A welding system is provided. The welding system includes a low power transceiver configured to be coupled to a weld cable. The low power transceiver includes a low power transmitter, a low power receiver, and a first processor. The low power receiver is configured to transmit one or more unmodulated tones through the weld cable to a welding power supply. The low power receiver is configured to receive the one or more unmodulated tones through the weld cable from the welding power supply. The first processor is configured to determine one or more channel equalization filter coefficients related to the weld cable corresponding to a distortive characteristic of the weld cable.

Provided is an electric arc generation system comprising a robot, an electric arc torch attached to the robot, a power supply configured to provide an electrical power output to the torch, and a user interface for adjusting a plurality of power supply parameters. The user interface comprises a display. The system includes a processor configured to receive respective settings of the plurality of power supply parameters, and configured to analyze the settings of the plurality of power supply parameters and control the display to display a pictograph warning associated with a current parameter setting, based on a result of analyzing the settings of the plurality of power supply parameters. Said pictograph warning graphically indicates an adjustment direction for the current parameter setting. The processor is configured to automatically adjust one or more of the settings of the plurality of power supply parameters based on a predetermined operating angle of the torch.

Methods and apparatus to communicate via a weld cable are disclosed. An example welding-type power supply includes a power converter, a receiver circuit, and a controller. The power converter converts input power to welding-type power based on a weld voltage setpoint and to output the welding-type power via a weld circuit. The receiver circuit receives a communication via the weld circuit while current is flowing through the weld circuit or after the current has stopped flowing through the weld circuit. The communication includes weld voltage feedback information measured at a device remote from the power supply while the current is flowing through the weld circuit. The controller controls the welding-type power output by the power converter according to a voltage feedback loop using the weld voltage feedback information to regulate a weld voltage at the remote device to the weld voltage setpoint.

An example welding user interface system includes: a user interface configured to receive a plurality of control inputs indicative of a plurality of weld specifications, wherein the plurality of weld specifications comprise two or more physical attributes of a weld, the physical attributes comprising two or more of a workpiece thickness, a joint type, a workpiece material, a fillet size, a penetration depth, a penetration profile, a bead width, a wire type, a wire feed speed, or a gas type; and a processor configured to convert the weld specifications from the plurality of control inputs into electrical parameters of a welding power source, and to control an output welding power of the welding power source based at least in part on the electrical parameters.

The present invention provides a unique and novel, low-cost external assembly that can be used to add a pulsed current functionality to a continuous welding machine. The external assembly is located in series between a pedal for controlling the welder and the welder itself. The external assembly includes a controller that modifies the pedal input signal typically entering directly into the welder. The modified signal converts the continuous welding machine such that it operates as a pulsed welding machine.

The present invention is directed to a system and method of remotely controlling a welding machine with command signals transmitted to the welding power source across a weld cable connecting the power source to a remote device, such a wire feeder. A transmitter transmits the control commands containing desired welding operational parameters to a receiver disposed in the power source across a weld cable also designed to carry welding power from the power source to the wire feeder.

A welding system includes a welding power source having a user interface disposed thereon and a weld controller disposed therein and being adapted to generate a welding power output for use in a welding operation. The welding system also includes a personal computer having control circuitry disposed therein and being removably interfaced with the welding power source via a docking mechanism. When the personal computer is docked within the docking mechanism, the personal computer is enabled for receiving operator input, and the control circuitry communicates with the weld controller to coordinate control of a welding operation in accordance with the operator input.

Engine-driven welding-type power supplies with portable welding units are disclosed. An example engine driven welder includes an engine, a generator configured to convert mechanical power from the engine to electric power, a chassis, the engine and the generator being mounted to the chassis, and a welding power supply configured to receive the electric power from the generator and convert the electric power to welding-type power, wherein the chassis is configured to physically hold the welding power supply, the welding power supply is physically separable from the chassis, and the welding power supply is connected to be able to receive the electric power when the welding power supply is separated from the chassis and when the welding power supply is connected to the chassis.

A device and method for welding a welding stud to a base is provided. A welding current is applied to a welding stud between the welding stud and the base material, wherein a material of the welding stud and the base material is partially liquefied. The welding stud is then immersed into the solidifying material of the welding stud or the base material in order to create a bond between the welding stud and the base material.

Systems are disclosed relating to a mobile device mounted to a welding helmet such that a wearer of the welding helmet can see a display of the mobile device when wearing the welding helmet. In some examples, the mobile device is mounted such that a camera of the mobile device is unobscured and positioned at approximately eye level, facing the same way the wearer's eyes are facing. In some examples, the simulated training environment may be presented to the user via the display screen of the mobile device, using images captured by the camera of the mobile device, when the mobile device is so mounted to the welding helmet.