A protective finger heat-guard and method of manufacture are disclosed. The protective finger heat guard includes a sleeve formed of a singular woven or non-woven material that defines a protective enclosure for receiving a finger of a user to insulate the finger from high-heat environments, such as during metal joining processes.

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 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.

An impact damper for a glove comprises a solid convex element formed from a resilient material. The convex element has a zenith cavity formed at its zenith. Upon an impact on the convex element, the zenith cavity enables resilient outward deformation of the convex element, and the resilient outward deformation dissipates energy from the impact. The impact damper may further comprise an outwardly deformable wall formed from a resilient material, with the wall circumferentially surrounding and spaced from the convex element. Upon an impact on the convex element, the convex element engages the wall as the convex element deforms, and resilient outward deformation of the wall under urging from the deforming convex element further dissipates the energy from the impact.

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 reinforced support device suitable for the protection of a hand and its digits from impacts, particularly those found in contact sports. The support device providing an outer skeleton and/or selected reinforcement portion(s), protects the digits of the hand and permits flexion of the fingers and/or thumb. The reinforcement portions can be of various shapes, sizes, materials, and weights. They may also be connected in various ways to one another.

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.

Disclosed are a pair of gloves having weights rigidly attached to outer surfaces of fingers and palm. The fingers may be partially cut off or have removable tips. At least several of the fingertips having crush resistant caps embedded within the outer layer of the fabric. A user may utilize touchscreen technology without remove the gloves as the outer layer of the gloves and liner are embedded with current conductive threading.

An impact damper for a glove comprises a solid convex element formed from a resilient material. The convex element has a zenith cavity formed at its zenith. Upon an impact on the convex element, the zenith cavity enables resilient outward deformation of the convex element, and the resilient outward deformation dissipates energy from the impact. The impact damper may further comprise an outwardly deformable wall formed from a resilient material, with the wall circumferentially surrounding and spaced from the convex element. Upon an impact on the convex element, the convex element engages the wall as the convex element deforms, and resilient outward deformation of the wall under urging from the deforming convex element further dissipates the energy from the impact.

A protective finger heat-guard and method of manufacture are disclosed. The protective finger heat guard includes a sleeve formed of a singular woven or non-woven material that defines a protective enclosure for receiving a finger of a user to insulate the finger from high-heat environments, such as during metal joining processes.