Abstract: Embodiments of the invention comprise a garment; a first design comprising fluorescent material placed on the garment, wherein the first design is externally visible when the garment is worn by a wearer; a second design comprising reflective material overlaid on the first design to create a resulting design, wherein the resulting design provides 360 degree external visibility of the wearer when the garment is worn by the wearer; and wherein the resulting design is an artistic expression. Other embodiments comprise the steps of: creating a design, wherein the design is an artistic expression and comprises a first partial design and a second partial design; transferring the first partial design to a garment comprised of clothing fabric using a fluorescent material; and transferring the second partial design to the garment using a reflective material, wherein all the materials cause a wearer of the garment to have 360 degree external visibility.

Abstract: Systems and methods are provided for support of low-power operation in training modes in welding machines.

Abstract: Embodiments of the invention comprise a garment; a first design comprising fluorescent material placed on the garment, wherein the first design is externally visible when the garment is worn by a wearer; a second design comprising reflective material overlaid on the first design to create a resulting design, wherein the resulting design provides 360 degree external visibility of the wearer when the garment is worn by the wearer; and wherein the resulting design is an artistic expression. Other embodiments comprise the steps of: creating a design, wherein the design is an artistic expression and comprises a first partial design and a second partial design; transferring the first partial design to a garment comprised of clothing fabric using a fluorescent material; and transferring the second partial design to the garment using a reflective material, wherein all the materials cause a wearer of the garment to have 360 degree external visibility.

Abstract: Embodiments of the invention comprise a garment; a first design comprising fluorescent material placed on the garment, wherein the first design is externally visible when the garment is worn by a wearer; a second design comprising reflective material overlaid on the first design to create a resulting design, wherein the resulting design provides 360 degree external visibility of the wearer when the garment is worn by the wearer; and wherein the resulting design is an artistic expression. Other embodiments comprise the steps of: creating a design, wherein the design is an artistic expression and comprises a first partial design and a second partial design; transferring the first partial design to a garment comprised of clothing fabric using a fluorescent material; and transferring the second partial design to the garment using a reflective material, wherein all the materials cause a wearer of the garment to have 360 degree external visibility.

Abstract: Embodiments of the invention comprise a garment; a first design comprising fluorescent material placed on the garment, wherein the first design is externally visible when the garment is worn by a wearer; a second design comprising reflective material overlaid on the first design to create a resulting design, wherein the resulting design provides 360 degree external visibility of the wearer when the garment is worn by the wearer; and wherein the resulting design is an artistic expression. Other embodiments comprise the steps of: creating a design, wherein the design is an artistic expression and comprises a first partial design and a second partial design; transferring the first partial design to a garment comprised of clothing fabric using a fluorescent material; and transferring the second partial design to the garment using a reflective material, wherein all the materials cause a wearer of the garment to have 360 degree external visibility.

Abstract: A safety garment includes a fluorescent material that forms at least a torso of the safety garment; a first design on the fluorescent material; a first reflective material band that at least partially overlays the first design, the first reflective material band encircles the torso; a second reflective material band that extends from the first reflective material band on a front of the safety garment to the first reflective material band on a back of the safety garment, wherein the second reflective material band extends over a first shoulder of the safety garment; and a third reflective material band that extends from the first reflective material band on the front of the safety garment to the first reflective material band on the back of the safety garment, wherein the third reflective material band extends over a second shoulder of the safety garment.

Abstract: Embodiments of the invention include a garment; a first design including fluorescent material placed on the garment, wherein the first design is externally visible when the garment is worn by a wearer; a second design including reflective material overlaid on the first design to create a resulting design, wherein the resulting design provides 360 degree external visibility of the wearer when the garment is worn by the wearer; and wherein the resulting design is an artistic expression. Other embodiments include the steps of: creating a design, wherein the design is an artistic expression and includes a first partial design and a second partial design; transferring the first partial design to a garment included of clothing fabric using a fluorescent material; and transferring the second partial design to the garment using a reflective material, wherein all the materials cause a wearer of the garment to have 360 degree external visibility.

Abstract: Apparatus, systems, and/or methods for mitigating audible noise generated by a welding-type power supply are disclosed. In some examples, the switching frequency of the welding-type power supply may be changed to a frequency that is outside the audible range for humans. This strategy takes advantage of the fact that the observed audible noise is generated by vibrating components within the welding-type power supply that vibrate at a frequency related to the switching frequency. Other noise mitigation strategies include dithering and deactivation of portions of the welding-type power supply that vibrate to generate the audible noise.

Abstract: Disclosed example welding power systems and methods monitor supply power inputs from a primary power source. The supply power is compared to current and/or power threshold values corresponding to limits associated with the primary power source. If the supply power exceeds a threshold value associated with the limits, the welding power system controls welding parameters or devices to adjust a supply power demand, thereby ensuring the draw on supply power does not exceed the capabilities of the power source. In some examples, the disclosed welding power system presents a subset of welding parameters identified as available for operation based on the capabilities of the power source. The user interface displays only the subset of available welding parameters to an operator for selection, thereby ensuring the draw on supply power does not exceed the capabilities of the power source.

Abstract: Present embodiments include systems and methods for stick welding applications. In certain embodiments, simulation stick welding electrode holders may include stick electrode retraction assemblies configured to mechanically retract a simulation stick electrode toward the stick electrode retraction assembly to simulate consumption of the simulation stick electrode during a simulated stick welding process. In addition, in certain embodiments, stick welding electrode holders may include various input and output elements that enable, for example, control inputs to be input via the stick welding electrode holders, and operational statuses to be output via the stick welding electrode holders. Furthermore, in certain embodiments, a welding training system interface may be used to facilitate communication and cooperation of various stick welding electrode holders with a welding training system.

Abstract: Systems and methods are provided for support of low-power operation in training modes in welding machines.

Abstract: A portable rehabilitation assembly (100) for pre-gait rehabilitation comprises first and second lower support bars (102a, 102b) coupled together by an adjustable cross-member (104). A first pair of vertical frame members (108a) can be coupled to the first lower support bar (102a), and a second pair of vertical frame members (108b) can be coupled to the second lower support bar (102b). First and second hand rails (110a, 110b) can be coupled to respective vertical frame members (108a, 108b) to form an unobstructed walkway (W) from the front region (106a) to a back region (106b). First and second pairs of wheels (112a-d) can be coupled to respective lower support bars (102a, 102b). At least one actuation mechanism (114a, 114b) operates to move the assembly (100) from a stationary rehabilitation position to a portable position by causing the wheels (H2a-d) to lift the lower support bars (102a, 102b) from the ground surface for transport.

Abstract: Present embodiments include systems and methods for stick welding applications. In certain embodiments, simulation stick welding electrode holders may include stick electrode retraction assemblies configured to mechanically retract a simulation stick electrode toward the stick electrode retraction assembly to simulate consumption of the simulation stick electrode during a simulated stick welding process. In addition, in certain embodiments, stick welding electrode holders may include various input and output elements that enable, for example, control inputs to be input via the stick welding electrode holders, and operational statuses to be output via the stick welding electrode holders. Furthermore, in certain embodiments, a welding training system interface may be used to facilitate communication and cooperation of various stick welding electrode holders with a welding training system.

Abstract: Apparatus, systems, and/or methods for mitigating audible noise generated by a welding-type power supply are disclosed. In some examples, the switching frequency of the welding-type power supply may be changed to a frequency that is outside the audible range for humans. This strategy takes advantage of the fact that the observed audible noise is generated by vibrating components within the welding-type power supply that vibrate at a frequency related to the switching frequency. Other noise mitigation strategies include dithering and deactivation of portions of the welding-type power supply that vibrate to generate the audible noise.

Abstract: Present embodiments include systems and methods for stick welding applications. In certain embodiments, simulation stick welding electrode holders may include stick electrode retraction assemblies configured to mechanically retract a simulation stick electrode toward the stick electrode retraction assembly to simulate consumption of the simulation stick electrode during a simulated stick welding process. In addition, in certain embodiments, stick welding electrode holders may include various input and output elements that enable, for example, control inputs to be input via the stick welding electrode holders, and operational statuses to be output via the stick welding electrode holders. Furthermore, in certain embodiments, a welding training system interface may be used to facilitate communication and cooperation of various stick welding electrode holders with a welding training system.

Abstract: A method including determining an orientation of a display of a welding torch relative to a joint of a workpiece, displaying, on the display of the welding torch during a welding operation, a graphical representation of a welding parameter in relation to a predetermined threshold range for the welding parameter as a position of the welding torch changes, the orientation of the welding torch changes, a movement of the welding torch changes, or some combination thereof, and rotating the graphical representation of the welding parameter based at least in part on the determined orientation of the display of the welding torch relative to the joint. The graphical representation of the welding parameter is associated with the position of the welding torch relative to the joint, the orientation of the welding torch relative to the joint, the movement of the welding torch relative to the joint, or some combination thereof.

Abstract: Present embodiments include systems and methods for stick welding applications. In certain embodiments, simulation stick welding electrode holders may include stick electrode retraction assemblies configured to mechanically retract a simulation stick electrode toward the stick electrode retraction assembly to simulate consumption of the simulation stick electrode during a simulated stick welding process. In addition, in certain embodiments, stick welding electrode holders may include various input and output elements that enable, for example, control inputs to be input via the stick welding electrode holders, and operational statuses to be output via the stick welding electrode holders. Furthermore, in certain embodiments, a welding training system interface may be used to facilitate communication and cooperation of various stick welding electrode holders with a welding training system.

Abstract: Embodiments of the invention comprise a garment; a first design comprising fluorescent material placed on the garment, wherein the first design is externally visible when the garment is worn by a wearer; a second design comprising reflective material overlaid on the first design to create a resulting design, wherein the resulting design provides 360 degree external visibility of the wearer when the garment is worn by the wearer; and wherein the resulting design is an artistic expression. Other embodiments comprise the steps of: creating a design, wherein the design is an artistic expression and comprises a first partial design and a second partial design; transferring the first partial design to a garment comprised of clothing fabric using a fluorescent material; and transferring the second partial design to the garment using a reflective material, wherein all the materials cause a wearer of the garment to have 360 degree external visibility.

Abstract: A method including determining an orientation of a display of a welding torch relative to a joint of a workpiece, displaying, on the display of the welding torch during a welding operation, a graphical representation of a welding parameter in relation to a predetermined threshold range for the welding parameter as a position of the welding torch changes, the orientation of the welding torch changes, a movement of the welding torch changes, or some combination thereof, and rotating the graphical representation of the welding parameter based at least in part on the determined orientation of the display of the welding torch relative to the joint. The graphical representation of the welding parameter is associated with the position of the welding torch relative to the joint, the orientation of the welding torch relative to the joint, the movement of the welding torch relative to the joint, or some combination thereof.