A glove made from a reinforced multilayer material can prevent cuts and/or abrasions. The glove can include and exterior layer and at least one interior layer, the interior layer consisting of an ultra-high molecular weight polyethylene filaments. While the interior layer can entirely cover a hand of a wearer of the glove, the exterior layer does not cover the index finger of the wearer, such that the wearer's dexterity, precision, and sensitivity in their index finger are improved.

The present invention is a disinfectant glove that prevents viruses from living on the surface of the embodiment thus preventing contamination. In particular, the invention allows a user to utilize gloves that kills viruses and diseases on contact. The proposed embodiment provides a unique experience for a user by providing a safe experience for the general public.

A liquid proof glove having impact protection comprises an outer glove portion comprising an outer fabric layer having an inner surface and an outer surface, a polymeric coating adhered to the outer surface of the outer fabric layer, and at least one protective structure adhered to at least one of the polymeric coating or outer fabric layer, or both. The glove further comprises an inner glove portion comprising an inner fabric layer having an outer surface and an inner surface and a liquid proof barrier layer adhered to the outer surface of the inner fabric layer. The liquid proof barrier layer is adhered to the inner surface of the outer fabric layer to join the inner glove portion to the outer glove portion.

Disclosed is a dipping composite material for enhancing the cut resistance of chemical-resistant gloves, wherein an additive is added to a latex, and the additive is a metal oxide and/or silica and/or glass fiber and/or basalt fiber and/or aramid fiber. The present invention improves the formula of a dipping layer such that the dipping layer has the cut resistance, which can significantly improve the cut resistant level of gloves.

A safety glove having a protective member or insert extending around the fingertip of the safety glove is provided. The protective member may be positioned along the outer surface or the inner surface of the glove. Alternatively, the protective member may be integrally formed between two layers of glove material. The protective member terminates distally from an interphalangeal joint line to enable finger flexion in order to grasp an item, such as a slab of meat to be deskinned in a skinning machine. The glove may include a rough outer surface formed from thrice dipping the glove and allowing the glove to cure. Additionally, the glove may have a width near the wrist that is wider than the width near the palm to enable the glove to be rapidly removed (i.e., doffed) in an emergency event of the glove getting caught in a rotating blade on the skinning machine.

A glove is provided that enables suppression of cracks in a coating layer containing nitrile butadiene rubber as a principal component. The glove comprises: a glove main body made of fibers for covering a wearer's hand; and a coating layer which comprises nitrile butadiene rubber as a principal component and coats at least a part of an outer face of a palm region of the glove main body, in which: the coating layer comprises zinc oxide and a cross-linked product of the nitrile butadiene rubber and polycarbodiimide; and a mass ratio of the polycarbodiimide to the nitrile butadiene rubber is no less than 0.002. The mass ratio of the polycarbodiimide to the nitrile butadiene rubber is preferably no greater than 0.09. The content of the zinc oxide with respect to 100 parts by mass of the nitrile butadiene rubber is preferably from 0.3 to 5 parts by mass.

The present invention relates to a novel animal glove training device. The device is designed to provide a modified glove for human use when interacting with puppies and other young animals. The device comprises a standard glove that has a leather stitched material on the palm side and fake fur on the back. Soft plastic and rubber strips line the outside of the fingers. Twisted chew ropes are wrapped between the finger portions. Squeaky toys are present inside the tips of the fingers, which are activated and make noise when a puppy bites them. An owner wears the gloves while engaging in play with or training their puppy.

A color splash effect is established by a darker backdrop color of an outer surface of a liquid proof and heat resistant glove in the event that a portion of the glove ruptures or fails. The color splash effect is accomplished by a lighter and brighter color being visible through the rupture in the glove. The lighter and brighter color may be formed on or as part of a protective member positioned beneath the outer layer. The protective member also protects the wearer against sharp objects contacting the outer layer of the glove and moving over the protective member. Some embodiments provide that the protective member is in a thumb crotch region of the glove.

An ultra-high molecular weight polyethylene fiber with ultra-high cut resistance includes an ultra-high molecular weight polyethylene matrix and carbon fiber powder particles dispersed therein. The content of the carbon fiber powder particles is 0.25-10 wt %. A method for preparing the ultra-high molecular weight polyethylene fiber with the ultrahigh cut resistance and a cut-resistant glove woven therefrom are further provided. The test proves that the glove woven from the ultra-high molecular weight polyethylene fiber with the ultra-high cut resistance is soft and comfortable, and does not have prickling sensation. According to the test of the Standard EN388-2003, the level of the cut-resistant grade ranges from 4 to 5.

Provided among other things is an polymeric protective garment comprising a layer of carboxylated polymer that incorporates an alumina-silica composition, thus forming a silica alumina polymer composite.