An electronic cutting machine includes at least one housing to which a drive roller is coupled for moving a sheet to be cut in a first direction and a cutter assembly coupled to the housing and moveable in a second direction that is perpendicular to the first direction.

Tape layup systems and associated methods. A tape layup system includes a feed spool and an uptake spool. The feed spool is configured to carry a tape roll of tackifier tape that includes a tackifier material and a backing material, and the uptake spool is configured to carry a backing material roll of the backing material. The tape layup system further includes a torque transmission system configured to convey a torque from the feed spool to the uptake spool. The tape layup system is configured such that conveying a torque from the feed spool to the uptake spool operates to draw the backing material onto the backing material roll. A method of operating a tape layup system includes generating tension in a tackifier tape to rotate a feed spool and consequently rotating an uptake spool to draw a backing material onto a backing material roll.

Cutting tools are provided for scoring a hose over a fitting. The cutting tool includes a handle with a central pass-through for the hose, and a scoring mechanism adjustably coupled to the handle. The scoring mechanism includes a base member with a central pass-through for the hose, and which is adjustably coupled to the handle. The scoring mechanism further includes an arm-blade subassembly coupled to the base member. The subassembly includes a blade, and an arm with a blade-receiving recess, and a guide surface to contact and travel along a hose. The blade is coupled to the arm within the blade-receiving recess to extend a selected penetration depth from the arm. The arm is radially adjustable with adjustment of the base member relative to the handle to physically contact the guide surface to the hose and insert the blade into the hose the selected penetration depth.

Tape layup systems and associated methods. A tape layup system includes a feed spool and an uptake spool. The feed spool is configured to carry a tape roll of tackifier tape that includes a tackifier material and a backing material, and the uptake spool is configured to carry a backing material roll of the backing material. The tape layup system further includes a torque transmission system configured to convey a torque from the feed spool to the uptake spool. The tape layup system is configured such that conveying a torque from the feed spool to the uptake spool operates to draw the backing material onto the backing material roll. A method of operating a tape layup system includes generating tension in a tackifier tape to rotate a feed spool and consequently rotating an uptake spool to draw a backing material onto a backing material roll.

Systems and methods include using an ultrasonic cutter tool to cut a seal. The system comprises an ultrasonic cutter tool disposed onto a railing system coupled to a platform, wherein the ultrasonic cutter tool is configured to translate along the railing system. The system further comprises a power source electrically coupled to the ultrasonic cutter tool, and an alignment mold disposed parallel to the railing system and offset by a distance. The system further comprises one or more roller bearing carriages coupled to the railing system, wherein each of the one or more roller bearing carriages comprises a set of roller bearings, wherein each set of roller bearings is disposed over the alignment mold, wherein each set of roller bearings is configured to translate along the alignment mold as each of the one or more roller bearing carriages translates along the railing system.

Disclosed is a tire building apparatus and a method for joining or cutting tire components. The tire building apparatus includes a rocking member that is movable in a rocking plane in a rocking motion along a rocking line, a translation guide extending parallel to the rocking line and a carriage that is displaceable along the translation guide, wherein the rocking member has a convex edge that defines a minor arc of a circle and extends up to a rotation center, wherein the rocking member is supported by the carriage at the rotation center and is angularly displaceable with respect to the carriage about a rotation axis extending through the rotation center.

A controller of a cutting apparatus specifies a target position of an attaching portion in a fifth direction and controls a second moving mechanism to move the attaching portion in a third direction. If the controller determines that the attaching portion has reached the target position, the controller executes cutting processing based on the obtained cutting data by controlling the second moving mechanism based on a pressure corresponding value achieved when the attaching portion is located at the target portion. If the controller determines that the pressure corresponding value has reached a pressure threshold, the controller executes the cutting processing by controlling the second moving mechanism based on the pressure corresponding value achieved when the attaching portion is located at a first particular position where the pressure corresponding value is equal to or lower than the pressure threshold value. The controller restarts controlling the second moving mechanism.

A method for providing a nonlinear line of weakness on a web material includes: providing a counter component comprising a nonlinear shape, where the nonlinear shape has a shape width, W; providing a blade in operative relationship with the counter component and comprising a plurality of teeth; rotating at least one of the blade and the counter component into interacting relationship with the other of the blade and the counter component; feeding a web between the counter component and the blade such that while in interacting relationship the blade cooperates with the counter component to perforate the web, wherein the web is moving in a machine direction; and reciprocally shifting one of the counter component and the blade for a distance, D, in a shifting direction, wherein D is at least the translational distance that one tooth travels to cover the shape width, W.

The invention relates to a Device (10) for separating a tubular web (11) in two flat webs (12, 13) with an adjustable blade (20) for cutting the tubular web (11) and with a pulling device (30) which impinges the blade (20) with a tensile force (K) on a folding edge (14) of the tubular web (11) wherein the pulling device (30) is configured in a way that the tensile force (K) is adjustable depending on the tubular properties of the tubular web (11) and that the tensile force (K) can be mainly kept constant with constant tubular properties independent from the tubular web (11).

A cutter unit includes a cutter holder, a cradle, a cutter lever, a cradle lever, and a transmitting portion. The cradle faces the cutter holder and movable between a full-cut position and a half-cut position. The cutter lever is configured to be contactable with the cutter holder. The cradle lever is configured to be contactable with the cradle. The transmitting portion is configured to move the cutter lever and the cradle lever in interlocking relation therebetween. The transmitting portion is configured to shut off transmission of movement of the cutter lever to the cradle lever in accordance with only operation to the cutter lever out of the cutter lever and the cradle lever while the transmitting portion is configured to transmit movement of the cradle lever to the cutter lever in accordance with only operation to the cradle lever out of the cutter lever and the cradle lever.