A method for joining a thermoplastic film to a metal component, at least comprising the following method steps: providing the metal component with a joining surface, incorporating microstructures and/or nanostructures into the joining surface of the metal component, arranging the thermoplastic film on the joining surface of the metal component, softening the thermoplastic film by heating to a temperature above the glass transition temperature of the thermoplastic film, pressing the softened thermoplastic film onto the joining surface of the metal component in such a way that part of the softened thermoplastic film penetrates into the microstructures and/or nanostructures in the joining surface of the metal component, and obtaining an interlocking connection between the thermoplastic film and the metal component after the thermoplastic film has cooled.

In a case where a circuit wiring is formed on a resin member by three-dimensional additive manufacturing, a method for manufacturing the circuit wiring by three-dimensional additive manufacturing capable of suppressing swelling or cracking of the circuit wiring is provided. A method for manufacturing a circuit wiring by three-dimensional additive manufacturing includes a discharging step of discharging a fluid containing a metal particle onto a resin member formed of a resin material; and a circuit wiring forming step of forming a circuit wiring by heating the fluid containing the metal particle discharged onto the resin member at a heating temperature to be cured, and the heating being performed at the heating temperature based on a glass transition point of the resin material, a linear expansion coefficient of the resin material, and a room temperature.

A three-dimensional molding machine includes a three-dimensional molding device configured to mold a three-dimensional molded object on a molding pallet, a circuit forming device configured to form a circuit pattern on the molded object during or after molding, a component mounting device configured to mount an electronic component on the circuit pattern formed on the molded object, a pallet conveyance device configured to convey the molded object together with the molding pallet between the three-dimensional molding device, the circuit forming device, and the component mounting device, and a component conveyance device configured to the electronic components into the component mounting device from an outside of the machine.

A three-dimensional molding machine for manufacturing a three-dimensional molded object comprising an electronic circuit includes multiple modules disposed adjacent to each other, a work unit provided in each of the multiple modules and configured to share a manufacturing operation for manufacturing the three-dimensional molded object on a pallet, and a pallet conveyance section provided in each of the multiple modules and configured to convey the pallet into and out of a module and to transfer the pallet between the module and another adjacent module of the multiple modules.

A method for manufacturing a Z-directed component for insertion into a mounting hole in a printed circuit board according to one example embodiment includes simultaneously extruding a plurality of materials according to the structure of the Z-directed component to form an extruded object and forming the Z-directed component from the extruded object. In one embodiment, the extruded object is divided into individual Z-directed components. In one embodiment, the timing of extrusion between predetermined sections of one of the materials is varied in order to stagger the sections in the extruded object.

A system for manufacturing an electromechanical structure includes first, second, and third entities. The first entity produces conductors on a planar, flat film. The second entity attaches electronic elements at locations on the film in relation to a three-dimensional shape of the film. The electronic elements include a number of surface mount technology components. The locations of the electronic elements are selected to omit substantial deformation during subsequent forming of the film into the three-dimensional shape. The third entity forms the film into the three-dimensional shape when the electronic elements are supported on the film. The third entity includes one or more machines that are continuously roll-fed, automatically in-precut-pieces-fed, computer numerical control, thermoforming, vacuum former, pressure forming, or blow molding. The first, second, and third entities are arranged relative to one another to manufacture the electromechanical structure.

A method includes placing a package structure into a mold chase, with top surfaces of device dies in the package structure contacting a release film in the mold chase. A molding compound is injected into an inner space of the mold chase through an injection port, with the injection port on a side of the mold chase. During the injection of the molding compound, a venting step is performed through a first venting port and a second venting port of the mold chase. The first venting port has a first flow rate, and the second port has a second flow rate different from the first flow rate.

Methods are provided for manufacturing flat devices to be used for forming a shape-retaining non-flat device by deformation of the flat device. Based on the layout of a non-flat device, a layout of a flat device is designed. A method for designing the layout of such a flat device is provided, wherein the method includes inserting mechanical interconnections between pairs of elements to define the position of the elements on a surface of the non-flat device, thus leaving zero or less degrees of freedom for the location of the components. Based on the layout of a flat device thus obtained, the flat device is manufactured and next transformed into the shape-retaining non-flat device by means of a thermoforming process, thereby accurately and reproducibly positioning the elements at a predetermined location on a surface of the non-flat device.

The invention provides a method for manufacturing a 3D item (10) comprising an electrically conductive coil (140) of at least part of an electrically conductive wire (51), wherein the method comprising printing with a fused deposition modeling (FDM) 3D printer (500) 3D printable material (201), wherein the 3D printable material (201) comprises the electrically conductive wire (51), to provide the 3D item (10) comprising the electrically conductive coil (140).

A method of forming a protective film on at least one electronic module is provided. The method includes the following steps. A protective material is disposed on at least one electronic module such that the protective material and the electronic modules are in contact with each other. The electronic modules and the protective material disposed on the electronic modules are disposed in a chamber, and a first ambient pressure is provided in the chamber. The protective material in the chamber is heated to a first temperature to soften the protective material disposed on the electronic modules. After the protective material is softened, a second ambient pressure greater than the first ambient pressure is provided in the chamber, wherein a gas in the chamber directly pressurizes the protective material such that the protective material conformally covers a top of the electronic modules. The protective material conformally covering the top of the electronic modules is heated to a second temperature to solidify the protective material conformally covering the top of the electronic modules to form a protective film conformally covering the top of the electronic modules.