The cut-resistant yarn structure (130,170) comprises a core-spun yarn (135) comprising a first cut-resistant core filament (132) and staple fibers (134) spun over the first cut-resistant core filament (132), a covering yarn (139) comprising a second cut-resistant core filament (136) and a first covering layer (138) wound over the second cut-resistant core filament (136), where the first covering layer (138) comprises a first filament and a second covering layer (140) wound over the core-spun yarn (135) and the covering yarn (139), where the second covering layer (140) comprises a second filament. The cut-resistant composite yarn structure can be used to manufacture cut-resistant cloth which may in turn be used to manufacture cut-resistant garments such as cut-resistant gloves, cut-resistant sleeves and other cut-resistant garments.

A woven fabric having warp yarns and weft yarns, wherein said warp yarns and said weft yarns comprise a core and a sheath, said core comprising a first core component and a second core component, wherein the first core component has a breaking tenacity, measured with DIN EN ISO 2062, of at least 6 g/den, more preferably of at least 10 g/den, more preferably of at least 14 g/den, even more preferably of at least 20 g/den, wherein the second core component comprises elastomeric elements, and wherein elasticity of the fabric in warp direction is at least 20% (measured according to ASTM D3107) and elasticity of the fabric in weft direction is at least 20% (measured according to ASTM D3107).

A thin coated supported glove and method of making the glove includes a thin knitted liner, including a plurality of finger components, a thumb component, a backhand component, and a palm component, wherein the thin knitted liner comprises a covered yarn including a tungsten core having a diameter of about 25-35 micrometers, a polyamide wrapping yarn disposed upon the tungsten core, and a high performance polyethylene wrapping yarn disposed upon the polyamide wrapping yarn, wherein the covered yarn is (350) denier or less; a second yarn, wherein the second yarn is an intermingled yarn of (115) denier or less; and a thin polymeric coating adhered to the thin knitted liner.

A silk blend ballistic fabric for creating comfortable and flexible bulletproof apparel includes a plurality of silk threads and a plurality of para-aramid fiber threads interwoven with the plurality of silk threads to create a fabric. An alternative embodiment of the disclosure generally comprises a hybrid thread comprising a silk thread and a para-aramid fiber thread twisted with the silk thread. The resulting hybrid thread can be woven to create the fabric. The resulting fabric is bulletproof and substantially flexible to create articles of clothing such as, but not limited to, trousers, shirts, and the like.

The present invention provides a highly functional polyethylene fiber exhibiting reduction of change in their physical properties in a wide range of temperatures for processing for products and in a wide range of temperatures for usage as products, thereby enabling improvement of dimensional stability. In addition, the present invention provides a highly functional polyethylene fiber exhibiting a high degree of dye exhaustion to be obtained in a simple dyeing operation, and excellent color fastness. The highly functional polyethylene fiber of the present invention is characterized in that an intrinsic viscosity [η] is higher than or equal to 0.8 dL/g, and not higher than 4.9 dL/g, ethylene is substantially contained as a repeating unit thereof, and a maximum thermal shrinkage stress is less than or equal to 0.4 cN/dtex in TMA (thermo-mechanical analysis), and a thermal shrinking percentage at 100° C. is less than or equal to 2.5%.

Cut-resistant and abrasion-resistant yarns including blends of technical fibers and mineral, inorganic, or ceramic fibers of substantially the same length as the technical fibers, and methods for manufacturing yarns, are disclosed.

A composite yarn. The composite yarn has a glass core having a linear weight ranging between 50 to 400 deniers and composing from 15 to 60% of a total linear weight of the composite yarn. The composite yarn has a sheath surrounding the glass core, where the sheath is constituted at least of fibers of meta-aramid. The sheath constitutes a remainder of the total linear weight of the composite yarn. The composite yarn has a yarn count between 10 tex and 80 tex.

Proposed are a high tenacity yarn and a method of manufacturing a glove using the same. More particularly, proposed are a high tenacity yarn capable of being knitted finely and thinly and having a high tenacity even if a metallic yarn is used as a core of a main yarn, and a method of manufacturing a glove using the same. To this end, the high tenacity yarn includes a core yarn and a covering yarn wound on a circumference of the core yarn. The core yarn includes a first core yarn part formed of a metal component and a second core yarn part formed of a metal component, and a total thickness of the first core yarn part and the second core yarn part is formed to be 0.07 mm or less.

A protective glove includes a primary yarn that forms the palm, thumb and finger sections of the glove. The primary yarn has an interior surface forming the interior surface of the glove, and an exterior surface forming the exterior surface of the glove. A plaiting yarn can be plaited to portions of the exterior surface of the primary yarn to form a plurality of enhanced sections on the exterior surface of the glove. The enhanced sections can have at least one substantially enhanced physical characteristic in relation to the primary layer.

Cut-resistant and abrasion-resistant yarns including blends of technical fibers and mineral, inorganic, or ceramic fibers of substantially the same length as the technical fibers, and methods for manufacturing yarns, are disclosed.