A pallet is taught having two openings on at least one side of the pallet, the two openings formed by a bisecting wall separating the openings. More specifically, at least one bisecting post creates a first opening and a second opening Each of the said first and second openings each have a convexly curved runner, said runner convexly curved along its width; and a concavely curved ceiling, said ceiling concavely curved along its width wherein the center point of the radius of the curved runner varies from the radius of the curved ceiling.

A diffraction light guide plate comprising an optical layer having diffraction lattice pattern formed as an integrated structure without an interface on one surface thereof, where the optical layer having diffraction lattice pattern is a continuous phase of polymer comprising an episulfide compound, a thiol compound, and an aromatic cyclic compound having two or more hydroxyl groups, the diffraction light guide plate having excellent thickness uniformity and flatness as well as low haze and excellent visibility, and excellent mechanical properties such as pencil hardness and strength, and a method for manufacturing the diffraction light guide plate.

An injection molding apparatus (10) comprising: one or more valves each comprised of a valve pin (1040, 1041, 1042) adapted to be driven upstream and downstream through a downstream channel (1006) that has a downstream channel portion (1006ds) that has a control surface (1008), the control surface (1008) forming a channel or restriction gap (CG, 1006rg), the valve pin (1041) being controllably drivable upstream and downstream through the channel or restriction gap (CG, 1006rg) at a single selected rate of upstream acceleration up to a selected reduced upstream velocity that is less than a maximum velocity at which the valve pin (1041) is drivable, the size or configuration of the channel or restriction gap (CG, 1006rg) and the single selected rate of upstream acceleration being selected in combination with each other to control flow of injection fluid (18) through the channel gap (CG, 1006rg).

A reinforcing element for reinforcing a structural element in a motor vehicle includes: a carrier element which is produced by a pultrusion method and which has a longitudinal axis which, when in use, extends substantially along a longitudinal axis of the structural element, wherein the carrier element has a plurality of outer surfaces extending in the direction of the longitudinal axis; and an adhesive for bonding the carrier element to the structural element; and at least one wall, which is arranged on an outer surface; wherein the adhesive is arranged at least on the same outer surface of the carrier element as the at least one wall.

The embodiments are and include at least an apparatus, system and method for forming print material particles for additive manufacturing (AM) printing. The apparatus, system and method include at least a melt chamber comprising a polymer melt; a vertical extruder that fluidically receives the polymer melt; an atomizer that atomizes the polymer melt from the vertical extruder and that distributes the atomized polymer melt; a fall chamber comprising a plurality of zones into which the atomized polymer melt is distributed; and a collector to receive the print material particles formed of the atomized polymer melt after falling through the plurality of zones.

An improved RPG shield netting that comprises a net structure supporting a spaced arrangement of one-piece nodes manufactured using an insert injection molding process such that each node is formed as a one-piece three-dimensional solid shape with uniform surfaces that envelopes a portion of one or more cord elements.

A three-dimensional object comprises stacked substrate layers infiltrated by a hardened material. Each substrate layer is a sheet-like structure that comprises fibers held together by a sodium silicate binder. The substrate layer material may be non-woven or woven. The substrate layer may be a non-woven fiber veil bound by a sodium silicate binder. The fibers may optionally include carbon fibers, ceramic fibers, polymer fibers, glass fibers, metal fibers, or a combination thereof.

A cavity plate assembly (400) for a preform mold (100), which includes a cavity plate (410) having an array of seats (412) and a corresponding array of cavity inserts (440) mounted to a front face (CVF) of the cavity plate (410) and in communication with a respective seat (412). Each cavity insert (440) includes a body (441) with a mounting face (441a) and a spigot (443) projecting from the mounting face (441a) and received in a respective seat (412) of the cavity plate (410) such that the mounting (441a) face abuts the front face (CVF) of the cavity plate (410). Each cavity insert (440) also includes a molding surface (448) along its length, at least two thirds of which extends beyond the cavity plate (410).

A strip of curable prepreg comprising unidirectional fibers aligned with the length of the strip, the fibers being at least partially impregnated with curable thermosetting resin and comprising a flexible polymeric sheet on an outer face of the strip, wherein the strip has a substantially rectangular cross-section defining a width and a thickness of the strip.

Insert designed to be fitted on a support, including a body extending along a longitudinal axis and a base including at least one plate extending along a base plane, at least one through hole oriented along an orientation axis perpendicular to the base plane being formed in said at least one plate, at least one protuberance being formed on a first surface of said at least one plate and forming a hollow on a second surface of said at least one plate.