A tool for driving a threaded fastener includes a driver head, a motor, and an injector. The driver head includes a spindle rotatable about an axis. A distal end of the spindle defines a plurality of drive surfaces configured to engage mating drive surfaces on the fastener to rotate the fastener about the axis. The driver head defines a fluid passage having an outlet proximate to the distal end of the spindle. The motor is drivingly coupled to the spindle to rotate the spindle about the axis. The injector is coupled to an inlet of the fluid passage and configured to feed a liquid insulator through the fluid passage.

The present invention provides a resin molded product production method that can reduce the molding defects even when resin-molding is performed in a state where a chip is temporarily bonded to a carrier via a temporary bonding sheet. The method for producing a resin molded product obtained by subjecting an object to be molded being a chip 21 temporarily bonded to a carrier 11 via a temporary bonding sheet 12 to transfer molding, including the step of: resin-molding the object to be molded by transfer molding using a molding die 1000, wherein the resin-molding is performed in a state where a gap G is formed so that the temporary bonding sheet 12 disposed in the molding die 1000 and a surface facing the temporary bonding sheet 12 on a side where the chip 21 is temporarily bonded do not come into contact with each other.

Provided are methods of forming thermally conductive flexible bonds for use in electronic boards of unmanned spacecraft and other types of aircraft. Also provided are methods of preparing adhesive materials to form these bonds including methods of preparing treated filler particles. In some aspects, an adhesive material includes filler particles having organofunctional groups, such as boron nitride particles treated in silane. These particles may be combined with a urethane modified epoxy to form the adhesive material. The weight ratio of the particles in the adhesive material may be about 40-60%. The adhesive material may be thermally cured using a temperature of less than 110° C. to prevent damage to bonded electronic components. The cured adhesive may have a thermal conductivity of at least about 2 W/m K measured in vacuum and may have a glass transition temperature if less than −40° C.

A method, for manufacturing an electronic assembly, such as an antenna or a capacitive sensing device or a coupled inductor, comprising at least a first electrically conductive element and a second electrically conductive element is presented. The method comprises obtaining said electrically conductive elements, such as patch elements, arranging said electrically conductive elements, such as inside of a cavity defined by a mold structure, at a pre-defined distance from each other for establishing an electromagnetic coupling between said electrically conductive elements, and molding, such as injection molding, a molding material layer at least between said electrically conductive elements, wherein the molding material layer has a thickness between said electrically conductive elements defined by the pre-defined distance. In addition, electronic assemblies, antennas, capacitive sensing devices and coupled inductors are presented.

A method, for manufacturing an electronic assembly, such as an antenna or a capacitive sensing device or a coupled inductor, comprising at least a first electrically conductive element and a second electrically conductive element is presented. The method comprises obtaining said electrically conductive elements, such as patch elements, arranging said electrically conductive elements, such as inside of a cavity defined by a mold structure, at a pre-defined distance from each other for establishing an electromagnetic coupling between said electrically conductive elements, and molding, such as injection molding, a molding material layer at least between said electrically conductive elements, wherein the molding material layer has a thickness between said electrically conductive elements defined by the pre-defined distance. In addition, electronic assemblies, antennas, capacitive sensing devices and coupled inductors are presented.

A chuck assembly for holding a plate comprises a member configured to hold the plate, the member including a flexible portion configured to have a central opening, and a first cavity formed by the flexible portion, wherein the plate is held by the flexible portion by reducing pressure in the first cavity, a light-transmitting member covering the central opening of the member, and a fluid path in communication with a second cavity defined by the member, the plate held by the member and the light-transmitting member for pressurizing the second cavity.

A resin molding apparatus includes: a first molding mold provided with a first member and a second member configured to move relative to the first member, and configured to form a cavity by the first member and the second member; a second molding mold configured to hold a substrate; and a mask member so as to be relatively immovable with respect to the first member, configured to make contact with a portion of the substrate when the first molding mold and the second molding mold are clamped, and formed with a flow portion through which a resin material existing in the cavity and pressurized by the second member is capable of flowing.

A resin molding apparatus includes: a resin supply mechanism including a nozzle for ejecting liquid resin to a supply target; a resin collection unit including: a resin-receiving member configured to receive a portion of the liquid resin which portion has dropped from the nozzle; and a movement mechanism configured to cause the resin-receiving member to move in such a manner as to follow the nozzle while keeping the resin-receiving member under the nozzle; a mold die including an upper die and a lower die facing the upper die; a mold clamp mechanism configured to clamp the mold die with the supply target between the upper die and the lower die; and a control section configured to control at least respective operations of the resin supply mechanism and the resin collection unit.

The present invention provides an imprint apparatus that performs a process of forming an imprint material on a substrate using a mold, with respect to each of a plurality of shot regions on the substrate, the apparatus comprising: a detector configured to detect positions of marks provided in the substrate; and a controller configured to control, in the process, alignment between the substrate and the mold based on a detection result by the detector, wherein each of the plurality of shot regions includes two or more transfer regions where a pattern of an original has been individually transferred in a pre-process, and in the process on a specific shot region, the controller controls the alignment based on the detection result of the marks provided in the transfer region other than the smallest transfer region among the two or more transfer regions.

A resin molding apparatus includes: a first molding mold provided with a first member and a second member configured to move relative to the first member, and configured to form a cavity by the first member and the second member; a second molding mold configured to hold a substrate; and a mask member so as to be relatively immovable with respect to the first member, configured to make contact with a portion of the substrate when the first molding mold and the second molding mold are clamped, and formed with a flow portion through which a resin material existing in the cavity and pressurized by the second member is capable of flowing.