Disclosed herein is an automated fiber placement system that comprises a robot, an end effector, and a creel assembly that is coupled to the robot and movable with the robot. The creel assembly comprises a spool of a tow and a tow tensioner. The tow tensioner comprises an arm assembly that is pivotable toward and away from a tow direction between a forward position and a rearward position, inclusive, and configured to secure the tow from the spool as the tow unwinds from the spool and moves in the tow direction. The tow tensioner also comprises a biasing member that is coupled to the arm assembly and configured to bias the arm assembly into a neutral position between the forward position and the rearward position. The tow tensioner additionally comprises a potentiometer that is coupled to the arm assembly and configured to detect a position of the arm assembly.

The present invention provides a production leveling apparatus for preventing warp of a light guide film, including: a fixed support mechanism, a sliding support mechanism, and a tension detection mechanism oppositely disposed, wherein the tension detection mechanism is disposed on a surface of the light guide film, and the fixed support mechanism is provided with a drive mechanism for driving the slidable support mechanism to slide. In the present invention, the drive mechanism mounted on the fixed support mechanism drives the slidable support mechanism to slide, so that the slidable support mechanism drives a guide shaft to move with respect to a rolling shaft; moreover, the tension detection mechanism performs tension detection on the light guide film, so that the surface tension of the light guide film is within a reasonable range; the cooperative usage of the infrared signal transmitter and the infrared signal receiver implements accurate horizontal detection on the light guide film; adjusting the height of a guide shaft by means of a lifting assembly further ensures that the light guide film is in a horizontal state and prevents the light guide film from being damaged and warped, so that the quality of the light guide film is ensured; the structure design is reasonable and simple, and the usage is convenient.

A bending machine has an automated profile bending process for providing controlled management, regulation of the controlled management, correction of the automated profile bending process, and application of 3D cameras to the bending machine. The bending machine includes a first camera fixed to a first holder and a second camera fixed to a second holder. The bending machine further includes rollers for applying the holders to the bending machine to provide a three-dimensional view of a portion of the bending process. The bending machine even further includes a computer for controlling the bending process, and the bending process includes a profile defined dimensionally and in space relative to the bending machine.

In an embodiment, a paint roller manufacturing system and method uses a fabric-coating applicator to apply a fabric adhesive onto a portion of a perforated paint roller cover fabric material having a plurality of perforations through which adhesive may flow, and into the plurality of perforations and into interstitial spaces of the fabric material, to yield a length of coated fabric. An inner strip and an outer strip are wound about a mandrel in offset relation. A strip-coating applicator is used to apply a strip adhesive to the outer strip as it is wound about the mandrel. Simultaneously with the step of applying the strip adhesive to the outer strip, a portion of the coated paint roller fabric material is received at the outer strip and the length of coated fabric is wound about at least the outer strip to form a paint roller tube.

An apparatus for manufacturing a container that includes a side wall (5) in the form of a tube and a base (7) at one end of the tube. The apparatus includes a tube forming unit (15) for progressively folding a length of a sheet (19) of a side wall material into an elongate tube shape (21) having a forward end (23) for receiving a base (7) of the container and welding together lengthwise extending sides of the sheet to form the tube. The apparatus also includes a base attachment unit (17) for positioning a base of the container on the forward end of the tube.

A sash (62) of a window opening up to 180 and capable of tilting is mounted onto a fixedly installed frame profile (63) and houses a pair of superimposing sashes that fit tightly therein when in closure position, i.e. an upper stationary sash (65) and a lower movable-divertible sash (64), each of the sashes (64,65) provided with laterally extending shafts (49) for connection with sash (62), roller wheels (50) provided onto the shafts (49) of sash (64) that roll within a predefined path created by insert guide profile members (19) and diverter guide members (66,68) to alternately bring sash (64) in a position of superimposing sash (65) and a position of alignment with the same. Lifting mechanisms (46) provided with a regulatory screw (84) for adjusting the pretension of a spring component thereof and thereby the force required by the user for moving the sash (64) are installed within the vertically extending sides of the sash (62).

An object of the present invention is to propose a device capable of automatically insetting a tube into a bending die instead of doing so manually, even if the shape of a product exceeds two meters in length, the device comprising a bending die having a tube insetting portion, and a traveling body that includes a guide mechanism guiding a tube to an upper portion of the tube insetting portion, an auxiliary guide mechanism keeping the tube in the upper portion of the tube insetting portion, a insetting roll insetting the tube in the tube insetting portion, a pair of drive wheels rolling along lower rails, and a drive mechanism, wherein the traveling body moves and insets a tube into the bending die while having the auxiliary guide mechanism and the drive wheels grip the bending die.

An installation for fabricating a thermal protection covering of a body or of a rear assembly for a thruster, includes an extruder presenting a die having an outlet orifice through which a strip of elastomer material is to be extruded, the extruder having a die control system to vary the size of the outlet orifice; a mandrel to be set into rotation about its axis; a deposition head to deposit the strip on the mandrel; a conveyor system to convey the strip from the outlet orifice of the die of the deposition head; and a thickness monitoring system to measure the thickness of the strip on the deposition head and on the mandrel and to compare each measured thickness value with a predetermined value, the thickness monitoring system to control the die control system so as to cause the size of the outlet orifice of the die to vary.

A method of patterning a combined layer of an electrically-conductive film, such as indium-tin-oxide (ITO), that is disposed on a flexible substrate includes bending the combined layer about a radius of curvature. The combined layer is initially bent in a first direction so that the electrically-conducive film is distal to the radius of curvature, so as to form initial dielectric lines in the electrically-conductive film. The combined layer is then bent in another direction so that the electrically-conductive film is proximate to the radius of curvature to further enhance the dielectric performance of the initial dielectric lines. The dielectric lines electrically isolate a portion of the electrically-conductive film that is disposed therebetween, to form an electrically conductive electrode.

A method of patterning a combined layer of an electrically-conductive film, such as indium-tin-oxide (ITO), that is disposed on a flexible substrate includes bending the combined layer about a radius of curvature. The combined layer is initially bent in a first direction so that the electrically-conducive film is distal to the radius of curvature, so as to form initial dielectric lines in the electrically-conductive film. The combined layer is then bent in another direction so that the electrically-conductive film is proximate to the radius of curvature to further enhance the dielectric performance of the initial dielectric lines. The dielectric lines electrically isolate a portion of the electrically-conductive film that is disposed therebetween, to form an electrically conductive electrode.