The present invention is directed to a golf ball having a cover in which the dimples have two distinct hardness regions. The cover of the present invention is formed from a castable formulation including at least one prepolymer that incorporates some degree of unsaturation in the backbone of the polymer, at least one curative, and at least one free radical initiator. The present invention also explores the methods of making such golf balls. The methods of the present invention allow for the production of a golf ball dimple with two distinct hardnesses to be formed using a single castable formulation.

Disclosed is a technique capable of preventing an encapsulating material from covering a heat-dissipating surface of a semiconductor module, which releases heat of a switching element. Specifically disclosed a step for manufacturing a semiconductor module including a submodule having a collector and an emitter with heat-dissipating surfaces, including a step for placing the submodule in the cavity so that the submodule is pressed by the pressing device while covering the heat-dissipating surface of the emitter with the pressing device and covering the heat-dissipating surface of the collector with the lower mold, and a step for feeding the encapsulating material to the cavity by moving the piston so that the pressure of the cavity measured by the pressure measuring device does not exceed the pressure at which the pressing device presses the submodule.

The present invention is directed to a golf ball having a cover in which the dimples have two distinct hardness regions. The cover of the present invention is formed from a castable formulation including at least one prepolymer that incorporates some degree of unsaturation in the backbone of the polymer, at least one curative, and at least one free radical initiator. The present invention also explores the methods of making such golf balls. The methods of the present invention allow for the production of a golf ball dimple with two distinct hardnesses to be formed using a single castable formulation.

According to one implementation, a composite material molding jig includes a rigid portion and a convex portion for forming a groove for inserting an optical fiber sensor. The rigid portion has a surface for laminating prepreg sheets. The convex portion is formed in a surface side of the rigid portion. Further, according to one implementation, a composite material molding method is a method for molding a composite material, on which the groove for inserting the optical fiber sensor has been formed, by heating and curing a laminated body of the prepreg sheets laminated on the above-mentioned composite material molding jig.

A method of embedding opto-electronic components in a layer, wherein the components are disposed beside one another to be spaced apart on a carrier, including providing a molding tool having a bearing plate, wherein the bearing plate on a lower side includes resilient bearing regions, bringing the bearing plate by way of the resilient bearing regions to bear on upper sides of the components, filling an intermediate space between the components, the carrier, and the bearing plate with a molding material, curing the molding material to form the layer, and removing the molding tool from the layer and the embedded components.

A soft mold tool including an elastomeric material; and a photomask; wherein the photomask is positioned within the elastomeric material is disclosed. Additionally, a soft mold tool, including an elastomeric material; and an opaque material on a portion of a surface of the elastomeric material is disclosed. A method of making the soft mold tool is also disclosed.

The present disclosure is directed methods for modifying molds of rotor blades of a wind turbine. In certain embodiments, the blade mold is constructed, at least in part, of a thermoplastic material optionally reinforced with a fiber material. In one embodiment, the method includes identifying at least one blade mold addition for the mold of the rotor blade and positioning the blade mold addition at a predetermined location of the mold of the rotor blade. Further, the blade mold addition is constructed, at least in part, of a thermoplastic material. Thus, the method includes applying at least one of heat, pressure, or one or more chemicals at an interface of the blade mold addition and the mold so as to join the blade mold addition to the mold. In further embodiments, the methods described herein are also directed repairing thermoplastic blade molds.

The present invention discloses a texture structure, an optical thin film, a mould and an electronic device cover plate. The texture structure comprises a plurality of distributed short lines, the plurality of short lines are arranged to be protruded and/or depressed, a gap is provided between adjacent short lines, and the gap forms an optical structure. The present invention provides a new texture structure, of which a direction of the short lines can be changed in a certain direction randomly or according to an expected effect, a side surface of the short line being an arc-shaped surface, adjacent arc-shaped surfaces connecting with each other to form a gap, and the gap being an optical structure, and provides an optical thin film having the texture structure, the optical thin film using this texture having at least one light beam under a certain light source and reducing to a certain extent the influence of rainbow streaks on light-shadow effects, and also provides an electronic device cover plate using the texture structure or the optical thin film, by which the rotational angles of the short lines can be used flexibly to realize different light-shadow effects of the electronic device cover plate.

A tooling device for making a plastic film component. The tooling device includes a molding tool having a molding part, a receptacle, an opening and closing device, and at least one covering device having a covering surface and guide arrangement. The molding part and the receptacle are movable relative to each other between a closed and an open position. Relative movement between the molding part and the receptacle to the closed position is transmitted to the covering device to move it from an exposed position, in which the covering surface is spaced from an inner surface of the molding part, to a covered position, in which the covering surface covers a covered section of molding part's inner surface.

According to one implementation, a composite material molding jig includes a rigid portion and a convex portion for forming a groove for inserting an optical fiber sensor. The rigid portion has a surface for laminating prepreg sheets. The convex portion is formed in a surface side of the rigid portion. Further, according to one implementation, a composite material molding method is a method for molding a composite material, on which the groove for inserting the optical fiber sensor has been formed, by heating and curing a laminated body of the prepreg sheets laminated on the above-mentioned composite material molding jig.