Fiber emitters, such as carbon nanotube (CNT) yarns, are used to create infrared (IR) transmitters that can operate at high data rates, can shift spectral response, and can emit polarized light, for example by alignment of the fiber emitters in close proximity and in parallel directions. These fiber emitters can, for example, be used in patches that can be bonded to fabric or to an object, or can be woven into fabric during fabrication of a textile. The fiber emitters can be used in a variety of methods, including for friend or foe identification, communications, and identification of objects.

A method measures inside a blanket of mineral and/or plant fibres being moved by at least one conveyor with a conveyor belt. The method uses a measuring system including a sensor and an actuator for introducing the sensor into the blanket, the actuator being mounted on the conveyor belt and able to move the sensor between a retracted position and a measuring position inside the blanket. The method also includes introducing the sensor into the blanket by the actuator under the effect of the movement of the conveyor belt.

Fiber emitters, such as carbon nanotube (CNT) yarns, are used to create infrared (IR) transmitters that can operate at high data rates, can shift spectral response, and can emit polarized light, for example by alignment of the fiber emitters in close proximity and in parallel directions. These fiber emitters can, for example, be used in patches that can be bonded to fabric or to an object, or can be woven into fabric during fabrication of a textile. The fiber emitters can be used in a variety of methods, including for friend or foe identification, communications, and identification of objects

A device measuring the fineness and/or maturity of cotton fibers contains a measuring chamber accommodating a cotton fiber sample and a tubular plunger. The measuring chamber extends between a first end closed by a wall having one or more vent holes and a second end opposed to the first end and hermetically closed. The plunger penetrates within the measuring chamber through the second end to run at least two strokes of predetermined lengths and has an inner channel extending between a tail portion and a perforated head portion placing the inner channel in fluid communication with the measuring chamber. The device further contains a reservoir placed upstream of the inner channel and in fluid communication with the inner channel; a pump filling the reservoir with air from an environment; and a flow regulator placed downstream of the reservoir and upstream of the inner channel. The flow regulator doses the air accumulated in the reservoir into the inner channel, and consequently into the measuring chamber, with a predetermined flow rate.

A fiber testing instrument having a fiber loading station that is sized to accommodate a fiber sample within a desired size range, a fiber extraction device for extracting a portion of the fiber sample for a first battery of fiber tests, a fiber transport device for conveying at least the remaining portion of the fiber sample, and a micronaire chamber for receiving the conveyed fiber sample, where the micronaire chamber is sized to test any fiber sample within the desired size range.

Apparatus for automating a high volume instrument (HVI) used for the classification of all Upland and American Pima cotton, including determining trash and color. A sub-sample delivery tube sub-system and a sample drum air chamber sub-system allow the HVI to receive sub-samples from an automated cotton system. A delivery tube, with an air dissipater, delivers the automated sub-sample to the HVI sample drum while an air chamber below the sample drum applies a negative air pressure to the drum. A sub-sample air-knife extraction sub-system and an autoMIC transfer tube assist sub-system allow the HVI to release automated sub-samples after the sample drum in the HVI has completed its operations on the sub-sample. An air-knife applies air jets to the sample plate of the HVI sample drum to release the sub-sample. As the sub-sample leaves the drum an air jet is actuated to push the sub-sample along a transfer tube.

A method for measuring absorbent hygiene products comprises placing absorbent bodies on a web and moving the web through at least one microwave resonator. Values of a shift in a resonance frequency and a spreading of the resonance frequency are measured using the at least one microwave resonator to continuously determine the shift in the resonance frequency and the spreading of the resonance frequency. At least one of moisture and density of the plurality of absorbent bodies is determined based on the measured values of the shift in the resonance frequency and a spreading of the resonance frequency. Empty values for each of the measured values of the shift in the resonance frequency and the spreading of the resonance frequency are determined and subtracted from the measured values of the shift in the resonance frequency and the spreading of the resonance frequency to evaluate the measured values.

The method is for monitoring contamination in a stream of fiber flocks transported pneumatically in an airflow. Characteristics of entities, including contamination, in the stream of fiber flocks are detected and evaluated. Values of a first parameter and a second parameter of the entities are determined from the characteristics of the entities. An event field is provided, which contains a quadrant or a part of a quadrant of a two-dimensional Cartesian coordinate system, wherein a first axis defines the first parameter and a second axis defines the second parameter. The values of the first parameter and the second parameter determined for an entity are entered in the event field as coordinates of an event representing the entity. Thus, entities can be handled in a differentiated way.

Describes a method for cotton mixes homogenization without categorizing bales in inventory, i.e., with no separation of bales into classes, whose main objective is to eliminate the large variability of cotton fiber quality for the spinning process resulted from data input concerning the quality of the mixes and inventories. With this method no categorization in inventory is required and more than 20 quality parameters can be controlled with no impact on the physical inventory management. The method is intended to solve problems in the production of cotton fibers relative to the variability among mixes, variability among the loads of the mixes and variability in the laydown of the bales resulting in cotton fiber with higher quality, as well this method presents an optimized logistics in the warehouse.

The invention relates to a computer-implemented method for optically characterizing a textile fiber structure. A plurality of pieces of information on the color at different locations of the textile fiber structure are detected by an optical sensor system. The detected color information is transmitted to a computer (107) and is entered into a color space (2) in the form of a scatter plot (31) by the computer. A frequency density distribution (4) of the scatter plot (31) is determined, and the frequency density distribution (4) is numerically specified. The invention allows a change in the material of the textile fiber structure to be ascertained and optimizes the elimination of foreign materials from the textile fiber structure.