A welding apparatus includes a module for prompting a user to input a command indicating that a welding pressure between a movable electrode tip and a fixed electrode tip has reached each of two welding pressures, a module for identifying a torque exerted in the servo motor and a movement amount of the movable electrode tip at a point in time when the command is input, a module for deriving a relational expression between the welding pressure and the movement amount, a module for using the relational expression to estimate a movement amount of the movable electrode tip required to generate another welding pressure, and a module for identifying a torque required for the movable electrode tip to move the estimated movement amount, and registering the torque in association with the another welding pressure.

According to the present invention, a plurality of actual spots where normal directions of welding surfaces are parallel to each other and arranged successively, are set as a spot group. Then, when the actual spots included in the spot group are collectively moved in the same direction by the same distance, a search is conducted of candidates for the directions and the distances that cause the actual spots having been moved to approach welding points. Further, optimum direction and distance are selected from among the candidates for the directions and distances, and a plurality of teaching points corresponding to the plurality of actual spots included in the spot group are corrected by using the selected direction and distance.

A spot welding system 10 includes a spot welding gun having an opposite electrode 44, a movable electrode 48, and a drive part 52, a position detection part 54 that detects a position of the movable electrode 48, and a pressure change calculation part that calculates an amount of change between first pressurizing force at a first attitude and second pressurizing force at a second attitude based on a first position of the movable electrode 48 when the drive part 52 has been driven by a first pressurizing force command at the first attitude, a second position of the movable electrode 48 when the drive part 52 has been driven by the first pressurizing force command at the second attitude, and the first pressurizing force command. The first pressurizing force command and the first pressurizing force coincide with each other.

An apparatus includes a housing, a lever, a plurality of gears and a sensor. The housing may be configured to receive a weld head. The lever may be rotatably attached to the housing and configured to convert a linear position of a free end of the lever relative to the housing into a first angular position of a first shaft relative to the housing. The gears may be configured to transform the first angular position of the first shaft to a second angular position of a second shaft. The sensor may be coupled to the second shaft and configured to generate a value representative of the linear position of the free end of the lever by a measurement of the second angular position of the second shaft.

An all-in-one jigless projection loading system for a vehicle is adapted to load and assemble a body component to a vehicle body. The all-in-one jigless projection loading system may include: a fixing bracket fixed to an arm of a robot; a position adjusting member rotatably mounted to the fixing bracket; a gripper mounted to the fixing bracket to be movable backward and forward, and gripping the body component; an array unit mounted to the position adjusting member, and arraying the body component; and a welding unit mounted to the fixing bracket, and projection-welding the body component to a vehicle body.

A resistance spot welding device for welding at least two overlapping steel sheets held between a pair of welding electrodes is provided. The resistance spot welding device includes the pair of electrodes, an electrode force gauge that measures an electrode force, and a controller that controls an electric current supply to the electrodes according to the electrode force measured by the electrode force gauge. The controller controls the electric current such that the electrode force F measured by the electrode force gauge after the start of the electric current supply is adjusted to a prescribed value.

The present disclosure relates to a method for controlling a spot welding arrangement, the method comprising the steps of moving a welding tip portion of the spot welding arrangement between a first and a second position by applying a force to the welding tip portion; determining a distance moved between the first and second positions; determining a type of welding yoke connected to the spot welding arrangement based on the determined distance and the applied force; and controlling settings of the spot welding arrangement based on the welding yoke connected to the spot welding arrangement.

A spatter detection method for accurately determining whether or not spatter has been generated when resistance spot welding is performed is provided. A spatter detection method including: a welding step for welding a plurality of welding materials by sandwiching parts to be welded of the welding materials between a pair of electrodes and then pressurizing the parts to be welded while simultaneously energizing the pair of electrodes; a calculation step for calculating an amount of expansion of the parts to be welded based on a pressurizing force and a stroke between the pair of electrodes; and a determination step for determining that the spatter has been generated when a magnitude of an inclination of an expansion amount waveform falls below a determination threshold, in which in the determination step, determination thresholds different from each other are applied to respective sections obtained by dividing a target period of the determination.

A welding training system includes a welding surface, a computer configured to execute a welding training software, and a calibration device. The welding training system also includes a sensor communicatively coupled to the computer and configured to sense a position of the calibration device, an orientation of the calibration device, or some combination thereof. The sensor is also configured to provide calibration data to the welding training software to calibrate a location of the welding surface relative to the sensor. The calibration data includes the position of the calibration device, the orientation of the calibration device, or some combination thereof.

A spot welding system comprises a robot which changes a relative position of a spot welding gun and a workpiece. A control device drives an electrode drive motor so that a movable electrode of the spot welding gun abuts on the workpiece, and is formed so as to perform a position detection control which detects a position of the workpiece based on a position of the movable electrode when a state value of the electrode drive motor deviates from a predetermined range. An operation program includes a workpiece detection parameter for performing the position detection control. The workpiece detection parameter is set at each of welding points in the operation program.