According to one embodiment, provided are an electronic device and an electronic component protection substrate in which an electronic component is prevented from entering an irregular state. According to the electronic device of the present embodiment, an electronic component is soldered onto a pattern line of a printed circuit substrate, and a surface of the printed circuit substrate where the electronic component is disposed is formed as a recess such that the thickness of the printed circuit substrate in the recess part is thinned.

The invention relates to a thermode for connecting at least two components, comprising a tip having a body portion with at least two contact surface portions connected to and spaced apart from one another by a recess configured to receive a portion of one of the at least two components; and a support portion having at least one supporting surface portion configured to support a further component (being the other of the at least two components, wherein the contact surface portions and the supporting surface portion are configured to receive the at least two components between them and wherein one or both of the contact surface portions and the supporting surface portion are moveable relative to and towards one another to exert heat and/or pressure on the at least two components located between the contact surface portions and the supporting portion.

Various embodiments include a method for producing electronic assemblies. The method may include: applying a fluid printing medium in a structured manner using a printing device multiple times consecutively in a sequential series of individual printing steps; measuring a rheological property of the printing medium in an automated repeated series of individual measurement steps during or between the individual printing steps; executing a computer-implemented rheological model for the execution of the individual printing steps, using the repeatedly measured rheological property as a variable input parameter; determining a favorable value for a selected printing parameter with the rheological model based on the currently measured rheological property; and automatically setting the determined favorable value for the selected printing parameter.

Printed circuit board assemblies (PCBAs) are a fundamental component used in nearly all electronics. PCBAs provide electrical connections and mechanical support to electronic components and are generally made of copper layers laminated onto, though, and/or between one or more non-conductive substrate layers. Press-fit pin connections are often driven through the non-conductive substrate layers to connect power or ground across multiple conductive copper layers within a PCBA and/or connect electronic components on opposing sides of the substrate layer(s). Some new PCBA designs utilize fewer, but larger contact pins (e.g., power pins) in place of a greater number of smaller contact pins. With larger contact pin sizes, press-fit pin connections become more difficult to achieve with repeatable reliability in electrical connection without damaging surrounding features in a PCBA. The press-fitting assembly fixtures, contact pins, and methods described herein are capable of repeatable reliability and avoiding open and short failures.

A pre-tin shaping system is disclosed. The pre-tin shaping system comprises a base securely holding a circuit board having a pre-tin layer, a heat-press unit having a contact tip, and a movable unit moving the heat-press unit relative to the base. The contact tip is movable to shape the pre-tin layer.

Embodiments of the invention include flexible circuit board interconnections and methods regarding the same. In an embodiment, the invention includes a method of connecting a plurality of flexible circuit boards together comprising the steps applying a solder composition between an upper surface of a first flexible circuit board and a lower surface of a second flexible circuit board; holding the upper surface of the first flexible circuit board and the lower surface of the second flexible circuit board together; and reflowing the solder composition with a heat source to bond the first flexible circuit board and the second flexible circuit board together to form a flexible circuit board strip having a length longer than either of the first flexible circuit board or second flexible circuit board separately. In an embodiment the invention includes a circuit board clamp for holding flexible circuit boards together, the clamp including a u-shaped fastener; a spring tension arm connected to the u-shaped fastener; and an attachment mechanism connected to the spring tension arm. Other embodiments are also included herein.

A camera module, a molded circuit board assembly, a molded photosensitive assembly and manufacturing method thereof are disclosed. The camera module includes a molded base which is integrally formed with a circuit board through a molding process, wherein a photosensitive element may be electrically connected on the circuit board and at least a portion of a non-photosensitive area portion of the photosensitive element is also connected by the molded base through the molding process. A light window is formed in a central portion of the molded base to provide a light path for the photosensitive element, wherein a cross section of the light window is configured to have a trapezoidal or multi-step trapezoidal shape which has a size increasing from bottom to top to facilitate demolding and avoiding stray lights.

A vertical circuit board printer includes a multi-layer conveyor, a printer assembly, and a control system. The multi-layer conveyor includes a number of front conveyors and one rear conveyor. Each upper front conveyor is coupled to a lower front conveyor by a circuit board-lowering mechanism to transport a number of circuit boards in sequence from the number of front conveyors to the rear conveyor. The printer assembly includes a number of printers arranged in sequence above the number of front conveyors. The control system controls operation of the multi-layer conveyor and controls operation of the printing assembly through a software system.

A wiring board manufacturing method and a wiring board in which a pattern can be simply and easily formed even when using a coating composition having a high surface tension are provided. The method includes a transferring step of bringing a resin composition containing a first compound inducing a low surface free energy and a second compound inducing a surface free energy which is higher than that of the first compound into contact with a master on which a desired surface free energy difference pattern is formed and curing the resin composition to form a base material to which the surface free energy difference pattern is transferred; and a conductor pattern forming step of applying a conductive coating composition onto a pattern transfer surface of the base material to form a conductor pattern, the base material having a pattern of a high surface free energy region and a low surface free energy region, and the high surface free energy region having a surface free energy of more than 62 mJ/m.sup.2.

A circuit board according to an embodiment includes a first insulating layer; a second insulating layer disposed on the first insulating layer and including a cavity; and a plurality of pads disposed on the first insulating layer and having top surfaces exposed through the cavity; wherein the cavity of the second insulating layer includes: a bottom surface positioned higher than a top surface of the first insulating layer; and an inner wall extending from the bottom surface, wherein the inner wall is perpendicular to top or bottom surface of the second insulating layer, wherein the bottom surface of the cavity includes: a first bottom surface positioned lower than a top surface of the pad and positioned outside an arrangement region of the plurality of pads; and a second bottom surface positioned lower than the top surface of the pad and positioned inside the arrangement region of the plurality of pads, and wherein a height of the first bottom surface is different from a height of the second bottom surface.