A spark absorbing system for use with a cutting torch, comprises a cap having at least one spark opening therethrough and a spark capture unit coupled to the cap and positioned to capture sparks passing through the spark opening. The spark capture unit may comprise a tube extending from the cap and may include an outlet and a flow-reduction element positioned between the cap and the outlet and/or a spark accumulator between the cap and the spark capture unit. The flow-reduction element may comprise at least one baffle, screen or mesh. The spark absorbing system may further include a spark ramp extending from the cap opposite the spark capture unit and/or a shield, which may define a cutting space between the shield and the cap.

Automated systems and methods for making cuts in large materials, particularly to trim and reduce the sizes of steel plates and slabs and produce therefrom one or more reduced-size pieces, optionally with the ability to reduce or avoid the need to perform a separate deburring operation on the materials after undergoing such cuts. Such a system includes multiple support units aligned in a longitudinal direction of a foundation and longitudinal and cross cutting units translatable in the longitudinal direction for performing, respectively, longitudinal and lateral cuts in a material. The support units are independently translatable in the longitudinal direction and each support unit has a crossmember that extends in the lateral direction, is adapted to at least partially support the material, and is operable to be raised and lowered in the vertical direction while the material is supported by the crossmembers.

Provided is a cutting machine that cuts a high-temperature moving object to be cut while moving in synchronization with the movement of the object to be cut, and that is capable of effectively protecting itself from the heat of the object to be cut and effectively utilizing the heat. A cutting machine for cutting a high-temperature moving object to be cut while moving in synchronization with the movement of the object to be cut, comprising: a cutter configured to cut the object to be cut; a movement device configured to move the cutting machine in synchronization with the object to be cut; a water-cooling plate configured to cool the cutting machine; and a thermoelectric power generation device including a thermoelectric element for converting the heat of the object to be cut into electric energy, wherein the water-cooling plate also serves to cool a low-temperature side of the thermoelectric element.

The present invention discloses a gantry cutting machine for pipe and flat plate, including a cutting assembly, a plate cutting mechanism, a pipe cutting mechanism and a crossbeam. The crossbeam is provided with a transverse driving unit. The cutting assembly is connected to the crossbeam. A cutting assembly mounting base is provided with a lifting-driving unit. The transverse driving unit includes a first gear, a first rack, a first motor and a first rail. The present invention provides a gantry cutting machine for pipe and flat plate to meet the demands in the field of numerically controlled cutting and machining of pipe products, which has a simple operation and is easy to use, and the clamping is flexible, so that the processing cost of pipe products can be reduced, and cutting and machining range of the numerically controlled cutting machine can be broadened.

The present invention relates to a cutting torch system having an ignition mode and a cooling and cleaning mode. The cutting torch system comprises a cutting torch (1) having a cutting oxygen channel (4), a heating oxygen channel (5), and a fuel gas channel (6) The heating oxygen channel (5) and the fuel gas channel (6) are connected to an ignition mixer (7) and a fuel gas shut-off valve (8) is arranged upstream of the ignition mixer (7). The fuel gas shut-off valve (8) is configured to be open in the ignition mode and closed in the cleaning and cooling mode. The ignition mixer (7) is adapted for mixing heating oxygen and fuel gas into an ignition gas and communicating the ignition gas into the cutting oxygen channel (4) in the ignition mode, and for communicating heating oxygen into the cutting oxygen channel (4) in the cleaning and cooling mode.

The present invention relates to a cutting torch system having an ignition mode and a cooling and cleaning mode. The cutting torch system comprises a cutting torch (1) having a cutting oxygen channel (4), a heating oxygen channel (5), and a fuel gas channel (6) The heating oxygen channel (5) and the fuel gas channel (6) are connected to an ignition mixer (7) and a fuel gas shut-off valve (8) is arranged upstream of the ignition mixer (7). The fuel gas shut-off valve (8) is configured to be open in the ignition mode and closed in the cleaning and cooling mode. The ignition mixer (7) is adapted for mixing heating oxygen and fuel gas into an ignition gas and communicating the ignition gas into the cutting oxygen channel (4) in the ignition mode, and for communicating heating oxygen into the cutting oxygen channel (4) in the cleaning and cooling mode.

An apparatus and method for supporting and severing an object of interest is described and which includes a frame for positioning an object of interest which is to be severed; a cutting device which is selectively mounted in spaced relation relative to the frame; a multiplicity of orientation units mounted on the frame and which are adjustable, as to length, to maintain the object of interest in a predetermined orientation while being severed; and a controller operably coupled to each of the cutting device, and orientation units, so as to effect an optimal severing of the object of interest while maintaining the object of interest in a given planar orientation on the frame.

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.

A method for disposing of a slug produced in a hole punching operation on a hollow profile is provided. The method includes the steps of providing a hollow profile; cutting at least one predeterminable hole or slug contour path into the hollow profile by means of a cutting device; leaving a residual web of the hole or slug contour path; moving a receiving device into the hollow profile; moving a punch from a first position into a residual-web-removing second position in such a way that the slug thereby produced is received by the receiving device; and moving the receiving device out of the hollow profile.

In known methods for through-cut detection in the thermally assisted through cutting of a workpiece, the workpiece is subjected to a first alternating signal. A method that allows a fast and accurate detection of a through-cut made comprises the method steps of detecting a second alternating electrical signal caused by the first alternating electrical signal in a measurement electrode spaced from the workpiece, determining the phase shift between the first and second alternating electrical signals to output a phase shift signal, and detecting a temporal evolution of the phase shift electrical signal or a measurement variable derived therefrom in a predetermined time interval. When a workpiece through-cut is made, it is detected in that the phase shift signal or the measurement variable derived therefrom is in the time interval within a predetermined fluctuation range.