Systems and methods are provided for supporting a head of a user, e.g., while the user inclines their head downward, leans forward, and the like, for extended periods of time. In an exemplary embodiment, a harness is provided that is configured to be worn on a body of a user, the harness including a shoulder harness configured to be worn over or around one or both shoulders of the user, and a head support. The head support may include a support bracket including a first end mounted to the harness, and a rest member coupled to a second end of the support bracket such that the rest member extends across a forehead of the user and/or at least partially around the user's head when the harness is worn for supporting the user's forehead.

In some examples, a system includes: a plurality of different articles of personal protection equipment (PPE) that are all controlled by a particular user, and a computing device. The computing device may include one or more computer processors configured to receive sets of data from each of the different articles of PPE, wherein each set of data is based at least in part on a type of each of the different articles of PPE; generate for display a user interface that contemporaneously includes a plurality of graphical elements that are based at least in part on at least two sets of data that correspond to at least two different articles of PPE of the plurality of different articles of PPE; and in response to receiving an indication of user input that corresponds to at least one of the plurality of graphical elements, perform at least one operation.

The present application discloses a wireless projector-type auto-darkening welding helmet comprising: a helmet housing; a headband structure for securing the helmet housing; an auto-darkening filter secured on the helmet housing; a wireless communication module; and a micro-projector which is data-connected to the auto-darkening filter and the wireless communication module, wherein when the auto-darkening filter is in a transparent state, the micro-projector is adaptable to project operating parameters of the auto-darkening filter and/or data received by the wireless communication module, as images, onto a plane in front of the welding helmet such that they can be watched by an operator who wears the welding helmet on his/her head. The present application also discloses a welding apparatus equipped with said wireless projector-type auto-darkening welding helmet.

The present application discloses a wireless projector-type auto-darkening welding helmet comprising: a helmet housing; a headband structure for securing the helmet housing; an auto-darkening filter secured on the helmet housing; a wireless communication module; and a micro-projector which is data-connected to the auto-darkening filter and the wireless communication module, wherein when the auto-darkening filter is in a transparent state, the micro-projector is adaptable to project operating parameters of the auto-darkening filter and/or data received by the wireless communication module, as images, onto a plane in front of the welding helmet such that they can be watched by an operator who wears the welding helmet on his/her head. The present application also discloses a welding apparatus equipped with said wireless projector-type auto-darkening welding helmet.

The present application relates to a welding helmet comprising a helmet housing and a head cover adapted to be worn on a wearer's head and made of an air-impermeable and flexible material, wherein a zipper arrangement is provided between the helmet housing and the head cover to detachably connect the head cover to the helmet housing around the whole perimeter of an opening of the helmet housing, and wherein after the head cover is connected to the helmet housing, the zipper arrangement is located within the housing of the welding helmet. The present application also relates to an assembly having the welding helmet.

The present application relates to a welding helmet comprising a helmet housing and a head cover adapted to be worn on a wearer's head and made of an air-impermeable and flexible material, wherein a zipper arrangement is provided between the helmet housing and the head cover to detachably connect the head cover to the helmet housing around the whole perimeter of an opening of the helmet housing, and wherein after the head cover is connected to the helmet housing, the zipper arrangement is located within the housing of the welding helmet. The present application also relates to an assembly having the welding helmet.

Dynamic range enhancement methods and systems for display for use welding applications are described. A display system in a dynamic range enhancement system can include, for example, a splitter, a high density filter, a low density filter, a first image sensor, a second image sensor, a graphical circuit, and a display. The high density filter and the first image sensor can be disposed in a first path. The low density filter and the second image sensor can be disposed in a second path. The first image sensor can receive filtered electromagnetic waves from the high density filter. The second image sensor can receive filtered electromagnetic waves from the low density filter. The graphic circuit can combine the signals from the first image sensor and the second image sensor to provide a high dynamic range image or video that is displayed on the display of a welding helmet, for example.

Dynamic range enhancement methods and systems for display for use welding applications are described. A display system in a dynamic range enhancement system can include, for example, a splitter, a high density filter, a low density filter, a first image sensor, a second image sensor, a graphical circuit, and a display. The high density filter and the first image sensor can be disposed in a first path. The low density filter and the second image sensor can be disposed in a second path. The first image sensor can receive filtered electromagnetic waves from the high density filter. The second image sensor can receive filtered electromagnetic waves from the low density filter. The graphic circuit can combine the signals from the first image sensor and the second image sensor to provide a high dynamic range image or video that is displayed on the display of a welding helmet, for example.

A safety garment includes at least one sensor unit for detecting at least one user-specific characteristic value and/or at least one environment-specific characteristic value. The safety garment further includes at least one communication unit configured to transmit the detected user-specific characteristic value and/or the detected environment-specific characteristic value to at least one other safety garment in order to communicate with the other safety garment.

A safety garment includes at least one sensor unit for detecting at least one user-specific characteristic value and/or at least one environment-specific characteristic value. The safety garment further includes at least one communication unit configured to transmit the detected user-specific characteristic value and/or the detected environment-specific characteristic value to at least one other safety garment in order to communicate with the other safety garment.