Prevent electrostatic damage: Principle: Nitrile gloves use blending technology to evenly disperse nano-scale fillers such as carbon nanotubes and conductive carbon black in the rubber matrix to form an “electrostatic flow network” that can quickly conduct human static electricity to the ground. Its surface resistivity is controlled at 10⁶-10⁹Ω, meeting the anti-static standard requirements. At the same time, plasma etching technology is used to form a micro-nano concave-convex structure on the surface of the gloves, which reduces the contact area between the gloves and the object by 70% and reduces the probability of static electricity generated by friction by 90%.
Application scenarios: In electronic maintenance, when maintenance personnel come into contact with computer motherboards, hard drives, graphics cards and other precision electronic components, wearing diamond-patterned nitrile gloves can prevent human static electricity from causing damage to the components such as breakdown. In the semiconductor industry, from wafer cutting to packaging and testing, many processes such as photoresist coating and ion implantation, operators wearing these gloves can effectively avoid static electricity from damaging precision components such as chips and improve product yield.
Provide good touch and operational flexibility: Principle: Diamond-patterned nitrile gloves are designed according to ergonomic principles and can fit the curve of the hand tightly. The distribution of diamond patterns will not affect the flexible movement of fingers. Users can accurately grasp and operate tiny electronic components, just as sensitive as touching them directly with their hands.
Application scenarios: When welding tiny electronic components and plugging and unplugging chip pins, electronic maintenance personnel can accurately complete the operation with the sensitive touch of gloves, thereby improving maintenance efficiency and quality. In semiconductor manufacturing, workers also need this good touch and operational flexibility when performing chip packaging, testing and other processes to ensure the accuracy of the operation and reduce product damage caused by operational errors.
Prevent chemical pollution and corrosion: Principle: Nitrile material has good chemical stability and can effectively block a variety of chemicals, such as acids, alkalis, greases, solvents, etc. Application scenarios: In electronic maintenance, some chemical cleaners, flux, etc. are often used. Diamond-patterned nitrile gloves can prevent these chemicals from harming the hands, and at the same time prevent chemicals from being contaminated on electronic components, causing corrosion or other damage. In the chip manufacturing process of the semiconductor industry, a variety of chemical reagents are involved, such as photoresist developer in the photolithography process and etchant in the etching process. Operators wearing diamond-patterned nitrile gloves can prevent chemical reagents from contacting the skin, ensure the safety of the hands, and avoid chemical reagents from contaminating chips or other precision equipment.
Have certain wear and tear resistance: Principle: Diamond-patterned nitrile gloves are made of high-quality nitrile rubber, which has high strength and toughness. At the same time, the diamond pattern design not only increases the friction of the gloves, but also optimizes the structure of the pattern, so that the gloves can disperse pressure when contacting objects and reduce local wear. In addition, most gloves will thicken high-frequency contact parts such as fingertips, which further improves the wear resistance.
Application scenarios: In the process of electronic maintenance and semiconductor production, workers may come into contact with some sharp tools or parts, such as tweezers, chip pins, etc. The wear resistance and tear resistance of diamond-patterned nitrile gloves can prevent the gloves from being scratched and avoid hand injuries. At the same time, it can also ensure the protective performance of the gloves and reduce the risk of component contamination or damage caused by glove damage.
Post time: Jun-11-2025