A coiled product, a control installation, computer software product, a coiling machine and method for coiling a coiled product, wherein the coiling tension is settable to an envisaged coiling tension, particularly to a constant coiling tension via either a setting unit and/or a change in the respective rotational speed of either a coil body and/or a supply roll, a characterizing aspect being the equalization of the free length of the coiled product, where the free length is the spacing of the first bearing point of the coiled product on the coil body from the second bearing point of the coiled product on a deflection roller such that the free length change is equalized by the setting unit and/or by a variation of the respective rotational speed so that coiling tension of a product coiled onto the coil body can be set in a simple, rapid, and precise manner.

A self-synchronizing yarn tension control system is provided. Self-synchronizing yarn tension control includes a yarn tension sensor, a yarn brake, and a controller configured to control the system. The controller includes one or more processors and one or more memory devices. The memory devices configured to store the more memory devices configured to store one or more tension pulses, store one or more tension thresholds, and store instructions that when executed by the processors cause the processors to perform operations. The operations include obtaining a first yarn tension value and selectively operating the yarn brake based on the tension pulses. Obtaining a second yarn tension value by operating the yarn brake based on the tension pulses. Determining whether the first tension value exceeds the second tension value. Obtaining a yarn tension signal from the yarn tension sensor, comparing the yarn tension signal to the one or more tension thresholds, generating one or more brake control signals based on said comparison and operating the yarn brake based upon each of the one or more brake signals.

An article of footwear may include a motorized tensioning system. The tensioning system may include a tensile member and a motorized tightening device configured to apply tension in the tensile member to adjust the size of an internal void defined by the article of footwear. The tensioning system may further include a power source configured to supply power to the motorized tightening device. The tensile member, the motorized tightening device, and the power source may be configured to be removably attached to the article of footwear.

An article of footwear may include a motorized tensioning system. The tensioning system may include a tensile member and a motorized tightening device configured to apply tension in the tensile member to adjust the size of an internal void defined by the article of footwear. The tensioning system may further include a power source configured to supply power to the motorized tightening device. The tensile member, the motorized tightening device, and the power source may be configured to be removably attached to the article of footwear.

An example welding wire feeder includes: a push motor configured to feed welding wire from a wire source; a first sensor configured to provide push motor velocity feedback; and control circuitry configured to control the push motor and a pull motor of a welding torch coupled to the welding wire feeder by: controlling a push motor velocity of the push motor and a pull motor velocity of the pull motor based on a target wire feed speed; and compensating each of the push motor velocity of the push motor and the pull motor velocity of the pull motor based on the push motor velocity feedback and based on pull motor velocity feedback, wherein the push motor velocity and the pull motor velocity are based on a target wire tension.

A tether management system is disclosed. The tether management system includes a spool, a tension sensor, a controller and a moveable pulley. The spool is rotatable to reel in and reel out a tether. The tension sensor measures a tension of the tether. The controller receives a desired tension of the tether and controls the rotation of the spool to reel in and reel out the tether based on a difference between a measured tension from the tension sensor and the desired tension of the tether. The moveable pulley is disposed to engage tether between the spool and the tension sensor. The moveable pulley being able to be biased and moveable along a linear path to adjust a tension of the tether when the tension of the tether deviates from the desired tension. A method for managing tether is also disclosed.

An example welding wire feeder includes: a push motor configured to feed welding wire from a wire source; a first sensor configured to provide push motor velocity feedback; and control circuitry configured to control the push motor and a pull motor of a welding torch coupled to the welding wire feeder by: controlling a push motor velocity of the push motor and a pull motor velocity of the pull motor based on a target wire feed speed; and compensating each of the push motor velocity of the push motor and the pull motor velocity of the pull motor based on the push motor velocity feedback and based on pull motor velocity feedback, wherein the push motor velocity and the pull motor velocity are based on a target wire tension.

A guiding chain carrier system (1) is configured for an installation (2), for deploying and for storing without folding said guiding chain and flexible supply cables and/or pipelines. Said guiding chain carrier system comprises a mobile workstation (6) movable over a work surface (3) and connected to the said cables and/or pipelines, at least one guiding chain (20), connected to a static connection area (7) on one end and to the mobile workstation (6) on the other end thereof, for supporting said cables and/or pipelines; characterized by at least one compensation trolley (8), comprising a compensation system. Said compensation trolley (8) is movable and the compensation system is able to generate a resistance force in order to maintain the guiding chain (20) straight while the mobile workstation (6) moves from an operation location nearest the static connection area (7) until an operation location furthest from the static connection area (7).