Abstract: It is disclosed a textile fabric comprising a first set of electrically conductive and externally isolated yarns (22) separated by isolating textile yarns (24); a second set of non-isolated conductive yarns (23); a plurality of textile yarns interlacing the first and the second set of yarns (22, 23), wherein part of the interlacing textile yarns are non-isolated conductive yarns (23) in order to form an electrical grounding grid with the non-isolated conductive yarns (23) of the second set of yarns and part of the interlacing textile yarns are isolating textile yarns (24).

Abstract: Provided is a garment comprising fabric and at least one seam, said garment comprising at least one vibrotactile actuator configured for producing a vibrational pattern based on audio and/or messaging information provided by an information signal from an external device. The vibrotactile actuator is contained within the seam. Also provided is a system, circuit and method for transmitting audio and/or messaging information to a user. The system comprises the garment, the external device, and a conversion unit comprising a microcontroller that converts the audio and/or messaging information into a driving signal to be provided to the vibrotactile actuator. The circuit comprises the microcontroller and the vibrotactile actuators coupled to one another by a ribbon of a flexible material. The method evaluates the delay between the vibrational pattern produced by the vibrotactile actuator and acoustic and/or visual signals produced by the external device based on the audio and/or messaging information.

Abstract: A system for transmitting signals from a garment to an analysis device, is provided. The system includes a button attachable to the garment by means of a pin passing through a hole arranged in a garment coupling portion to be clamped between a head of said pin and a button coupling surface. The button coupling surface includes an electric contact connected to at least one integrated circuit contained in the button for performing analog and digital processing of signals coming from at least one garment sensor. The button contains a wireless module for communicating data between the button and an analysis device. The garment coupling portion is provided with at least one conductive trace arranged on its surface and which faces the button coupling surface. The electric contact is arranged in order to contact at least one conductive trace.

Abstract: It is disclosed a stretchable touchpad (10) of the capacitive type including a stretchable textile fabric (20) having a plurality of conductive elements incorporated therein. The conductive elements are resistive strain gauges (30, 40) which form electrodes to detect a change of capacitance caused by a touch. It is also disclosed a method for operating a stretchable touchpad (10) comprising the steps of measuring continuously a capacitance analog signal provided by a resistive strain gauge (30, 40) of the stretchable touchpad (10); and comparing the measured capacitance signal with a threshold value in order to determine whether or not a touch has taken place, wherein the threshold value is continuously adjusted as a function of the actual measurement of capacitance and as a function of the resistance of said resistive strain gauges (30, 40) which form the capacitor electrodes of said touchpad (10).

Abstract: A wearable device and a method are disclosed for determining induced voltage exposure of a human body to low voltage fluctuations or induced static electricity variation on human body. The wearable device includes conductive elements which form at least part of an antenna and comprises an RF-to-DC converter connected to the conductive elements of the wearable device for harvesting RF energy and induced static electricity variation at the input in the form of an AC voltage (Vin), while the RF-to-DC converter provides a DC voltage (Vout) at the output. The wearable device also comprises a control unit connected to the output of the RF-to-DC converter to determine the induced voltage exposure of a device wearer's body.

Abstract: A needle clamp (1) for sewing machine (100) is provided. The needle clamp (1) comprises a body (2) at least partially made of a thermally conductive material and having retaining means (3) for constraining at least one needle (10). The needle clamp comprises a thermoelectric cooling device (5) directly or indirectly constrained to a portion of said body (2).

Abstract: It is disclosed a woven textile fabric comprising a first and a second electrically conductive layer (20; 30) of interwoven conductive yarns (22, 24; 32, 34) and a first intermediate pseudo-layer (40) of structural and insulating yarns (45) comprised between the first and the second electrically conductive layer and a plurality of binding yarns (47) interlacing the first and second conductive layers (20; 30) and the intermediate layer (40). The structural yarns (45) and the binding yarns (47) have piezoelectric properties.

Abstract: It is disclosed a composite yarn structure (10) comprising: —a first element (15) comprising a coaxial flexible bi-component monofilament including a conductive component (20) and a thermoplastic component (30) exhibiting piezoelectric properties, —at least a second element (40) twisted around the first element (15), wherein the second element (40) has a lower elasticity with respect to the elasticity of the first element (15) such that, upon elongation of the yarn structure (10) in a first direction, the yarn structure (10) expands in a second direction, whereby the dimensions of the yarn are increased both in first and second directions to generate an additional force on said piezoelectric component of the first element.

Abstract: The disclosure provides a compression garment (68) formed of a stretchable fabric (10) with a uniform, i.e. constant, elasticity but in which the compression garment provides different degrees of garment compression when worn by a wearer due to geometric cuts (6, 8) made to the fabric to form one or more fabric panels (2, 4) that extend the entire length of the circumferential portion (60) of the garment. The circumferential portion surrounds a wearer's body part (66) and includes degrees of compression that vary at different locations (12, 14, 16, 18, 20, 22, 24, 26), along the axial direction (62). The geometric cuts produce non-linear edges (6A, 6B, 8A, 8B) and are made to provide different circumferential lengths (12F, 14F, 16F, 18F, 20F, 22F, 24F, 26F) of fabric that produce desired compression levels at various axial locations, and are calculated using formulas and algorithms that take into account various factors relating to the fabric and the garment being formed.

Abstract: A real-time motion capture system and garment includes a wearable activity monitor that may be a pair of denim jeans. The wearable activity monitor includes multiple sensors such as accelerometers, gyrometers, magnetometers disposed within the seams of the garment. A microprocessor and wireless transmitter) communicate the motion data to an external device. The microprocessor and wireless transmitter may be included within one of the seams. An elastically stretchable ribbon or a flexible ribbon such as a kapton ribbon or a ribbon formed of textile, electrically couples the sensors and microprocessor and is also disposed inside the seams and the components within the seam are coated with a waterproof coating. The external device can store the data or display and analyze the data real-time, and may communicate the data to a further electronic device.

Abstract: A unique multi-functional emergency bandage stops bleeding by: (1) optimizing mechanical properties and preventing ischemia and/or necrosis while applying enough pressure to help stop bleeding, and (2) incorporating inorganic anti-bleeding nano-structures (embedded within a gauze and/or microbial cellulose) with almost infinite life-time. Additionally, pathogen passage through the bandage is prohibited (via an intermediate filter layer). Together with the overall anti-microbial character of the bandage, the unique multi-functional bandage offers all these vital features within a single design. The unique bandage can be applied by using a single hand and bandaging direction can be changed using a unique binding apparatus.

Abstract: The present invention relates to the use of indigo derivatives for dyeing synthetic textiles to a process for dyeing synthetic textiles and to dyed textiles and articles containing them. The invention also relates to novel indigo derivatives per se and to a process for the preparation thereof.

Abstract: Provided are novel compounds of indigo-derivatives as irreversible color changeable dyes. Also provided are methods for the use of various indigo-derivatives for irreversibly color changeable dyes for textile materials and to novel compounds. Also provided is a process for dyeing textile materials, especially denim, with indigo-irreversible color changeable dyes and for textiles and garment articles made by the dyeing process for textile materials.

Abstract: Provided is a composite fabric having a base fabric and at least one bacterial biopolymer layer. The base fabric is a woven fabric, and includes warp yarns and weft yarns. At least a first plurality of warp yarns and a first plurality of weft yarns form a base layer of the base fabric. A second plurality of warp yarns and/or a second plurality of weft yarns forms an additional layer of loop portions on at least one of the sides of the base fabric. The bacterial biopolymer layer is provided at least on part of the additional layer. Further provided is a process for the production of the composite fabric and a clothing article formed of the composite fabric.

Abstract: Disclosed is a wearable step counter system comprising a garment for a wearer's legs, a capacitive electrode and a microcontroller, said garment comprising a textile fabric portion, said capacitive electrode comprising an electrically conductive yarn woven into said textile fabric portion, said textile fabric portion being arranged on said garment for providing a parasitic capacitive coupling between said capacitive electrode and a wearer's leg, said microcontroller being electrically connected to said capacitive electrode for evaluating said parasitic capacitive coupling so that the relative movement between the wearer's legs is detected by the microcontroller.

Abstract: The present invention provides a process for the production of a fabric having a unique appearance and the fabric so obtained. Also provided is the clothing articles, i.e. garments, including the fabric. More particularly, the present invention relates to a process for producing a woven fabric having a unique, e.g. “used” (i.e. worn-out) or “multi-shaded” appearance and the process includes a step of providing a woven fabric with a layer of bacterial biopolymer, dyeing at least part of the fabric together with the biopolymer layer, and then removing at least part of the bacterial biopolymer layer from the fabric.

Abstract: Provided is a process for the production of a dyed fabric using enzyme aggregates. In particular, provided is a process that comprises a step of providing a woven fabric that comprises a base layer and an additional layer which is located on at least one side of the fabric, wherein the yarns of the additional layer comprise fibers that are at least partially dyed, and a step of contacting the woven fabric with enzyme aggregates such as cross-linked enzyme aggregates (CLEAs), to remove at least part of the dye from at least the yarns of said additional layer. The disclosure also provides a fabric obtained with the process and garments including the fabric.

Abstract: A fabric comprising at least one conductive element to define at least one portion of an electric circuit, and a sensor coupled to said conductive element, wherein the sensor comprises a degradable element configured to at least partially degrade in preset conditions to change an electric feature of said sensor. An article comprising the fabric and a process for monitoring the life-cycle of the fabric are also disclosed.

Abstract: A unique multi-functional emergency bandage is introduced, wherein bleeding is stopped by: (1) optimizing mechanical properties and preventing ischemia and/or necrosis while applying enough pressure to help stop bleeding, and (2) incorporating inorganic anti-bleeding nano-structures (embedded within a gauze and/or microbial cellulose) with almost infinite life-time. Additionally, pathogen passage through the bandage is prohibited (via an intermediate filter layer). Together with the overall anti-microbial character of the bandage, the unique multi-functional bandage offers all these vital features within a single design. The unique bandage can be applied by using a single hand and bandaging direction can be changed using a unique binding apparatus.