A high pressure fluid system including enhanced safety, maintenance and servicing features. The system can include a cartridge assembly module, having a valve seat assembly and a seal cartridge assembly selectively joinable with one another and installable within the high pressure fluid system.

Provided is a centrifuge media separator for separating blast particulate from fine particulate carried by air flowing from a blast cabinet and through the media separator. The centrifuge media separator comprises an upper panel, a lower panel, and an outer wall. The upper panel has a central opening formed therein. The outer wall is configured in a truncated logarithmic shape and which extends between the upper and lower panels. The outer wall has at least one particulate escape aperture formed therein. The upper panel, lower panel and outer wall collectively define a curvilinear air passageway having an inlet and an outlet. An air foil extends from the outer wall in to the air passageway. The distance than the air foil extends in to the air passageway is adjustable. The inlet is configured to allow a flow of air to enter the air passageway and circulate therethrough toward the outlet. The escape aperture is configured to exhaust the blast particulate out of the passageway. The central opening is configured to exhaust the fine particulate out of the passageway.

The invention relates to a method for adjusting or operating a particle-metering system for a particle blasting installation, in particular a blasting installation for the working of surfaces, the abrasive throughput of which is preset by means of a passing-through opening that can be varied on the basis of time and/or variables and is determined by means of a downstream throughput sensor as a throughput sensor signal (DS), wherein the throughput sensor signal (DS) is used for controlling a manipulated variable (SG) for the degree of setting of the passing-through opening, wherein to adjust the metering system for at least one value of the manipulated variable (SG) the actual throughput (D) through the passing-through opening is determined by means of a measurement of the weight of abrasive material (M) allowed through within a defined time period (Dt), and the manipulated variable (SG), the actual throughput (D) and the corresponding throughput sensor signal (DS) are stored in an assignment table, wherein the relations between the actual throughput (D), the manipulated variable (SG) and the throughput sensor signal (DS) are used during subsequent operation.

An abrasive jet apparatus configured to machine features into an inner diameter of bored structures. In the abrasive jet apparatus, an abrasive mixture of pressurized liquid and abrasive particles is propelled as an abrasive jet in a direction other than the direction in which the abrasive jet apparatus extends. The abrasive jet apparatus may be implemented in an automated boring system and boring method for machining rifling grooves and other features into bored structures. The boring system and boring method use an iterative process of mapping a target surface of the bored structure and adjusting parameters of the boring system in between successive passes of the abrasive jet on the target surface.

The use of abrasive entrainment waterjet technology to cut improvised hazardous devices, such as improvised explosive devices (IEDs), located above or below ground. Abrasive is conducted to an entrainment abrasive waterjet cutting head under the control of an abrasive feed and metering system that monitors the flow rate of abrasive.

The use of abrasive entrainment waterjet technology to cut improvised hazardous devices, such as improvised explosive devices (IEDs), located above or below ground. Abrasive is conducted to an entrainment abrasive waterjet cutting head under the control of an abrasive feed and metering system that monitors the flow rate of abrasive.

Wet abrasive blasting systems are described that have a slurry piping system and a gas piping system that have pipes and other piping components, such as valves and regulators, that have a more consistent internal cross-sectional area than conventional wet abrasive blasting systems. The more consistent flow area provides astonishing improvements in blasting efficiency and consistent and predictable slurry flow rates.

The present invention provides a system and method for wirelessly controlling an operating device by way of a wireless connection between the operating device and a computing device. The computing device provides an interface for controlling the operating device. The interface includes a switch for use as a deadman switch, whereby releasing the switch will cease the operation of the operating device. The user may remotely control the operating device via the computing device while the switch is actuated. Upon releasing the switch, the computer device wirelessly halts the operating device for safety.

Wet abrasive blasting systems are described that have a slurry piping system and a gas piping system that have pipes and other piping components, such as valves and regulators, that have a more consistent internal cross-sectional area than conventional wet abrasive blasting systems. The more consistent flow area provides astonishing improvements in blasting efficiency and consistent and predictable slurry flow rates.

An abrasive jet apparatus configured to machine features into an inner diameter of bored structures. In the abrasive jet apparatus, an abrasive mixture of pressurized liquid and abrasive particles is propelled as an abrasive jet in a direction other than the direction in which the abrasive jet apparatus extends. The abrasive jet apparatus may be implemented in an automated boring system and boring method for machining rifling grooves and other features into bored structures. The boring system and boring method use an iterative process of mapping a target surface of the bored structure and adjusting parameters of the boring system in between successive passes of the abrasive jet on the target surface.