Abstract: A soldering apparatus includes an application device, a conveying device and an application nozzle. The application device has a laser duct extending straight from a laser entry at the top to a laser exit at the bottom and a drop duct that extends from a drop entry at the top to a drop exit at the bottom of the application device. The conveying device separately conveys solder bodies to the drop entry. The application nozzle temporarily holds solder bodies received from the drop exit. The laser and drop ducts are interconnected over their entire lengths from the top to the bottom of the application device. The drop entry and laser entry are side by side and form a common entry. The drop exit and laser exit are spatially coincident and form a common exit that is smaller than the common entry. The application nozzle is connected to the common exit.

Abstract: A method for forming a contact connection between a chip-and a conductor material formed on a non-conductive substrate, the chip being arranged on the substrate or on another conductor material track, a sinter paste consisting of at least 40% silver or copper being applied to respective chip contact surfaces of the chip and the conductor material track, a contact conductor being immersed in the sinter paste on the chip contact surface and in the sinter paste on the conductor material track, and the contact connection being formed by sintering the sinter paste by means of laser energy.

Abstract: A laser soldering system and a method for monitoring a laser soldering process by means of a monitoring device of the laser soldering system, wherein a solder ball is dispensed onto a solderable surface of a substrate by means of a solder ball feeding device of the laser soldering system, wherein the solder ball is at least partially melted by means of a laser device of the laser soldering system, wherein, during the laser soldering process, a light signal is formed which is detected by means of an optical detection unit of the monitoring device, wherein the light signal is dispersed into a spectrum of the light signal by means of a spectroscope device of the monitoring device, wherein the spectrum is analyzed by means of a processing device of the monitoring device, and it is identified on the basis of a composition of the spectrum whether or not a burning of the substrate has occurred during the laser soldering process.

Abstract: A press-forming device for forming individual solder bodies from a wire of soldering material includes a press-forming mechanism and a separation means. The press-forming mechanism forms a continuous strand of preformed solder sections from the wire by using two notched rollers that rotate in opposite directions and that press opposite notches into the wire. The preformed solder sections are disposed equidistantly along the strand and are connected to each other by connecting links disposed at the notches. The separation means forms individual solder bodies by separating the preformed solder sections one by one at the connecting links. The separation means separates individual preformed solder sections using a cutting mechanism that moves in a direction perpendicular to the length direction of the strand. Individual solder bodies are transported to a solder jetting section where they are liquefied by a laser beam and jetted from the solder jetting section by gas pressure.

Abstract: A laser-assisted soldering apparatus includes a solder jetting section and a laser coupling unit. The solder jetting section includes a jetting nozzle and a solder body holding capillary adapted to hold a solder body that is being liquefied by a laser beam. The laser coupling unit includes an optical window, a laser entry, a laser passage, a fastening section, and a laser exit. The laser passage extends from the laser entry to the laser exit and is aligned with the solder body holding capillary. The optical window is transparent to the laser beam. The fastening section is fastened to the solder jetting section. A first pressure gas feeding passage merges into the laser passage between the optical window and the fastening section. The solder jetting section includes a second pressure gas feeding passage that merges into the solder body holding capillary between the laser exit and the jetting nozzle.

Abstract: A method for soldering an electronic component to a circuit board involves jetting liquefied solder. A laser beam melts a solid solder ball to produce a liquefied solder ball before the ball is jetted. The liquefied solder ball is jetted towards a through hole in the circuit board such that a portion of the liquefied solder ball flows into an annular gap between a pin and sides of the through hole. The pin is attached to the electronic component and passes through the through hole. As the liquefied solder ball is jetted towards the through hole, the laser beam is directed at the ball so as to keep it liquefied. How much of the solder ball remains outside the through hole after liquefied solder has flowed into the annular gap is determined. The filling degree of the annular gap is determined based on how much solder remains outside the hole.

Abstract: A semiconductor-chip stack package includes a plurality of semiconductor chips disposed in a stack arrangement and at least one connecting substrate which connects the semiconductor chips. The semiconductor chips include a chip terminal face on a chip edge extending at least partially as a side terminal face in a side surface of the semiconductor chip. The side surfaces of the semiconductor chips provided with the side terminal face are arranged in a shared side surface plane S of the semiconductor-chip stack arrangement. The connecting substrate is arranged with a contact surface parallel to the side surface plane S of the semiconductor chips. Substrate terminal faces are formed on the contact surface for connecting a connection conductor structure formed in the connecting substrate and which are connected to the side terminal faces via a connecting material in a connection plane V1 parallel to the contact surface.

Abstract: A device for removing or repositioning defective and erroneously placed electronic components from circuit boards includes a vacuum suction nozzle, a laser beam and a temperature sensor. The vacuum nozzle has an adaptor tip at which suction is generated. The adaptor tip is larger than the defective or erroneously positioned electronic component. The laser beam is emitted out of the suction opening towards the electronic component on the circuit board. The temperature sensor measures the temperature of the electronic component based on infrared radiation emitted from around the electronic component. A method for removing or repositioning the defective or erroneously placed electronic component from the circuit board positions the adaptor tip over the electronic component and directs the laser beam through the suction opening and onto the electronic component so as to heat and detach the electronic component, which is then removed or repositioned and remounted on the circuit board.

Abstract: A device for removing a defective electronic component from a circuit board includes a vacuum suction nozzle, a laser beam emitter and an infrared temperature sensor. The vacuum suction nozzle has a suction opening at which suction is generated. The suction opening is dimensioned to be larger than the defective electronic component. The laser beam emitter is oriented so as to emit a laser beam out the suction opening towards the electronic component on the circuit board. The temperature sensor measures the temperature of the electronic component based on infrared radiation emitted from around the electronic component. A method for removing the defective electronic component from the circuit board includes positioning the suction opening over the electronic component and directing the laser beam through the suction opening and onto the electronic component so as to heat and detach the electronic component, which is then sucked into the vacuum suction nozzle.

Abstract: A method and a device for establishing a wire connection between a first contact surface and at least one further contact surface. A contact end of a wire is positioned in a contact position relative to the first contact surface with a wire guiding tool. Subsequently, a mechanical, electrically conductive connection is established between the first contact surface and the contact end with a first solder material connection, and subsequently the wire guiding tool is moved to the further contact surface thus forming a wire section and establishing a further mechanical, electrically conductive connection between the wire section end and the further contact surface with a further solder material connection.

Abstract: A semiconductor-chip stack package includes a plurality of semiconductor chips disposed in a stack arrangement and at least one connecting substrate which connects the semiconductor chips. The semiconductor chips include a chip terminal face on a chip edge extending at least partially as a side terminal face in a side surface of the semiconductor chip. The side surfaces of the semiconductor chips provided with the side terminal face are arranged in a shared side surface plane S of the semiconductor-chip stack arrangement. The connecting substrate is arranged with a contact surface parallel to the side surface plane S of the semiconductor chips. Substrate terminal faces are formed on the contact surface for connecting a connection conductor structure formed in the connecting substrate and which are connected to the side terminal faces via a connecting material in a connection plane V1 parallel to the contact surface.

Abstract: A method and a device for establishing a wire connection between a first contact surface and at least one further contact surface. A contact end of a wire is positioned in a contact position relative to the first contact surface with a wire guiding tool. Subsequently, a mechanical, electrically conductive connection is established between the first contact surface and the contact end with a first solder material connection, and subsequently the wire guiding tool is moved to the further contact surface thus forming a wire section and establishing a further mechanical, electrically conductive connection between the wire section end and the further contact surface with a further solder material connection.

Abstract: A method for joining aligned discrete optical elements by which the optical elements can be joined in the aligned state. A thermal connection having long-term stability can be produced at little expense and with high positioning accuracy. Surface regions to be joined can be provided with at least one thin metallic layer by the method for joining aligned discrete optical elements. The surface regions are subsequently wetted using a liquid solder free of flux in a contactless dosed manner. The solder is applied to the surface regions to be joined via a nozzle using a pressurized gas stream.

Abstract: A method for joining aligned discrete optical elements by which the optical elements can be joined in the aligned state. A thermal connection having long-term stability can be produced at little expense and with high positioning accuracy. Surface regions to be joined can be provided with at least one thin metallic layer by the method for joining aligned discrete optical elements. The surface regions are subsequently wetted using a liquid solder free of flux in a contactless dosed manner. The solder is applied to the surface regions to be joined via a nozzle using a pressurized gas stream.