A method for putting on or taking off a piece of clothing or for closing, putting on, opening, or taking off a piece of luggage, including the steps of tightening or loosening by means of a tensioning element driven by a driven tension roller and a switching element. The tightening or loosening takes place by actuation of the switching element. The switching element has a number of contact-sensitive sensors which are arranged adjacent to one another and form a surface accessible to the user of the piece of clothing or of the piece of luggage. The method includes the steps of scanning the surface of the sensors by the user in a first direction, detecting the signal of the sensors by a controller, and causing a first tensioning force level or a first closing path of the tensioning element to be initiated by the controller and the electric motor.

A footwear lacing apparatus can comprise a housing structure, a modular spool and a drive mechanism. The housing structure can comprising a first inlet, a second inlet, and a lacing channel extending between the first and second inlets. The modular spool can be disposed in the lacing channel and can comprise a lower plate including a shaft extending from the lower plate, and an upper plate including a drum portion. The upper plate can be releasabley connected to the lower plate at a connection interface. The drive mechanism can couple with the modular spool and can be adapted to rotate the modular spool to wind or unwind a lace cable extending through the lacing channel and between the upper and lower plates of the modular spool.

Assembly methods related to an automated footwear platform including a lacing engine drive apparatus are discussed. In an example, an assembly method can include operations such as inserting a mid-sole plate, attaching a laced upper portion, and inserting a lacing engine. The inserting a mid-sole plate operation can include inserting the mid-sole plate into a mid-sole of the footwear platform. The attaching a laced upper portion operation can include attaching a laced upper portion to the mid-sole and positioning a lace loop in the mid-sole plate. Finally, the inserting a lacing engine operation can include inserting a lacing engine into a cavity in the mid-sole plate, wherein the lacing engine includes a lace spool exposed along a superior surface to receive the lace loop.

Assembly methods related to an automated footwear platform including a lacing engine drive apparatus are discussed. In an example, an assembly method can include operations such as inserting a mid-sole plate, attaching a laced upper portion, and inserting a lacing engine. The inserting a mid-sole plate operation can include inserting the mid-sole plate into a mid-sole of the footwear platform. The attaching a laced upper portion operation can include attaching a laced upper portion to the mid-sole and positioning a lace loop in the mid-sole plate. Finally, the inserting a lacing engine operation can include inserting a lacing engine into a cavity in the mid-sole plate, wherein the lacing engine includes a lace spool exposed along a superior surface to receive the lace loop.

A footwear acing apparatus can comprise a housing structure, a spool and a drive mechanism. The housing structure can comprise a first inlet, a second inlet, and a lacing channel extending between the first and second inlets. The lacing channel can comprise a spool receptacle located between the first and second inlets, a first relief area located between the spool receptacle and the first inlet, and a second relief area located between the spool receptacle and the second inlet. The first and second relief areas can be linearly tapered between the spool receptacle and the first and second inlets, respectively. The spool can be disposed in the spool receptacle of the lacing channel. The drive mechanism can be coupled with the spool and adapted to rotate the spool to wind or unwind a lace cable extending through the lacing channel and through the spool.

Computer program product, controller, winding machine and method for winding a winding material from a supply device onto a winding body of a winding machine, wherein the winding material is provided from a supply roller and wound onto the winding body via at least one deflection roller, where an actual winding tension of the winding material is set to a setpoint winding tension depending on a position-dependent compensation signal, stored in a storage unit, to compensate for a changeable free length, resulting from a non-circular cross section of the winding material, of the winding material between the deflection roller and the winding body, whereby due to the fact that the actual winding tension is set to the setpoint winding tension via the position-dependent compensation signal, which is already stored in the storage unit prior to the winding, the computational load for the setting can be reduced.

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.

A footwear lacing apparatus can comprise a housing structure, a spool and a drive mechanism. The housing structure can comprise a first inlet, a second inlet, and a lacing channel extending between the first and second inlets. The lacing channel can comprise a spool receptacle located between the first and second inlets, a first relief area located between the spool receptacle and the first inlet, and a second relief area located between the spool receptacle and the second inlet. The first and second relief areas can be linearly tapered between the spool receptacle and the first and second inlets, respectively. The spool can be disposed in the spool receptacle of the lacing channel. The drive mechanism can be coupled with the spool and adapted to rotate the spool to wind or unwind a lace cable extending through the lacing channel and through the spool.

A footwear lacing apparatus can comprise a housing structure, a spool and a drive mechanism. The housing structure can comprise a first inlet, a second inlet, and a lacing channel extending between the first and second inlets. The lacing channel can comprise a spool receptacle located between the first and second inlets, a first relief area located between the spool receptacle and the first inlet, and a second relief area located between the spool receptacle and the second inlet. The first and second relief areas can be linearly tapered between the spool receptacle and the first and second inlets, respectively. The spool can be disposed in the spool receptacle of the lacing channel. The drive mechanism can be coupled with the spool and adapted to rotate the spool to wind or unwind a lace cable extending through the lacing channel and through the spool.