A smart welding system and smart welding process which integrates technology to increase performance and safety in welding operations.

A protective cover for a remote device for welding equipment is provided. In some examples, the protective cover is configured as a fitted and sacrificial protective cover configured to prevent damage to the remote device from byproducts of a welding process.

Systems and methods for monitoring and/or controlling a welding system using a remote device are disclosed. The remote device communicates, via one or more transceivers or communication circuits, with one or more component of the welding system (such as a welding power supply or auxiliary device) or a remote computing system (such as a personal computer, cloud computing resource, etc.). The remote device receives signals from the welding system, the signals containing data associated with diagnostic parameters of one or more of the components. The remote device then controls one or more transceivers to transmit signals containing the data to the remote computing system. There, the data may be analyzed, manipulated, and/or displayed. In some examples, software update data is provided to the remote device and transmitted to a welding system component associated with the particular software update.

A welding device for remotely controlling welding power supply settings is provided. One embodiment of the welding device includes a welding pendant having a control panel configured to control a plurality of settings of a welding power supply. The control panel is not part of the welding power supply and the plurality of settings includes a welding current output by the welding power supply. The welding pendant also includes a welding power input configured to receive welding power and data from the welding power supply via a welding power cable. The welding power is combined with the data such that the data is provided over the welding power cable.

A voltage sensing wire feeder includes a storage device and a user interface. The user interface is configured to receive a first selection and a second selection. The first selection is configured to direct the voltage sensing wire feeder to use a first group of settings stored in the storage device, and the second selection is configured to direct the voltage sensing wire feeder to use a second group of settings stored in the storage device.

An example welding type system includes: a welding power circuit having a control input and a welding type power output; a feedback circuit configured to provide feedback regarding the welding type power output or a weld produced using the welding type power output; and a controller connected to the feedback circuit, wherein the controller includes a parameter setting module and a process selection module, the process selection module configured to automatically select a welding process from a plurality of welding processes based on the feedback from the feedback circuit or one or more welding parameters set by the parameter setting module.

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.

Apparatus for allowing a welder to control the output power of a welding machine, and thus its arc power by applying force to a surface of a force sensing transducer assembly. The force sensing transducer assembly generates a force signal based upon the force applied, for example by reducing the resistance within the force sensing transducer assembly. A control interface module then receives the force signal and controls the welding machine power output based upon the force signal. The welder may set the range of force to change the arc power by setting a minimum amount of force to actuate the welding machine and a maximum force that increases the output power of the welding machine (force below the minimum does not actuate the welding machine and force above the maximum does not increase the welding machine power above a certain level).

Portable, wearable or integrate-able devices may be used in detecting gestures or motions by operators of welding systems, and performing actions based thereon. The detection may be performed using sensors (e.g., MEMS or muscle sensors), which generate sensory data. The detected gestures or motions may be processed and translated into corresponding actions or commands, which may be handled directly or communicated to other devices in the welding systems. The actions or commands may comprise welding actions/commands, which are configured for controlling a particular component used during welding operations, and/or gesture-related actions/commands, which are configured for controlling gesture-related components and/or operations. Feedback is provided to the operator, such as to acknowledge or validate detection of the gestures, to identify the corresponding action or command, and to complete the identified action or command. The feedback may be non-visual feedback, such as haptic or audio feedback.

Systems and methods are provided for indicating schedules in welding-type torches. A welding-type system may comprise a welding-type power source, a welding-type torch, driven by the welding-type power source, and a welding-type connector configured for connecting the welding-type power source to the welding-type torch. The welding-type torch may comprise one or more indication components configured for providing, to a user of the welding-type system, indications relating to at least one of operations of the welding-type torch, status of welding-type operations, or welding-type parameters. The one or more indications comprise an indication of a present value of a particular welding-type parameter that pertains to configuration of the welding-type power source; and the one or more indication components are configured to provide the indication of present value of the particular welding-type parameter without requiring a change to structure of the welding-type connector.