The present disclosure relates to a non-contact type pile cutting apparatus using a waterjet, particularly to a pile cutting apparatus entering the inside for cutting a pile including: a body that has a pipe form and is put into an inside of the pile; a gripper unit that is provided at an outer side of the body and fixes the body to the pile when the pile cutting apparatus has reached a cutting position of the pile; a waterjet unit that is provided at one side of the body and fixed by the gripper unit, and then sprays an abrasive mixture in which an abrasive and a fluid are mixed, toward the pile in a high pressure; a rotation unit that rotates the waterjet unit around a central axis of the body; a feed line that feeds the abrasive mixture in which the fluid and the abrasive of a set ratio are mixed, to the waterjet unit from the outside; a feed unit that controls a feed pressure of the abrasive mixture fed through the feed line; and a nozzle driving unit that controls a position of the waterjet unit.

An abrasive head with clean gas infeed for cleaning/removing material surfaces and splitting/cutting materials by a liquid beam enriched with solid abrasive particles to extend the tool lifetime by eliminating damage to the liquid jet's aperture by the abrasive, avoid degrading the abrasive inside the tool and increase the cutting power and flow efficiency.

An abrasive head with clean gas infeed for cleaning/removing material surfaces and splitting/cutting materials by a liquid beam enriched with solid abrasive particles to extend the tool lifetime by eliminating damage to the liquid jet's aperture by the abrasive, avoid degrading the abrasive inside the tool and increase the cutting power and flow efficiency.

A method and apparatus produce an enhanced blast stream which may be directed at a workpiece. The enhanced blast stream has higher energy allowing the blast stream to remove difficult to remove coatings from substrates. A heated flow is combined with an entrained particle flow and expelled through a nozzle. The heated flow results in more energy being imparted to the coating.

A method and apparatus produce an enhanced blast stream which may be directed at a workpiece. The enhanced blast stream has higher energy allowing the blast stream to remove difficult to remove coatings from substrates. A heated flow is combined with an entrained particle flow and expelled through a nozzle. The heated flow results in more energy being imparted to the coating.

A wet dry blast system comprising having a source of pressurized air for providing a pressurized air flow, a source of pressurized water for providing a pressurized water flow, and an abrasive media source to provide an abrasive media flow. There is an abrasive release conduit for receiving the abrasive media flow, and an abrasive release orifice configured for directing the abrasive media flow along a desired or targeted portion of the abrasive release conduit.

A wet dry blast system comprising having a source of pressurized air for providing a pressurized air flow, a source of pressurized water for providing a pressurized water flow, and an abrasive media source to provide an abrasive media flow. There is an abrasive release conduit for receiving the abrasive media flow, and an abrasive release orifice configured for directing the abrasive media flow along a desired or targeted portion of the abrasive release conduit.

An apparatus for abrasive cleaning includes an abrasive media storage vessel for storing a supply of abrasive media at ambient pressure. The storage vessel has an outlet for supplying abrasive media into a first gas stream at a first gas pressure in a first flow passage, the first flow passage supplying a mixture of gas and abrasive media to an outlet nozzle. A main gas stream communicates with the outlet nozzle via a second flow passage at a second gas pressure, the second gas pressure being higher than the first gas pressure. The mixture of gas and abrasive media from the first flow passage is entrained into the main gas stream from the second flow passage in or downstream of the outlet nozzle.

An apparatus for abrasive cleaning includes an abrasive media storage vessel for storing a supply of abrasive media at ambient pressure. The storage vessel has an outlet for supplying abrasive media into a first gas stream at a first gas pressure in a first flow passage, the first flow passage supplying a mixture of gas and abrasive media to an outlet nozzle. A main gas stream communicates with the outlet nozzle via a second flow passage at a second gas pressure, the second gas pressure being higher than the first gas pressure. The mixture of gas and abrasive media from the first flow passage is entrained into the main gas stream from the second flow passage in or downstream of the outlet nozzle.

A wet media blasting system with a water injection system that provides more uniform distribution of the water, air and media components for achieving better application of the mixture while minimizing the amount of water required to contain and minimize or eliminate airborne particulate matter such as dust produced during the blasting operation. By more thoroughly mixing the water into the abrasive/water mix, the amount of water required is reduced. The abrasive feed is placed and shaped to optimize spray coverage and minimize abrasive flow into injection space thus mitigating water nozzle clogs. The abrasive flow is shaped as it is released from the metering valve in order to tighten the abrasive flow before it enters into the blast air stream. The shaped and tightened abrasive flow is maintained at the lower portion of the blast air stream. This positions the abrasive flow in optimum placement for spray wetting the abrasive as it flows into and through the nozzle. This also mitigates nozzle clogging by directing most of the abrasive flow away from the water spray nozzle port.