Various embodiments of the present disclosure are directed to a method for producing a ball valve for regulating a fluid. In one example embodiment, the method includes the steps of: providing first and second housing parts of the valve housing, said first and second housing parts each including at least a central housing part and a connection end; providing a valve element shaped as a ball with at least one through-going aperture; arranging the first and second housing parts with the respective central part ends facing towards each other, and further arranging the ball at a position inside an inner space defined by the respective central parts; and welding the first and second housing parts together using a welding tool while performing an interrelated rotation about an axial rotation axis between the position of the first and second housing parts and the position of the ball.

Various embodiments of the present disclosure are directed to a method for producing a ball valve for regulating a fluid. In one example embodiment, the method includes the steps of: providing first and second housing parts of the valve housing, said first and second housing parts each including at least a central housing part and a connection end; providing a valve element shaped as a ball with at least one through-going aperture; arranging the first and second housing parts with the respective central part ends facing towards each other, and further arranging the ball at a position inside an inner space defined by the respective central parts; and welding the first and second housing parts together using a welding tool while performing an interrelated rotation about an axial rotation axis between the position of the first and second housing parts and the position of the ball.

A battery bridge for an electronic device, preferably for an electronic implant, has an electrically conductive first contact element, an electrically conductive second contact element and an insulator. The first contact element and the second contact element comprise a weldable material. In a first state of the battery bridge, the first contact element is distanced from the second contact element via a predefined air gap and the first contact element is electrically insulated from the second contact element by the air gap and the insulator. The battery bridge is formed in such a way that it can be transferred, by welding the first contact element and the second contact element together, into a second state, in which the air gap between the first contact element and the second contact element is closed electrically conductively, at least in part. A method for activating such an electronic device is also disclosed.

A method is provided for interconnecting the batteries in a battery pack in a manner that is designed to minimize damage and contamination of the contact surfaces of the interconnect and the battery terminal, thereby minimizing connection resistance and increasing interconnect reliability.

A laser system includes a laser configured to emit pulse bursts and a motion device in optical communication with the laser. The motion device moves a laser beam along a process path on a substrate and is configured to have a natural frequency that is greater than an operating frequency of the laser system. The laser system enables high and constant speed processing along tight radii in the process path, which is useful to form laser induced channels along the process path with equal spacing.

A laser system includes a laser configured to emit pulse bursts and a motion device in optical communication with the laser. The motion device moves a laser beam along a process path on a substrate and is configured to have a natural frequency that is greater than an operating frequency of the laser system. The laser system enables high and constant speed processing along tight radii in the process path, which is useful to form laser induced channels along the process path with equal spacing.

A bonding structure of an electrical contact, a bonding method of the electrical contact and a battery module are provided. The bonding structure of the electrical contact includes an electroconductive part and an electrode sheet welded to the electroconductive part. The electrode sheet is a first metal material, and the electroconductive part is a second metal material. A welding track is formed on an interface formed by combining the electrode sheet with the electroconductive part. The welding track is a mixture of the first metal material and the second metal material. The welding track substantially has no overlap. In addition, the welding track includes a moving path, and a lateral path of performing a wobble movement or an oscillation movement on lateral sides of the moving path.

A method of laser welding a first aluminum workpiece and a second aluminum workpiece arranged to form a lap joint includes forming a laser weld between the first aluminum workpiece and the second aluminum workpiece and forming a lap through weld joint using a weld speed equal to or greater than 10 meters per minute. The laser weld has less than 10% area fraction keyhole voids, for example, less than 5% area fraction keyhole voids and the lap through weld joint can have a flange length of less than 10 mm. The first aluminum workpiece can be an inner workpiece of a halo assembly of a vehicle door, the second aluminum workpiece can be a channel workpiece of the halo assembly and laser welding the inner workpiece to the channel workpiece forms the halo assembly without the use of mechanical fasteners, thereby decreasing weight and costs of the halo assembly.

The present disclosure includes a laser welding method in which a joint surface between a plurality of workpiece members is welded by radiating laser beam LB, and a locus of laser beam LB is controlled so as to perform wobbling scanning Sw by a combination of scanning motion Sa moving along first direction x parallel to the joint surface and swing motion Sb including first swing component Bx along first direction x and second swing component By along second direction y perpendicular to first direction x, the method including a defect determination step of determining occurrence of a welding defect; and an output control step of increasing or decreasing an output of laser beam LB when laser beam LB is radiated again toward the welding defect in a case where the welding defect occurs.

The present disclosure includes a laser welding method in which a joint surface between a plurality of workpiece members is welded by radiating laser beam LB, and a locus of laser beam LB is controlled so as to perform wobbling scanning Sw by a combination of scanning motion Sa moving along first direction x parallel to the joint surface and swing motion Sb including first swing component Bx along first direction x and second swing component By along second direction y perpendicular to first direction x, the method including a defect determination step of determining occurrence of a welding defect; and an output control step of increasing or decreasing an output of laser beam LB when laser beam LB is radiated again toward the welding defect in a case where the welding defect occurs.