An example head-worn device includes a camera, a display device, weld detection circuitry, and pixel data processing circuitry. The camera generates first pixel data from a field of view of the head-worn device. The display device displays second pixel data to a wearer of the head-worn device based on the first pixel data captured by the camera. The weld detection circuitry determines whether a welding arc is present and generates a control signal indicating a result of the determination. The pixel data processing circuitry processes the first pixel data captured by the camera to generate the second pixel data for display on the display device, where a mode of operation of said pixel data processing circuitry is selected from a plurality of modes based on said control signal.

Described herein are examples of smart helmet modules that can be affixed to conventional welding helmets. In some examples, a smart helmet module may include one or more sensors configured to detect if/when welding is occurring, and/or whether a welding helmet is being worn in an up or down position, or not at all. In some examples, a smart helmet module may include one or more helmet devices configured to automatically activate or deactivate based on whether welding is taking place and/or the welding helmet is being worn up, down, or not at all.

A welding system includes power supply configured to provide a welding power output. The welding system also includes a welding helmet having an electronic display and an inertial measurement unit. The electronic display is configured to display a representation of the power supply and to display one or more indications of one or more parameters of the power supply. The inertial measurement unit is configured to detect movement of the welding helmet. The welding system also includes a processing system communicatively coupled to the inertial measurement unit and configured to adjust at least one parameter of the one or more parameters based at least in part on the movement of welding helmet.

A welding system includes power supply configured to provide a welding power output. The welding system also includes a welding helmet having an electronic display and an inertial measurement unit. The electronic display is configured to display a representation of the power supply and to display one or more indications of one or more parameters of the power supply. The inertial measurement unit is configured to detect movement of the welding helmet. The welding system also includes a processing system communicatively coupled to the inertial measurement unit and configured to adjust at least one parameter of the one or more parameters based at least in part on the movement of welding helmet.

A system is disclosed for attaching a bump cap to a welding headgear. The system includes a bump cap, and an attachment member. The attachment member is configured to attach the bump cap to a welding headgear.

A system is disclosed for attaching a bump cap to a welding headgear. The system includes a bump cap, and an attachment member. The attachment member is configured to attach the bump cap to a welding headgear.

A system to support communication and control in a welding environment is disclosed. In one embodiment the system includes an internet-of-things (IoT) technology platform configured to provide scalable, interoperable, and secure communication connections between a plurality of disparate devices within a welding environment. The system also includes a welding power source configured to communicate with the IoT technology platform. The system further includes a computerized eyewear device. The computerized eyewear device includes a control and communication circuitry configured to communicate with the welding power source via the IoT technology platform. The computerized eyewear device also includes a transparent display configured to display information received from the welding power source via the IoT technology platform while allowing a user to view a surrounding portion of the welding environment through the transparent display.

A system to support communication and control in a welding environment is disclosed. In one embodiment the system includes an internet-of-things (IoT) technology platform configured to provide scalable, interoperable, and secure communication connections between a plurality of disparate devices within a welding environment. The system also includes a welding power source configured to communicate with the IoT technology platform. The system further includes a computerized eyewear device. The computerized eyewear device includes a control and communication circuitry configured to communicate with the welding power source via the IoT technology platform. The computerized eyewear device also includes a transparent display configured to display information received from the welding power source via the IoT technology platform while allowing a user to view a surrounding portion of the welding environment through the transparent display.

The present application relates to a welding helmet comprising: a helmet housing; a headband structure for securing the helmet housing; a HUD-type auto-darkening filter secured in the helmet housing; and a light-permeable protective sheet installed in front of the HUD-type auto-darkening filter in the helmet housing, wherein the HUD-type auto-darkening filter comprises a head-up display which is used to reveal operating parameters of the auto-darkening filter, and the head-up display is arranged between a body of the auto-darkening filter and the protective sheet such that when the auto-darkening filter is in a transparent state the luminously revealed operating parameter of the auto-darkening filter can be imaged via the protective sheet into the eyes of an operator who wears the welding helmet.

The present application relates to a welding helmet comprising: a helmet housing; a headband structure for securing the helmet housing; a HUD-type auto-darkening filter secured in the helmet housing; and a light-permeable protective sheet installed in front of the HUD-type auto-darkening filter in the helmet housing, wherein the HUD-type auto-darkening filter comprises a head-up display which is used to reveal operating parameters of the auto-darkening filter, and the head-up display is arranged between a body of the auto-darkening filter and the protective sheet such that when the auto-darkening filter is in a transparent state the luminously revealed operating parameter of the auto-darkening filter can be imaged via the protective sheet into the eyes of an operator who wears the welding helmet.