A substrate processing apparatus includes a substrate support unit including a chuck for supporting a substrate, a fluid supply unit that supplies a processing fluid to the substrate, and a recovery unit surrounding the chuck and recovering the supplied processing fluid. The substrate support unit includes an antistatic material in which milled carbon fibers (MCF) are blended into a perfluoroalkoxy alkane (PFA) resin.

An adjustable level 3-D printing platform includes a platform, three support posts, and an adjusting component by which heights of the three support posts are adjustable. The bottom of the build platform includes at least one socket to engage with a ball end of one of the three support posts, thereby enabling two point leveling. The adjusting component is configured to simultaneously adjust a height of the at least three support posts using a first arm and a second arm, each connected to the build platform at respective pivot points and configured to apply respective clamping forces to the support posts. The printing platform further includes at least one sensor leveling system that deploys a probe, measures a relative probe state, and compares the measurement to a predetermined value. During the leveling processes, the 3-D printer is configured to provide sensory feedback.

A guide rail for a window lifter for raising and lowering a window pane or door system for a vehicle door having a carrier and at least two guide rails disposed on the carrier. The guide rails include a guide profile that can be twisted or bent for guiding an adjusting part of the window lifter coupled to the window pane along an adjusting direction predetermined by the guide rails and the guide profile includes a base and two legs protruding at obtuse draft angles from the ends of the base, such that the size of the draft angles is proportional to the bending or twisting of the guide rails prescribed by the kinematics of the retraction of the window pane over the adjusting travel of the window pane.

A method for manufacturing an arrestor for an electrostatic chuck includes printing first layers of an arrestor for an electrostatic chuck using a 3-D printer and an electrically non-conductive material. The first layers of the arrestor at least partially define a first opening to a gas flow channel. The method includes printing intermediate layers of the arrestor using the 3-D printer and the electrically non-conductive material. The intermediate layers of the arrestor at least partially define the gas flow channel. The method includes printing second layers of the arrestor using the 3-D printer and the electrically non-conductive material. The second layers of the arrestor at least partially define a second opening of the gas flow channel. At least one of the first opening, the second opening and/or the gas flow channel of the arrestor is arranged to prevent a direct line of sight between the first opening and the second opening of the arrestor.

A method for manufacturing an arrestor for an electrostatic chuck includes printing first layers of an arrestor for an electrostatic chuck using a 3-D printer and an electrically non-conductive material. The first layers of the arrestor at least partially define a first opening to a gas flow channel. The method includes printing intermediate layers of the arrestor using the 3-D printer and the electrically non-conductive material. The intermediate layers of the arrestor at least partially define the gas flow channel. The method includes printing second layers of the arrestor using the 3-D printer and the electrically non-conductive material. The second layers of the arrestor at least partially define a second opening of the gas flow channel. At least one of the first opening, the second opening and/or the gas flow channel of the arrestor is arranged to prevent a direct line of sight between the first opening and the second opening of the arrestor.

The present invention relates to a method for producing a fiber-plastics-composite tool component (1) having a matrix system (6) that has embedded fibers, PBO fibers (4) being selected as the fiber component and a thermosetting plastics matrix (8) being used as the matrix component of the matrix system (6) (S1), which thermosetting plastics matrix has such adhesion to the PBO fibers (4) in the hardened fiber-plastics composite (2) that the coefficient of thermal expansion of the PBO fibers (4) is imparted to the matrix system (6). The invention also relates to a load-bearing tool component (1) of a chip-removing tool in the design of a fiber-plastics-composite press-molded part, the load-bearing tool component (1) comprising a matrix system (6) that has a thermosetting matrix component (8) and comprising PBO fibers (4) embedded into said thermosetting matrix component.

A constant force expansion construct includes a plurality of expandable layers, each expandable layer including: (a) a longitudinal restricting beam; and (b) a plurality of interconnected flexible biasing struts connecting the longitudinal restricting beam of one expandable layer to another longitudinal restricting beam in a next adjacent expandable layer, the biasing struts being biased toward a compressed position and being movable between the compressed position and an expanded position in which a distance between successive longitudinal restricting beams is increased.

A machine foot with a built-in load cell is provided, the load cell being suspended in an overlying sheath, with the feature that the screws which hold the load cell in place in the lower part of the machine foot pass through a bottom plate and are screwed up into a fastening ring that is separate from the sheath material. A method of production of a machine foot is provided, by which a rubber resin is moulded down into the sheath of the machine foot and is vulcanized thereto, the fastening ring being embedded in the rubber resin in an area that abuts the lower side of the sheath.

A method is provided for connecting hollow profiles (1-4) in a joint (10) to produce a load-bearing structure (5). The method includes placing ends of hollow profiles (1-4) in a mold and pressing the ends together with at least one semi-finished product to connect the ends of the hollow profiles to the semi-finished product.

A mold assembly, for an overhead console button carrier having a unitary body, includes a cavity side and a core side. The core side includes at least one zero draft core insert, a first buried retractor mechanism and a first slide mechanism.