, or they failed to meet the minimum requirements set out in the standard for protection against molten metal splashes. This means that the gloves are either unsuitable for use in environments where there is a risk of contact with molten metals, or additional testing is required to determine their suitability. Typically, such a classification implies that the gloves should not be used for handling molten metals and should only be considered for other types of thermal risks specified in the standard, where molten metal exposure is not a concern. This classification helps in ensuring that users select the right type of glove based on the specific hazards present in their working environment, thereby preventing inappropriate use and enhancing safety.

  Radiant Heat Level 3

  EN 407:2004 is a European standard that outlines the performance requirements for protective gloves intended to shield against various thermal risks, including radiant heat. Radiant Heat Level 3 signifies a higher degree of protection, indicating that the gloves are designed to effectively delay significant heat transfer from a radiant source. This level ensures that the gloves can protect the wearer for a minimum of 50 seconds before the temperature inside the glove increases. The test method involves exposing the glove to a controlled source of radiant heat and measuring the duration it takes for the heat to penetrate through the glove material to the point where it increases the inner temperature to a defined threshold. Gloves achieving Level 3 protection are suitable for more intense radiant heat environments, such as those found in steel mills, glass handling, and other industrial settings where substantial exposure to high levels of radiant heat occurs regularly. This enhanced protection is critical for maintaining safety and preventing thermal burns during prolonged exposure to high temperatures.

  Burning Behaviour Level 4

  Level 4 requires the material to have an afterflame time of no more than 2 seconds and an afterglow time of no more than 5 seconds after exposure to flame. This level offers substantial protection for handling or exposure to fire, suitable for environments where there is a significant risk of intense and immediate contact with flames.

  Heat Contact Level 1

  The standard EN 407:2004 on Protective gloves against thermal risks, including the testing for contact heat at Level 1, is designed to assess the protection level of gloves when exposed to thermal hazards. A Level 1 result on the contact heat resistance indicates basic protection where the glove can delay the transfer of heat from a contact source at 100°C for at least 15 seconds before the inside of the glove reaches a temperature increase of 10°C. The test method involves placing the outer surface of the glove in contact with a hot probe of defined dimensions and temperature, while the rate of temperature rise of a calorimeter on the inside of the glove is measured. This measurement provides a straightforward metric for assessing the thermal protection offered by the glove at low-level exposure. Practically, gloves rated at Level 1 for contact heat are suitable for environments where exposure to thermal risks is minimal and not excessively severe, making them adequate for certain low-risk industrial, laboratory, or handling applications where brief contact with warm objects is common.

  Heat Convection Level 2

  The EN 407:2004 standard, specifically concerning Heat Convection result at Level 2, measures the performance of protective gloves against heat and/or fire. With a Level 2 convection heat test result, it indicates that the gloves have a moderate level of protection against heat transferred through convection. This result correlates to an exposure to convective heat at a predefined level, which in Level 2 typically offers thermal resistance for a minimum of 5 seconds before the glove’s inner temperature increases by 24°C. The test method used involves circulating hot air around the glove, and measuring the time taken for the temperature inside the glove to rise by a specific amount (typically 24°C). This result is crucial for professionals working in environments where moderate exposure to convective heat is expected, helping them choose gloves that provide adequate protection while ensuring usability and dexterity. Such protective gloves are generally used in industries like industrial baking, glass operations, and certain chemical processes where hot vapors or similar conditions might pose risks.

  Metal Splash Resistance Level 4

  EN 407:2004 is a European standard focused on assessing the protective capabilities of gloves against thermal risks, including hazards such as molten metal splashes. Metal Splash Resistance Level 4 represents an advanced level of protection, where the gloves are designed to handle substantial exposure to molten metal. This performance level signifies that the gloves can effectively resist at least 35 droplets of molten metal, protecting the wearer without the metal penetrating the glove material significantly. The testing involves simulating conditions where molten metal is splashed onto the glove, assessing the glove's ability to prevent molten metal from sticking and causing burns. Gloves that achieve Level 4 are ideal for heavy industrial applications such as steel mills, foundries, and welding, where frequent and substantial contact with molten metal occurs. This level of protection is crucial for maintaining safety and preventing serious injuries in environments with high thermal risks.

• EN 12477:2001/A1:2005

  EN 12477:2001, along with the amendment A1:2005, is a European standard that specifically addresses protective gloves for welders. The standard sets requirements and test methods for gloves designed to protect the hands and forearms from heat and splatter during welding operations. The amendment A1:2005 introduces updates and refinements to enhance the performance and reliability of the gloves, ensuring improved protection for welders. It may include additional requirements for factors such as dexterity, grip, and durability. Compliance with EN 12477:2001 and its amendment ensures that welders have appropriate gloves that meet the necessary safety standards.

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• CE Marking

  CE Marking is a label that shows a product meets certain safety and environmental standards set by the European Union. To get the CE Marking, a company must test and certify their product meets these standards. CE Marking is required for many products sold in the EU, including electronics, machinery, toys and medical devices. It helps ensure that products are safe for consumers and the environment, and allows for easy trade within the EU.

• PPE Category 3

  PPE stands for "personal protective equipment." PPE Category 3 refers to equipment that is complex and provide the highest level of protection such as powered respirators, SCBA, and full body suits. In Europe, PPE Category 3 must meet certain safety standards set by the European Union, which means that it must be designed and manufactured to protect the user without causing harm. Companies that make or sell PPE must prove that it meets these standards. They also must have a quality management system in place, have to be audited regularly by a notified body and have to have a technical documentation.