A frame is described for positioning a battery using a vision system to determine at least one weld point on the battery. The frame includes at least one visual reference feature detectable by the vision system. The reference feature is used by the vision system to determine the weld point(s). For example, the at least one visual reference feature includes a pair of stubs that define a line, and the at least one weld point is determined based on the line. In a further example, the pair of stubs correspond to respective batteries, which are arranged adjacent to one another within the frame. In a further example, respective centers of the stubs are lined up along a center line extending from respective centers of respective end faces of the respective batteries. The vision system includes vision circuitry, processing circuitry coupled to the vision circuitry, and a weld system.

A frame is described for positioning a battery using a vision system to determine at least one weld point on the battery. The frame includes at least one visual reference feature detectable by the vision system. The reference feature is used by the vision system to determine the weld point(s). For example, the at least one visual reference feature includes a pair of stubs that define a line, and the at least one weld point is determined based on the line. In a further example, the pair of stubs correspond to respective batteries, which are arranged adjacent to one another within the frame. In a further example, respective centers of the stubs are lined up along a center line extending from respective centers of respective end faces of the respective batteries. The vision system includes vision circuitry, processing circuitry coupled to the vision circuitry, and a weld system.

A welding system includes a welder, a human-machine-interface, an identification-device, a test-device, a memory, and a controller-circuit. The welder creates an assembly between electrical-components. The human-machine-interface receives an input from an operator and displays instructions to the operator. The identification-device creates a label identifying the assembly. The test-device produces test-data of the weld-joint. The memory stores welder-process-data of the weld-joint. The controller-circuit activates the welder, stores the welder-process-data in the memory, determines whether the welder-process-data violates a quality-metric, determines a number of violating-weld-joints, activates an alert-device to alert the operator to violating-weld-joints, disables the welder when a number of violating-weld-joints exceeds a threshold, activates the identification-device to create the label, instructs the operator to attach the label to the assembly having the violating-weld-joints, instructs the operator to perform a test of the violating-weld-joints with the test-device, and stores the test-data of the violating-weld-joints in the memory linked to the identity.

A welding system includes a welder, a human-machine-interface, an identification-device, a test-device, a memory, and a controller-circuit. The welder creates an assembly between electrical-components. The human-machine-interface receives an input from an operator and displays instructions to the operator. The identification-device creates a label identifying the assembly. The test-device produces test-data of the weld-joint. The memory stores welder-process-data of the weld-joint. The controller-circuit activates the welder, stores the welder-process-data in the memory, determines whether the welder-process-data violates a quality-metric, determines a number of violating-weld-joints, activates an alert-device to alert the operator to violating-weld-joints, disables the welder when a number of violating-weld-joints exceeds a threshold, activates the identification-device to create the label, instructs the operator to attach the label to the assembly having the violating-weld-joints, instructs the operator to perform a test of the violating-weld-joints with the test-device, and stores the test-data of the violating-weld-joints in the memory linked to the identity.

A welding system includes a welder, a human-machine-interface, an identification-device, a test-device, a memory, and a controller-circuit. The welder creates an assembly between electrical-components. The human-machine-interface receives an input from an operator and displays instructions to the operator. The identification-device creates a label identifying the assembly. The test-device produces test-data of the weld-joint. The memory stores welder-process-data of the weld-joint. The controller-circuit activates the welder, stores the welder-process-data in the memory, determines whether the welder-process-data violates a quality-metric, determines a number of violating-weld-joints, activates an alert-device to alert the operator to violating-weld-joints, disables the welder when a number of violating-weld-joints exceeds a threshold, activates the identification-device to create the label, instructs the operator to attach the label to the assembly having the violating-weld-joints, instructs the operator to perform a test of the violating-weld-joints with the test-device, and stores the test-data of the violating-weld-joints in the memory linked to the identity.

A welding system includes a welder, a human-machine-interface, an identification-device, a test-device, a memory, and a controller-circuit. The welder creates an assembly between electrical-components. The human-machine-interface receives an input from an operator and displays instructions to the operator. The identification-device creates a label identifying the assembly. The test-device produces test-data of the weld-joint. The memory stores welder-process-data of the weld-joint. The controller-circuit activates the welder, stores the welder-process-data in the memory, determines whether the welder-process-data violates a quality-metric, determines a number of violating-weld-joints, activates an alert-device to alert the operator to violating-weld-joints, disables the welder when a number of violating-weld-joints exceeds a threshold, activates the identification-device to create the label, instructs the operator to attach the label to the assembly having the violating-weld-joints, instructs the operator to perform a test of the violating-weld-joints with the test-device, and stores the test-data of the violating-weld-joints in the memory linked to the identity.

A chassis welding device for welding brackets as standard members to a body of a chassis includes a frame, a first transferring member, a plurality of loading mechanisms, a plurality of carriers, a conveying member, a shifting member, and a spot welder. The loading mechanism transfers standard members to individual preset positions on the carrier to face the solder joints on the standard members away from the carrier. The first transferring member transports the carrier to the shifting member. The shifting member transfers the carrier from the first transferring member to the spot welder. The conveying member transfers the body into contact with the solder joints. The spot welder applies heat to melt the solder joints to bond the standard members to the body.

A different material welded joint in which a first member made of a first material and a second member made of a second material having a melting point lower than that of the first material are joined to each other by welded parts at a plurality of welding sections, wherein the first member has a plurality of through-holes respectively corresponding to the plurality of welding sections and a filler material made of the second material is filled in the plurality of through-holes, and wherein apexes of welding beads of the welded parts, which are deposited and formed on a surface of the second member facing the through-holes, are formed independently of each other at each of the welding sections.

A different material welded joint in which a first member made of a first material and a second member made of a second material having a melting point lower than that of the first material are joined to each other by welded parts at a plurality of welding sections, wherein the first member has a plurality of through-holes respectively corresponding to the plurality of welding sections and a filler material made of the second material is filled in the plurality of through-holes, and wherein apexes of welding beads of the welded parts, which are deposited and formed on a surface of the second member facing the through-holes, are formed independently of each other at each of the welding sections.

In the present invention, a flat emitter is formed from emitter material preforms shaped as thin sheets of the emitter material. These sheets are subjected to various levels and/or amounts of mechanical working during their initial formation and are bonded to one another to create a preform having the desired thickness. The preform including the bonded sheets is subsequently worked to shape the preform into the desired configuration for the emitter. The working of the sheets of emitter material utilized to create the preform and the working of the preform to form the emitter provide a highly creep-resistant emitter that significantly improves the operation and useful life of the resulting emitter.