The invention addresses the problem of providing a cloth and a protective product, which are excellent not only in flame retardancy but also in protection performance against electric arcs, and can further be provided with any color appearance. As a means for resolution, in a cloth including a flame-retardant fiber, a UV absorber or carbon particles are contained in the cloth, and the cloth is configured to have a lightness index L-value of 25 or more.

A shielding device for shielding against weather influences that includes a textile sheet material which is stretched two-dimensionally or can be rolled out and which forms a shield against weather influences, in particular, against solar radiation and/or rain. The textile material has warp threads and weft threads connected together in a lattice-like manner so as to form a fabric. A foam layer which has foam pores that are separated from one another by solid foam walls is applied onto the textile sheet material on at least one side of the textile sheet material.

The present invention relates to a light shielding net, which can improve productivity by facilitating a weaving process, can be wound by a winding device due to a high winding strength, and can express various colors, thereby adjusting a light shielding amount and improving a design aesthetic sense. To this end, a warp yarn is made of a PE monofilament, the weft yarn is made of a PE film, and the two warp yarns are repeatedly woven in a Leno weave form surrounding each weft yarn.

A weather-resistant fabric is disclosed made from highly texturized multifilament synthetic polymer yarns. The yarns have a relatively large size or denier and are woven in a manner that produces a fabric with wool-like characteristics. The weather-resistant fabric is particularly well suited as an upholstery fabric for outdoor furniture.

The present disclosure provides a method for processing an all-polyester fiber cotton-like fabric with sunlight resistance. The method includes: 1) weaving a PTT/PET bicomponent composite stretch yarn into a fabric; 2) dyeing processing the fabric; and 3) finalizing and finishing, wherein the finalizing and finishing comprises: a) preparing a finishing liquor obtained by mixing a crosslinking agent and an emulsion of benzophenone-containing polyorganosiloxane; b) padding the fabric; and c) drying and finalizing at a high temperature.

The invention relates to a weatherproofing arrangement having a textile sheet material which forms a screen against the effects of weather, in particular against solar radiation and/or rain, and has warp threads and weft threads connected to one another in the manner of latticework. In order to achieve particular protective functions, it is proposed for the warp threads and weft threads to bound elongate-rectangular latticework openings, wherein the length of these openings is at least 10 times the width thereof, and wherein the width of the openings is from between 0.1 and 0.001 mm.

A woven shielding textile includes a set of weft yarns and a plurality of warp yarns, including a set of primary warp yarns and a set of secondary warp yarns. The set of primary warp yarns and the set of secondary warp yarns are selectively interlaced with the set of weft yarns using a double beam weaving system such that the woven shielding textile is warp-faced. A face surface is predominantly composed of the set of primary warp yarns and a back surface is predominantly composed of the set of secondary warp yarns, while the plurality of warp yarns alternates between the set of primary warp yarns and the set of secondary warp yarns. A substantial percent of light incident to the woven shielding textile does not pass through.

The present disclosure is generally directed to a covering for architectural features, which may include windows, doorways, archways, and the like, where the covering includes a panel made from a light diffusing material. The light diffusing material is designed and engineered to allow a significant amount of light to pass through the material for providing a desired visual effect while having improved dimensional stability. The covering may contain a light diffusing material that extends along a first direction of the covering (e.g., vertically). The light diffusing material may have an openness factor of about 60% or greater and contain pillars extending in the first direction and bridges extending between the pillars. Each pillar may contain at least two yarns, and each bridge may contain at least one yarn.

A covering for an architectural feature includes a woven material. The woven material is made at least partially from binder yarns to form a woven fabric. The binder yarns are heated after the fabric is woven to a temperature sufficient to cause the binder yarns to bond and fuse to adjacent yarns at crossover points. The woven material is inherently resistant to fraying and/or unraveling.

The present disclosure is generally directed to a covering for architectural features, which may include windows, doorways, archways, and the like, where the covering includes a panel made from a light diffusing material. The light diffusing material is designed and engineered to allow a significant amount of light to pass through the material for providing a desired visual effect while having improved dimensional stability. The covering may contain a light diffusing material that extends along a first direction of the covering (e.g., vertically). The light diffusing material may have an openness factor of about 60% or greater and contain pillars extending in the first direction and bridges extending between the pillars. Each pillar may contain at least two yarns, and each bridge may contain at least one yarn.