A new weld configuration is used to obtain a robust and consistent resistance weld between the tabs of an anode current collector and the casing of an electrochemical cell. This is done by adding a resistive transferable electrode tip between at least one of the welding electrodes, preferably the movable welding electrode, and the stacked parts that are being joined together. The purpose of the transferable electrode tip is to generate a sufficient amount of heat during the welding process so that the stacked parts are joined together without adding any product functionality. In one embodiment of the present invention, the transferrable electrode tip is a stainless-steel ball, the stacked anode current collector tabs are of nickel, and the cell casing is of stainless-steel.

Disclosed is an engine driven power supply that includes a housing having a first area that includes an engine and a second area that includes a temperature sensitive component. A fan is configured to force air in multiple directions through the housing. A temperature sensor to measure a temperature. And a controller controls the fan to force air in a first direction into the first area when the temperature exceeds a first threshold temperature value, and controls the fan to force air in a second direction into the second area when the temperature is below the first threshold temperature value.

The present disclosure generally relates to a welding machine adapted for performing a spot welding process on a workpiece, wherein the welding machine is specifically adapted for automatically applying pre-conditioning a welding pulse portion to the workpiece prior to performing the spot welding process. The present disclosure also relates to a corresponding method and computer program product.

The present disclosure generally relates to a welding machine adapted for performing a spot welding process on a workpiece, wherein the welding machine is specifically adapted for automatically applying pre-conditioning a welding pulse portion to the workpiece prior to performing the spot welding process. The present disclosure also relates to a corresponding method and computer program product.

A setting welding device is set forth for setting stud-like auxiliary joining parts in a plurality of layers of material and subjecting them to a mechanical-thermoforming process on a second layer of material and connecting them to said second layer by way of a welding operation. For this purpose, the punch is used to apply to the welding auxiliary joining part mechanical and thermal loads that follow prescribed characteristic force and current curves. Furthermore, a corresponding connecting method that can be realized with the aid of the setting welding device is also disclosed.

A setting welding device is set forth for setting stud-like auxiliary joining parts in a plurality of layers of material and subjecting them to a mechanical-thermoforming process on a second layer of material and connecting them to said second layer by way of a welding operation. For this purpose, the punch is used to apply to the welding auxiliary joining part mechanical and thermal loads that follow prescribed characteristic force and current curves. Furthermore, a corresponding connecting method that can be realized with the aid of the setting welding device is also disclosed.

The disclosure relates to a measuring device (1) for automated welding devices, in particular for robot welding tongs with a housing (18); with a holding piece (19); that is affixed inside the housing (18) and insulated against the housing (18) by means of a first insulating ring (2); that has a reception space (22) with a base wall (23) and an affixing appliance (24); and with a load cell (17) that is affixed inside the housing (18) opposite the base wall (23) and that is insulated against the housing (18) by means of a circumferential second insulating ring (5) and an insulating washer appliance (7, 21) located at the front-face side and adjacent to the base wall (23).

The disclosure relates to a measuring device (1) for automated welding devices, in particular for robot welding tongs with a housing (18); with a holding piece (19); that is affixed inside the housing (18) and insulated against the housing (18) by means of a first insulating ring (2); that has a reception space (22) with a base wall (23) and an affixing appliance (24); and with a load cell (17) that is affixed inside the housing (18) opposite the base wall (23) and that is insulated against the housing (18) by means of a circumferential second insulating ring (5) and an insulating washer appliance (7, 21) located at the front-face side and adjacent to the base wall (23).

A welding gun is incorporated into a unidirectional welding system, where the unidirectional welding system includes: the welding gun performing welding when a set pressing force is applied; a power portion configured to generate power to be applied to the welding gun; a power connecting portion having one end portion connected to the power portion through a power wire and an opposite end portion engaged with the welding gun; and a power switch provided at the power connecting portion to selectively apply the power generated from the power portion to the welding gun.

A joining machine to join work-pieces together comprises a body, at least one scanner disposed on the body and configured to collect data on the work-pieces and convert the data to a scanned image, a guide device and a positioning device. The positioning device is configured to determine a join position according to the scanned image and instruct the guide device to indicate the join position on the work-pieces to an operator of the machine.