A printed circuit board includes an internal insulating layer, an internal conductive pattern layer disposed on the internal insulating layer and including a line portion and a bonding pad portion, and an external insulating layer disposed on the internal conductive pattern layer and the internal insulating layer and having an accommodation groove extending therethrough to expose the bonding pad portion. The bonding pad portion includes a connection pattern extending from the line portion of the internal conductive pattern layer embedded in the external insulating layer, and exposed to the accommodation groove; a land pattern disposed closer to a center portion of the accommodation groove than the connection pattern; and a dam pattern connecting the connection pattern and the land pattern, in which a line width of the dam pattern is narrower than a line width of the land pattern.

A light device may include a printed circuit board having at least one conductive section. An LED may be electrically connected and fixed on a conductive section of the printed circuit board by means of a soldered connection. The printed circuit board may also include a coating-type insulating layer and/or the conductive section has an edge. The fixing region of the LED is connected to a discharge space by means of an outlet, so that during the production process, melted solder can flow off in a defined manner. The arrangement and/or embodiment of the outlet is such that in a preferred direction of movement of the LED is developed in order to position same in a defined manner.

A method for producing an electric circuit in which a contact carrier comprising a first contact area and a second contact area is provided. An insulating body is applied to the circuit carrier and at least partially covers the first contact area and the second contact area. The insulating body comprises cut-outs in regions both contact areas. A flowable electrical conducting medium is introduced into the insulating body.

According to one embodiment, a printed wiring board includes a wiring board, a connector part, a connection pad provided between the wiring board and the connector part and connected with the connector part with a solder material and a guide groove provided in the wiring board to be continuous to the connection pad, to guide a portion of the solder material from the connection pad.

A defect may occur in which as the amount of fluid discharged by a fluid discharge device decreases, a mask is not filled with the fluid even when the fluid is discharged. In order to fill a workpiece with the fluid, it is necessary to replace air in the workpiece corresponding to a discharge part with the fluid. The air in the workpiece is removed in advance, thereby filling the workpiece with the discharged fluid. A fluid discharge device in which, at one end of a discharge head, a suction port for sucking air in the mask on the workpiece, and a fluid discharge device having a discharge nozzle formed thereon for discharging the fluid are formed is used.

According to one embodiment, a printed wiring board includes a wiring board, a connector part, a connection pad provided between the wiring board and the connector part and connected with the connector part with a solder material and a guide groove provided in the wiring board to be continuous to the connection pad, to guide a portion of the solder material from the connection pad.

The invention relates to a method (20) for producing an electric circuit (2) in which a circuit carrier (4) comprising a first contact surface (14) and a second contact surface (16) is provided. An insulating body (26) is placed on the circuit carrier (4), wherein the insulating body (26) at least partially covers the first contact surface (14) and the second contact surface (16), and the insulating body (26) comprises a recess (34) in the region of both contact surfaces (14, 16). A flowable electro-conductive medium (44) is introduced into the insulating body (26). The invention also relates to an electric circuit (2) and to a further method (60) for producing an electric circuit (2).

A method for forming an electronic device that includes solder bonding pins from a component to plated through holes of a board, the component being positioned on a first side of the board; and applying solder paste to openings of the plated through holes on a second side of the board opposite the first side of the board that the component is positioned on. The method can further include drawing the solder paste to the pins to provide a reworked solder bond bonding at least one of the pins to the plated through hole.

The present disclosure provides a conductor connecting structure that connects a cable to a substrate, where the substrate includes at least one connection pad, the cable includes at least one core wire, the core wire is connected to an upper surface of the connection pad through soldering, and the connection pad includes a solder storing part that is present further frontward than a front end of the core wire.

A connecting arrangement. The connecting arrangement includes at least a first connecting partner and a second connecting partner, which are connected integrally together using a solidified solder layer, arranged between the connecting partners, with a solder layer thickness. Each connecting partner has a solder connection surface, which are wettable by the solder material in a molten state. The solder connection surfaces are arranged one above the other and face one another so that both are each contacted at least regionally by the solidified solder layer. Each solder connection surface is configured such that a perpendicular projection of both solder connection surfaces onto one another has at least one definable projection area with mutually overlapping solder connection surface parts. The definable projection area has a peripherally closed edge with at least one contained first cohesive projection sub-area, which is directly adjoined by at least one or more further projection sub-areas.