A textile machine with a plurality of similar workstations as well as display means and a central control device, wherein the display means is connected to the central control device and/or a workstation control device. The textile machine comprises a display means, which is designed as an LED light bar, a section of the LED light bar is assigned respectively to a workstation, and the LED light bar displays the respectively produced yarn batch and/or operating states of the respective workstation.

A textile machine with a plurality of similar workstations as well as display means and a central control device, wherein the display means is connected to the central control device and/or a workstation control device. The textile machine comprises a display means, which is designed as an LED light bar, a section of the LED light bar is assigned respectively to a workstation, and the LED light bar displays the respectively produced yarn batch and/or operating states of the respective workstation.

A guard insert having a body and a guide. The body can include a top surface, an opposed bottom surface, and a plurality of side edges extending between the top and bottom surfaces and including a front side edge. The body can define a slot and a plurality of fastener-receiving openings. The slot can extend inwardly from the front side edge. The plurality of fastener-receiving openings can extend through the top and bottom surfaces, with each opening of the plurality of fastener-receiving openings being configured to receive a fastener. The guide can be securely received within the slot of the body. The guide can have an outer peripheral wall and an inner peripheral wall. The outer peripheral wall can have a shape complementary to the slot, and at least a portion of the inner peripheral wall can define a channel configured for receiving yarn.

A guard insert having a body and a guide. The body can include a top surface, an opposed bottom surface, and a plurality of side edges extending between the top and bottom surfaces and including a front side edge. The body can define a slot and a plurality of fastener-receiving openings. The slot can extend inwardly from the front side edge. The plurality of fastener-receiving openings can extend through the top and bottom surfaces, with each opening of the plurality of fastener-receiving openings being configured to receive a fastener. The guide can be securely received within the slot of the body. The guide can have an outer peripheral wall and an inner peripheral wall. The outer peripheral wall can have a shape complementary to the slot, and at least a portion of the inner peripheral wall can define a channel configured for receiving yarn.

A yarn producing apparatus produces carbon nanotube (CNT) yarn by aggregating CNT fibers. A substrate support supports a CNT forming substrate, a winding unit 7 continuously draws the CNT fibers, a yarn producing unit aggregates the CNT fibers, and a substrate replacing mechanism replaces the carbon nanotube forming substrate supported on the substrate support with another carbon nanotube forming substrate.

A method is performed at a spinning machine that includes a plurality of spinning stations at which different yarn lots are spun. The method transports tubes from multiple tube magazines to the spinning stations. At the spinning station, a yarn is spun from a sliver deposited in a can and is wound onto the tube. An identical marking associated with a respective one of the different yarn lots is provided on the following components: each of the tubes, each of the tube magazines, a display device at the spinning station, a monitor at a machine control system, the cans at the spinning station, and a service unit that travels alongside of the spinning stations.

A method is performed at a spinning machine that includes a plurality of spinning stations at which different yarn lots are spun. The method transports tubes from multiple tube magazines to the spinning stations. At the spinning station, a yarn is spun from a sliver deposited in a can and is wound onto the tube. An identical marking associated with a respective one of the different yarn lots is provided on the following components: each of the tubes, each of the tube magazines, a display device at the spinning station, a monitor at a machine control system, the cans at the spinning station, and a service unit that travels alongside of the spinning stations.

A method and apparatus for detecting leaks and/or blockages in a spinning unit of a spinning apparatus of a spinning machine. The method can comprise: setting the spinning machine wherein compressed air valves are set to an open state to release a compressed air flow feed to the spinning unit, switching on a compressed air source provided that the compressed air source is switched off, closing the compressed air valves one after the other in a defined order, wherein each time a compressed air valve is closed, the compressed air flow value is measured and transmitted to an evaluation device and assigned to the spinning unit assigned to the air valve and is compared with a specified limit value or limit value range, and identifying and assessing whether compressed air flow values of which deviate from the limit value or limit value range.

A textile machine, especially a spinning machine or winding machine, has numerous identical workstations arranged beside one another along a longitudinal side, with numerous maintenance devices movable along the workstations for servicing the workstations, and with a control and communication system. The maintenance devices are connected to a bus topology component through a maintenance device bus line, in which case at least some of the bus topology components are connected to the control and communication system with a common bus line. The bus topology components are arranged in a middle area of the textile machine, in the longitudinal direction (LR) of the textile machine.

An electronic device and associated method are used to detect a fault in a spinning mill and to estimate one or more sources of the fault, the spinning mill including a plurality of textile machines that sequentially process textile materials. With the electronic device, the method receives parameter information of one or more of the textile machines and of one or more of the textile materials. The electronic device detects faults and location of the faults by identifying parameter information of the textile materials deviating from reference information. The electronic device is used to access configuration information of the textile machines and knowledge-based information related to possible sources of faults in the spinning mill. The method incudes using the electronic device to apply parameter information, configuration information, and knowledge-based information to one or more machine-learning algorithms to estimate the sources of the faults.