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 oxyhydrogen torch system includes a gas storage system having an oxygen gas storage container and a hydrogen gas storage container; a first gas line in communication with the oxygen gas storage container; a second gas line in communication with the hydrogen gas storage container; a nozzle connected to the first gas line and the second gas line via a first valve and a second valve, the first and second valves to control gaseous flow through the nozzle, the nozzle having a handle; a trigger extending from the handle and engaged with the first valve and the second valve, the trigger operates gaseous flow through the nozzle; and an ignition to provide heat to gaseous flow through the nozzle; the nozzle operates a torch created by the hydrogen gas and the oxygen gas.

An oxyhydrogen torch system includes a gas storage system having an oxygen gas storage container and a hydrogen gas storage container; a first gas line in communication with the oxygen gas storage container; a second gas line in communication with the hydrogen gas storage container; a nozzle connected to the first gas line and the second gas line via a first valve and a second valve, the first and second valves to control gaseous flow through the nozzle, the nozzle having a handle; a trigger extending from the handle and engaged with the first valve and the second valve, the trigger operates gaseous flow through the nozzle; and an ignition to provide heat to gaseous flow through the nozzle; the nozzle operates a torch created by the hydrogen gas and the oxygen gas.

A torch with integral flashback arrestor and thermal shut-off device is provided. In one approach, a torch body includes a passageway of the torch body, and a cartridge assembly disposed within the passageway. The cartridge assembly may include at least one of: a resettable pressure-sensitive device, and a thermal shut-off device, wherein the pressure-sensitive device and the thermal shut-off device are modifiable from a first configuration to a second configuration in response to a pressure or temperature gradient in the torch body, and wherein the second configuration restricts flow through the passageway. The cartridge may further include a check valve disposed along the passageway, for example, within a bore of a bushing, or within a retainer coupled to the torch body at an inlet of the passageway.

An aspect provides a method of removing a liner of a well, the liner comprising a liner material. The method comprises providing a seal in the well for defining an upper and/or lower boundary of a removal space, the space being delimited by at least the seal and the liner and providing oxygen or an oxygen releasing compound in the space. The method further comprises providing an ignition module for igniting the liner material near a lower boundary of the space and activating the ignition for igniting the liner material. This method works faster and requires less energy. An important reason for the latter point is that burning of iron generates a large amount of energy. Furthermore, the burning of steel produces a powder (iron oxide) or small droplets so the waste is easier to handle.

The invention relates to an ozone supply unit (26) for a flame burner apparatus and/or an oxygen cutting apparatus (10), comprising an oxygen inlet (28) to be supplied with oxygen (18), an ozone generator (32) coupled to the oxygen inlet (28) and configured to convert at least a part of the oxygen (18) supplied to the oxygen inlet (28) into ozone (18a), and an outlet (30) coupled to the ozone generator (32), wherein the outlet (30) provides at least a part of the oxygen (18) supplied to the oxygen inlet (28) and at least a part of the ozone (18a) converted by the ozone generator (32). The ozone supply unit (26) is configured to be integrated into a flame burner apparatus and/or an oxygen cutting apparatus (30). The invention further relates to a method for supplying ozone to a flame burner apparatus and/or an oxygen cutting apparatus (30).

The relevant regulations in the field of automated flame-cutting technology stipulate various safety devices for the process-gas supply of a cutting torch. The invention relates to the simplified installation and maintenance of the safety devices and to a compact structure thereof. Proposed is a multi-functional safety module, in the module body of which there are integrated a first and a second safety element to prevent flame- or gas-blowout, and in which there is provided a mechanical plug-type connection for establishing a gas-tight connection between the safety elements and the corresponding gas lines of the cutting torch.

The relevant regulations in the field of automated flame-cutting technology stipulate various safety devices for the process-gas supply of a cutting torch. The invention relates to the simplified installation and maintenance of the safety devices and to a compact structure thereof. Proposed is a multi-functional safety module, in the module body of which there are integrated a first and a second safety element to prevent flame- or gas-blowout, and in which there is provided a mechanical plug-type connection for establishing a gas-tight connection between the safety elements and the corresponding gas lines of the cutting torch.

A cutting nozzle for a gas torch, such as a postmixed oxy-fuel gas torch, comprising a body with a torch end adapted to engage the gas torch, a discharge end, and a peripheral surface between the torch end and the discharge end. The body has a plurality of bores for respectively conducting fuel gas, preheat oxygen and cutting oxygen through the nozzle, each of the plurality of bores extending from the torch end and terminating in a respective discharge orifice at the discharge end of the body. A set of the plurality of bores are preheat oxygen bores connected to an oxygen source at the torch end for discharging the preheat oxygen at the discharge end. A plurality of air bores each have an inlet orifice located on the peripheral surface of the body and open to an air source, and a discharge orifice in or proximal to the discharge end.