A method and system for using image analysis to generate an automobile surface protecting device attached with an adhesive are provided. The method includes generating from a scanned three-dimensional image, using one or more image analysis applications, a protective film template for a vehicle panel based on the dimensions of the vehicle panel, a determined transition point, a determined termination point, and a plurality of relief cuts. Generating the protective film template includes converting a three-dimensional protective film template into a two-dimensional protective film template by flattening the protective film template. The method includes transferring the protective film template to the sheet of protective film. The sheet of protective film includes an adhesive and is used to modify an appearance of the vehicle panel by modifying how light reflects off scratches on the vehicle panel.

A deflectable lifting device can be mounted to a frame, work surface, or other member of a material conveying system. The deflectable lifting device can have a base that mounts into a mounting slot of a frame, and a bendable arm arranged in the pathway of a material conveying system, such as a paper stripping or paper blanking work station. When a sheet of material travels over the deflectable lifting device, the bendable arm can bend and deflect downwardly, but still contacts the sheet of material to provide a small margin of elevation or lift to the sheet of material. The sheet of material can therefore be elevated above edges, holes, or other obstructions in the pathway, which could otherwise jam or snag the delivery of the sheet of material.

A method of cutting a wafer of composite core from a bulk composite core including the steps of placing the bulk composite core in a container, the bulk composite core having a plurality of tube members; depositing a potting compound in contact with an outer surface of the bulk composite core; curing the potting compound; and after curing of the potting compound, cutting through each of the tube members. A method of cutting a wafer of composite core from a bulk composite core, the method comprising the steps of stabilizing the bulk composite core by wrapping an exterior of the bulk composite core with a composite wrap, the bulk composite core having a plurality of tube members; curing the composite wrap; and cutting through each of the tube members.

The present invention relates to a device to cut hair, fibers, or thin, flexible materials, comprising at least one retaining element (2) with a cylindrically formed interior that is suitable for immobilizing and potentially bundling in lengthwise direction a sample (1) to be cut, composed of a multiplicity of hairs, fibers, or thin, flexible materials, and a cutting device (3) that is suitable for cutting the sample that is immobilized and possibly bundled in lengthwise direction, in a direction that is substantially perpendicular to the cylinder axis of the interior of the retaining element (2). The present invention relates furthermore to a method making use of the device, as well as a hair section that can be produced with the device or the method.

A method of cutting a wafer of composite core from a bulk composite core includes stabilizing the bulk composite core with a fixture, the bulk composite core having a plurality of tube members. The method also includes cutting through each of the tube members to create the wafer while the bulk composite core is stabilized by the fixture.

A rapid exchange catheter comprises a guide wire lumen including a substantially sealed portion in which a lumen wall extends around an entire periphery thereof and a channel portion including a channel opening the lumen to an exterior of the catheter, wherein a width of the channel is less than a maximum width of the channel portion. A guide wire ramp extends into the channel portion, with the ramp extending further into the lumen of the channel portion as a distal end of the ramp is approached.

Systems, dies, and methods are provided for processing pericardial tissue. The method includes positioning a die-cut assembly over the pericardial tissue, the die-cut assembly including a die having a plate, a die pattern, and an opening, the die pattern attached to the plate, the opening formed in the plate to provide access to the pericardial tissue, and measuring a thickness of the tissue through the opening. The die-cut assembly may be mounted for automated vertical movement, and a platen on which the tissue is placed is capable of automated horizontal movement. Different target areas on the tissue can be assessed by measuring the thickness through the die, and when an area is deemed suitable the die pattern cuts a shape therefrom. The system is useful for cutting uniform thickness heart valve leaflets, and can be automated to speed up the process.

A cutting apparatus configured to hold an elongate element, such as a ribbon, in a desired orientation as the elongate element is cut into two sections. A cutting element of such a cutting apparatus may be confined to a single orientation relative to that of the elongate element, reducing or eliminating the likelihood of misalignment between the cutting element and the elongate element immediately before the elongate element is cut. In some embodiments, the cutting apparatus, or even its cutting element, may be configured to seal the newly cut ends of the elongate element. Methods for cutting and or sealing elongate elements, such as ribbons, are also disclosed.

A deflectable lifting device can be mounted to a frame, work surface, or other member of a material conveying system. The deflectable lifting device can have a base that mounts into a mounting slot of a frame, and a bendable arm arranged in the pathway of a material conveying system, such as a paper stripping or paper blanking work station. When a sheet of material travels over the deflectable lifting device, the bendable arm can bend and deflect downwardly, but still contacts the sheet of material to provide a small margin of elevation or lift to the sheet of material. The sheet of material can therefore be elevated above edges, holes, or other obstructions in the pathway, which could otherwise jam or snag the delivery of the sheet of material.

Systems, dies, and methods are provided for processing pericardial tissue. The method includes positioning a die-cut assembly over the pericardial tissue, the die-cut assembly including a die having a plate, a the pattern, and an opening, the die pattern attached to the plate, the opening formed in the plate to provide access to the pericardial tissue, and measuring a thickness of the tissue through the opening. The die-cut assembly may be mounted for automated vertical movement, and a platen on which the tissue is placed is capable of automated horizontal movement. Different target areas on the tissue can be assessed by measuring the thickness through the die, and when an area is deemed suitable the die pattern cuts a shape therefrom. The system is useful for cutting uniform thickness heart valve leaflets, and can be automated to speed up the process.