A housing of an electronic device according to various embodiments may include a woven material including TPU yarns, and a light emission module comprising light emitting circuitry, wherein light emitted from the light emission module may be directly transmitted through the woven material to display at least one piece of information about the electronic device.

A fabric for arc-protective garments includes first yarns and second yarns different from the first yarns. The first yarns include first modacrylic fibers, and the first modacrylic fibers contain an infrared absorber in an amount of 2.5 wt % or more with respect to a total weight of the first modacrylic fibers. The weight of the infrared absorber per unit area in the fabric for arc-protective garments is 0.05 oz/yd.sup.2 or more. An arc-protective garment includes the fabric for arc-protective garments.

A bimorph meta fiber is formed through spinning of two antagonistic polymer melts, one of which contains pre-compounded optical nanostructures, into an eccentric sheath-core configuration or a side-by-side key-lock configuration. The bimorph meta fiber is capable of an adaptive regulation of the infrared radiation responsive to humidity level deviation from a comfort zone or perspiration level of the wearer of the garment fabricated from the meta fibers. The bimorph meta fibers are humidity/heat trained to attain dynamical environmentally responsive behavior to maintain the humidity/thermal comfort zone at various the humidity level fluctuations.

A bimorph meta fiber is formed through spinning of two antagonistic polymer melts, one of which contains pre-compounded optical nanostructures, into an eccentric sheath-core configuration or a side-by-side key-lock configuration. The bimorph meta fiber is capable of an adaptive regulation of the infrared radiation responsive to humidity level deviation from a comfort zone or perspiration level of the wearer of the garment fabricated from the meta fibers. The bimorph meta fibers are humidity/heat trained to attain dynamical environmentally responsive behavior to maintain the humidity/thermal comfort zone at various the humidity level fluctuations.

Light-permeable multilayer composite film made of plastic as the surface coating of an article, wherein the composite film comprises at least one outer, at least partially light-permeable top layer optionally provided with a lacquer and at least one further layer arranged on the back of the top layer, wherein arranged on the back side of the top layer is at least one sheetlike, optically active textile layer, preferably a textile layer comprising threads made of polyethylene terephthalate (PET) and/or made of polyvinylidene fluoride (PVDF), wherein the textile layer has light-transmitting, light-refracting and light-reflecting properties or a combination thereof and the transmission, refraction and reflection properties are such that illumination of the textile layer, in particular back side illumination of the textile layer, results in preferably uniformized light transmission through the top layer.

A woven textile has one or more weavable threads and at least one lighting filament in which the weavable threads and the at least one lighting filament are woven together to form a textile with integrally woven lighting.

A woven textile has one or more weavable threads and at least one lighting filament in which the weavable threads and the at least one lighting filament are woven together to form a textile with integrally woven lighting.

A fabric substrate material is provided. The fabric substrate includes at least a first layer and a second layer. The first layer includes a first plurality of non-functional fill yarns and at least one functional fill yarn, and the second layer includes a second plurality of fill yarns. The second plurality of fill yarns and the at least one functional fill yarn exhibit substantially the same compressive strength, compressive resistance, or flexural strength. As such, the functional fill yarn in the first layer is protected from shrinkage or expansion and remains undamaged and functional after the fabric substrate is woven and subsequently handled or processed. The aforementioned practice of reinforcement described in the fill direction of the second layer can also be applied in the warp yarn direction, using the same principles described herein.

A greenhouse screen strips of film material that are interconnected by a yarn system of transverse threads and longitudinal threads by means of knitting, warp-knitting or weaving process to form a continuous product, wherein at least some of the strips comprise a film material in the form of a single- or multilayer polyester film is disclosed. The film material has a transparency of at least 93.5% and is provided with at least a first anti-reflective coating or layer on a first side of the film material.

A novel fabric combination is provided to absorb electromagnetic radiation (ER) and electromagnetic field (EMF) waves. The fabric combination may be shaped into a wearable garment or an electronics case or cover. The fabric combination includes carbon yarn or carbon pieces, elastic yarn, and a soft yarn, such a wool or cotton. No metals configured to reflect ER and EMF waves are used, such as silver. The elastic yarn is a carbon stretch yarn made up of synthetic elastic fabric, such as spandex, and carbon fibers. The fabric combination absorbs ER and EMF waves from the environment, produced by electric devices, such as phones, laptops, tablet computers, microwaves, ovens, robots, 4G, 5G, Wi-Fi radiation, Bluetooth, or any other device or environmental sources emitting ER and EMF.