A method for manufacturing a plastic lens that can enhance productivity by shortening the cooling time without affecting transferability even if the temperature of a mold is set low and may be applicable to an existing injection molding apparatus. When a plastic lens having a prescribed lens shape is manufactured by injecting and filling a molten resin in a cavity 3 formed between a movable mold 1 and a fixed mold 2, a molding surface of at least one of cavity forming member insert molds 11 and 12 is formed in glass substrates 11a and 12a, and for a period of time for which filling is completed with the cavity 3 being filled with a raw material resin that flows into the cavity 3, temperature control is conducted such that the surface temperature of the molding surface does not exceed the glass transition temperature of the raw material resin.

An injection moulded thermoplastic preform for blow moulding to form a container, the preform comprising a lower closed base portion, a hollow body portion, a hollow transition portion between the lower closed base portion and the hollow body portion, and an upper open end portion adjacent to an upper part of the hollow body portion, wherein the closed base portion comprises a central portion which extends over at least 50% of an internal radius of a lower end of the hollow body portion and is either substantially flat or has a shallow concave or convex internal curvature, and the transition portion comprises an upwardly and radially outwardly tapering portion extending away from the central portion to connect to the hollow body portion, the tapering portion being inclined at an angle of from 1 to 20 degrees to a longitudinal axis of the preform and the tapering portion increasing in thickness from the central portion to the hollow body portion. Also disclosed is a method of injection moulding the thermoplastic preform.

A light irradiation molding apparatus 1 includes a pair of rubber die units 2A and 2B, which are formed of a rubber material having a property of transmitting light X therethrough and form a cavity between facing sides which face each other, and a light irradiation means 4, which applies light X to a particulate or solid thermoplastic resin 6 arranged in the cavity 20 through surfaces of a pair of the rubber die units 2A and 2B. The light irradiation molding apparatus 1 is constituted so that a pair of the rubber die units 2A and 2B are made to come close to each other while the thermoplastic resin 6 arranged in the cavity 20 is molten by the light X applied from the light irradiation means 4, and a molded article 7 of the thermoplastic resin 6 is formed in the cavity 20 having a reduced volume.

A tandem mold for creating injection-molded parts from synthetic material includes a first part (2), a second part (4), a third part (6), and a guide (20, 22, 26, 28). A first parting surface is defined between the first part (2) and the third part (6), and a second parting surface is defined between the second part (4) and the third part (6). The mold also includes, for each parting surface, at least one mechanical stop (44) that is movable between a first position, where said stop prevents a drive mechanism from reaching the closed position of the mold, and a second position, or retracted position, where the mold can reach its closed position.

A mold for a plastic lens that arranges an insert member inside a cavity formed between a pair of halved molds, injects and fills molten raw material resin to mold a plastic lens having a predetermined shape, integrally with the insert member. The insert member is arranged on a molding surface on one of the halved molds, a notch to be engaged with a positioning tab formed at a periphery of the insert member is engraved on one parting surface of the halved mold, overlapping with a gate position. Positioning of the insert member is performed by engaging the positioning tab with the notch. With this configuration, in molding a plastic lens having an insert member by injection molding including insert molding, positioning of the insert member is performed at the gate position without deteriorating the quality of a molded product and without increasing the load of post-processing after molding.

A display cover can include a rectangular body having opposing outer and inner surfaces and an edge that connects the outer and inner surfaces. A central region, widthwise edge regions, and lengthwise edge regions can each define a portion of the outer and inner surfaces, and the edge regions each can extend from the central region to define a portion of the edge. The central region can be planar such that a plane lies between the outer and inner surfaces throughout the central region. Each of the widthwise edge regions can curve away from the central region such that a line that is tangent to the outer surface at the edge region is substantially perpendicular to the plane of the central region. The body's average thickness can be less than or equal to 0.5 mm, and the body can comprise at least a majority, by weight, of a polymeric material.

Methods, systems, and devices for manufacturing a wearable ring device are described. A printed circuit board (PCB) may be connected to an inner cover, where one or more apertures of the inner cover are aligned with one or more sensors of the PCB. Additionally, an injection molding process may be performed to fill a cavity between the inner cover and a surface of one or more molds with a filler material. The filler material may bind the PCB to the inner cover and fill the one or more apertures with the filler material, creating a ring assembly. Following the injection molding process, an outer cover may be placed around the ring assembly and one or more side covers may engage to secure the inner cover to the outer cover.

The present invention provides a method for manufacturing a press-molded body, the method having a step for disposing an X material inside a mold, a step for closing the mold and extruding a Y material, which is a kneaded material, into the mold after pressure has begun to be applied to part of the X material, and a step for cold-pressing and integrally molding the X material and the Y material inside the mold, wherein: the X material includes reinforcing fibers FA, having a weight-average fiber length Lw.sub.A, and a thermoplastic resin R.sub.X; the Y material includes reinforcing fibers FB, having a weight-average fiber length Lw.sub.B, and a thermoplastic resin R.sub.Y; Lw.sub.B<Lw.sub.A; Lw.sub.A is 1 mm or greater and 100 mm or less; the X material has a spring-back amount greater than 1.0 and less than 14.0; the press-molded body has an vertical plane part and a top plane part; during the cold pressing, the Y material is caused to move from a region other than a vertical plane portion to the vertical plane portion; and a thickness t1 of the vertical plane portion and a thickness t2 of the top plane portion satisfy t1>t2.

The present invention is intended to provide a protective cover having a reliable sensor holder part that prevents reduction in air tightness and strength of a division wall between a magnetic sensor and a magnetic encoder.

A protective cover 1 is press-fitted into an outer ring to seal one axial end portion of a bearing, and has a sensor holder part 3B holding a magnetic sensor A. In the protective cover 1, a disc-shaped member 3 has a thick part 6 as a flow path for preferentially charging a molten resin into a thin part for forming a division wall B in a cavity of a molding die for use in injection molding between a position corresponding to a gate of the molding die and the division wall B.

Injection molding at substantially constant pressure and utilizing sequential coining to produce molded parts substantially free of cosmetic and mechanical defects.