A method and an apparatus efficiently and reliably cut a steel frame. The cutting method includes locating a cutting torch apart from the steel frame held by a holding device in a direction along a cutting surface, moving the cutting torch from a cutting start position to a first cutting end position in a first feed direction perpendicular to a supply direction along the cutting surface, while applying a flame from a fire port of the cutting torch in the supply direction and supplying cutting oxygen to thereby cut a part of the cutting surface, stopping the cutting torch at the first cutting end position and thereafter cutting an uncut part by moving the cutting torch from the first cutting end position in a second feed direction opposite to the first feed direction.

A underwater cutting torch having a control valve assembly, a check valve assembly and a torch head all positioned within a housing. The control valve assembly and check valve assembly include a passageway for gasses to flow that includes a coupler formed of PTFE material to inhibit combustion within the handle of the underwater cutting torch.

A underwater cutting torch having a control valve assembly, a check valve assembly and a torch head all positioned within a housing. The control valve assembly and check valve assembly include a passageway for gasses to flow that includes a coupler formed of PTFE material to inhibit combustion within the handle of the underwater cutting torch.

The Adjustable Circular Burner Attachment is a device that attaches to double-barrel burning torches to give an operator the ability to cut circles into steel or other metals. The attachment is adjustable to allow for different size circles to be cut. The attachment gives added stability for better quality cuts and a safer environment for the operator by becoming a part of the burning torch.

A bevel head assembly is shown capable of fine motor control of a cutting tool (for instance, a laser or plasma cutter) in three simultaneous dimensions of movement. A rack-and-pinion system moves the bevel head assembly and cutter up and down in the Z-axis while a rotational motor attached to the rack-and-pinion system moves the bevel head assembly in a first rotational (X) axis, and a linear actuator pivotally connected to the cutting tool is mounted to the rotational motor to move the bevel head assembly in a second (Y) rotational axis.

The system and method described herein generally pertains to generating a lead in profile that defines acceleration before a cutting velocity is achieved to perform a cutting operation and a lead out profile that defines deceleration after the cutting operation is performed. The lead in profile defines acceleration from approximately zero (0) to the cutting velocity within a duration of time in order to perform the cutting operation, wherein the lead in profile is calculated based on the cutting velocity or a type of material of the workpiece, a start location for the cutting operation, and a thickness of the workpiece. The lead out profile defines deceleration from the cutting operation to approximately zero (0) within a duration of time, wherein the lead out profile is calculated based on the cutting velocity or a type of material of the workpiece, an end location for the cutting operation, and a thickness of the workpiece.

The system and method described herein generally pertains to generating a lead in profile that defines acceleration before a cutting velocity is achieved to perform a cutting operation and a lead out profile that defines deceleration after the cutting operation is performed. The lead in profile defines acceleration from approximately zero (0) to the cutting velocity within a duration of time in order to perform the cutting operation, wherein the lead in profile is calculated based on the cutting velocity or a type of material of the workpiece, a start location for the cutting operation, and a thickness of the workpiece. The lead out profile defines deceleration from the cutting operation to approximately zero (0) within a duration of time, wherein the lead out profile is calculated based on the cutting velocity or a type of material of the workpiece, an end location for the cutting operation, and a thickness of the workpiece.

A system for performing exothermic operations or oxygen delivery uses a rod and handle configuration to create a flowpath of oxygen. The rod includes cables having stainless steel fibers that burn using the oxygen within a hollow center area. While burning, the rod cuts through material. A sheath covers the covers to contain the gases and prevent unraveling of the cables. The handle attaches to the rod and provides control of the flow of oxygen to the rod. A manifold fixing in place bottles of oxygen connects to the handle and can be fixed to provide different mixtures from different bottles. The rod is disconnected when needed to fix a mask thereto for delivering breathable oxygen to a patient.

A system for performing exothermic operations or oxygen delivery uses a rod and handle configuration to create a flowpath of oxygen. The rod includes cables having stainless steel fibers that burn using the oxygen within a hollow center area. While burning, the rod cuts through material. A sheath covers the covers to contain the gases and prevent unraveling of the cables. The handle attaches to the rod and provides control of the flow of oxygen to the rod. A manifold fixing in place bottles of oxygen connects to the handle and can be fixed to provide different mixtures from different bottles. The rod is disconnected when needed to fix a mask thereto for delivering breathable oxygen to a patient.

In some aspects, material processing head can include a body; an antenna disposed within the body; a first tag, associated with a first consumable component, disposed within a flux communication zone of the body at a first distance from the antenna, the first tag having a first resonant frequency; and a second tag, associated with a second consumable component, disposed within the flux communication zone of the body at a second distance from the antenna, the second tag having a second resonant frequency that is different than the first resonant frequency, where the first and second resonant frequencies are tuned based upon at least one of: i) a difference between the first distance and the second distance; or ii) a characteristic (e.g., shape) of the flux communication zone in which the first tag and/or the second tag is disposed.