An article having an embossed seal includes at least two webs, and an embossed seal joining a portion of the at least two webs, the seal including co-registered concentric discrete extended elements formed in the at least two webs, the discrete extended elements having open proximal ends.

A method for perforating a wall, includes calculating mechanical stresses applied on the wall for a use of the wall. The method further includes perforating an orifice in a first determined zone of the wall, the perforation being made using a tool with a cross-section dependent on the mechanical stresses calculated in the first determined zone.

A method for perforating a wall, includes calculating mechanical stresses applied on the wall for a use of the wall. The method further includes perforating an orifice in a first determined zone of the wall, the perforation being made using a tool with a cross-section dependent on the mechanical stresses calculated in the first determined zone.

A method for hydroforming a composite precursor material includes forming a composite precursor material comprising an original spun bonded nonwoven web and a polymer film layer. The method also includes applying a plurality of pressurized liquid jets onto an outer surface of the original spun bonded nonwoven web while the composite precursor material passes over a forming structure to push and reorient a plurality of spun bonded fibers from a closely packed substantially horizontal orientation to a more loosely packed orientation with greater vertical spacing between the fibers to produce a hydroformed composite material comprising an expanded spun bonded nonwoven layer having a loft of at least about 1.3 times greater than the original loft of the original spun bonded nonwoven web, and an air permeability of at least about 1.2 times greater than an original air permeability of the original unexpanded spun bonded nonwoven web.

The present invention relates to systems and processes for cutting and creasing corrugated cardboards, and more specifically, to digital system and processes for cutting and creasing corrugated cardboards, wherein the system includes an array of cutting elements that can be dynamically configured to cut and/or crease a wide range of contours.

A robot system includes an articulated robot having a base near one end, a wrist flange near an opposite end, and a plurality of robot portions between the base and the wrist flange. A cutting tool is secured to the wrist flange and selectively moveable about at least one tool axis to change an angle of orientation of the cutting tool. A controller coordinates movement of the robot portions and at least one change in the angle of orientation of the cutting tool to move the cutting tool in an uninterrupted manner along a continuous cutting path to cut a slab of material while avoiding a singularity condition in which any two of the robot's axes are collinear.

A robot system includes an articulated robot having a base near one end, a wrist flange near an opposite end, and a plurality of robot portions between the base and the wrist flange. A cutting tool is secured to the wrist flange and selectively moveable about at least one tool axis to change an angle of orientation of the cutting tool. A controller coordinates movement of the robot portions and at least one change in the angle of orientation of the cutting tool to move the cutting tool in an uninterrupted manner along a continuous cutting path to cut a slab of material while avoiding a singularity condition in which any two of the robot's axes are collinear.

An apparatus for manufacturing a glass laminated substrate includes a chamber, a cutting apparatus configured to cut the glass laminated substrate within the chamber, and a surface processing apparatus configured to process a surface of the glass laminated substrate that is cut. The cutting apparatus and the surface processing apparatus of the apparatus for manufacturing a glass laminated substrate can be used to manufacture in-line the glass laminated substrate within the chamber.

A linear electro-mechanical actuator (1) preferably for water cutting, makes it possible to significantly improve the working conditions of the actuator (1), so as to optimize its load capacity and increase the working life of the actuator (1), and makes it possible to reduce the risk of breakage or damage of the actuator (1) following loss of control of the movement aimed at producing the force applied by the actuator (1).

A linear electro-mechanical actuator (1) preferably for water cutting, makes it possible to significantly improve the working conditions of the actuator (1), so as to optimize its load capacity and increase the working life of the actuator (1), and makes it possible to reduce the risk of breakage or damage of the actuator (1) following loss of control of the movement aimed at producing the force applied by the actuator (1).