Apparatus and methods are provided for a welding-type power system that includes an engine configured to drive an electric generator to provide power to a power output, wherein a power signal is applied to the power output. A sensor monitors the power signal, and a controller determines a change in the power signal based on a feedback signal received from the sensor, and controls the engine to start or stop operation in response to the change in the power signal.

Systems and methods for remote control of a weld schedule of a welding power supply are disclosed. In some examples, a remote device is provided for monitoring or controlling the welding power supply, which controls and delivers power to one or more welding tools (e.g., a welding torch) and/or accessories (e.g., a wire feeder). The remote device includes a user interface to receive one or more inputs, which are provided to a control circuitry configured to transmit signals to or receive signals from the welding power supply via a remote transceiver. In some examples, the signals include data corresponding to one or more weld schedules.

The invention described herein generally pertains to a welder system that includes one or more welding power sources, an input device having a display and an imaging device, and a fabrication computer device. The fabrication computing device includes a processor configured to execute computer-executable instructions that configure the fabrication computing device to receive an informational input from the input device. The informational input is based at least in part on an image captured by the imaging device of the input device, and the informational input is indicative of one or more of a weld procedure, an operator identifier, a welding power source identifier, a part identifier, or an operation status. The fabrication computing device is further configured to control operation of at least one welding power source of the one or more welding power sources based on the informational input received.

Systems and methods for controlling an engine driven power system and/or a welding system from two or more control sources are disclosed. In some examples, multiple control devices or sources are in communication with a central control circuitry of the engine driven power system, and/or a welding system which is capable of managing commands from multiple control sources by prioritizing commands and/or limited the scope of control. In some examples, the central control circuitry controls the multiple control sources to update systems and displays to harmonize commands and/or data that originated at another source.

Embodiments of a the present disclosure include a remote control system for a welding system having a control device and control circuitry configured to select a first operating parameter adjustment for a first operating parameter of the welding system based on a first actuation of the control device, wherein the first operating parameter adjustment comprises an adjustment to a rate of change of the first operating parameter.

A welding machine includes one or more processors configured to control the welding machine and remote reset circuitry communicatively coupled to the one or more processors. The remote reset circuitry is configured to receive a remote signal and to reset the one or more processors based at least in part on the remote signal.

Sensor assisted head mounted displays for welding are disclosed. Disclosed example head mounted devices include an optical sensor, an augmented reality controller, a graphics processing unit, and a semi-transparent display. The optical sensor collects an image of a weld environment. The augmented reality controller determines a simulated object to be presented in a field of view, a position in the field of view, and a perspective of the simulated object in the field of view. The graphics processing unit renders the simulated object based on the perspective to represent the simulated object being present in the field of view and in the weld environment. The display presents the rendered simulated object within the field of view based on the position. At least a portion of the weld environment is observable through the display and the lens when the display is presenting the rendered simulated object.

Embodiments of systems and methods for remotely controlling a robotic welding system over a long distance in real time are disclosed. One embodiment is a method that includes tracking movements and control of a mock welding tool operated by a human welder at a local site and generating control parameters corresponding to the movements and control. The control parameters are transmitted from the local site to a robotic welding system at a remote welding site over an ultra-low-latency communication network. The round-trip communication latency over the ultra-low-latency communication network is between 0.5 milliseconds and 20 milliseconds, and a distance between the local site and the remote welding site is at least 50 kilometers. An actual welding operation of the robotic welding system is controlled to form a weld at the remote welding site via remote robotic control of the robotic welding system in response to the control parameters.

A system for aiding a user in at least one of welding, cutting, joining, and cladding operations is provided. The system includes a welding tool and a welding helmet with a face-mounted display. The system also includes a spatial tracker configured to track the welding helmet and the welding tool in 3-D space relative to an object to be worked on. A processor based subsystem is configured to generate visual cues based on information from the spatial tracker and transmit the visual cues to a predetermined location on the face-mounted display.

An inductive sensor which includes one or more inductive coils and an inductance to digital converter. The output of the inductive sensor may be used to replace the functions of a switch and a potentiometer to initiate and control various outputs in welding-type systems and applications.