Abstract: A media blast includes a nozzle body manufactured of a first material with a set of internal threads manufactured of a second material different than the first material. A media blast nozzle for a spray gun, the media blast nozzle includes a nozzle body manufactured of a first material, the nozzle body defines an axis; and an insert with a set of internal threads manufactured of a second material different than the first material, the insert located at least partially within the nozzle body.

Abstract: A device (33) for blast-machining or abrasive blasting objects such as structural elements, tools, household objects, pots, pans or the like, has a blast pot (3) for holding a blasting abrasive (35) which is connected via at least one line (21) to a blasting nozzle (24) which extends into a blasting space (1) in which the objects which are to be blasted can be placed. Compressed air is introduced above the blasting abrasive mixture (35) provided in the blast pot (3) by means of a pressure-generating means (43) and the blasting abrasive (35) thus being forced into the blasting space (1), the compressed air conveying via a second line (10) the granular material or the granular material mixture (35) and/or a suspension formed from granular material and liquid out of the blasting space (1) and back into the blast pot (3), which also takes the form of a pressurized space.

Abstract: A fan nozzle for cleaning a surface with an abrasive blast media is constructed of a longitudinal body having an axial pathway through which the media is passed under pressure for release from a substantially rectangular cross-sectional outlet to release the media in a substantially flat, wide path. A first transition zone provides a conversion in the axial pathway from the inlet cross-section to the substantially rectangular cross-section of the outlet opening. A second transition or convergence zone first reduces and then expands the cross-section of the axial pathway for providing a Venturii acceleration of the media as it passes through the nozzle. The transition zone and the convergence zone may be coexistent along a portion of the axial pathway.

Abstract: Prepping a surface entails entraining a coating particle into a fluid stream, directing the fluid stream containing the coating particle at the surface to be prepped to thereby prep the surface using the coating particle. The prepped surface can then be coated using the same or substantially similar coating particle. This technique can be used with a continuous airjet, a forced pulsed airjet, a continuous waterjet or a forced pulsed waterjet as the carrier stream. This invention solves the problem of foreign blasting particles becoming embedded in the atomic matrix of the surface to be prepped, which can result in unpredictable behavior of the surface properties and even catastrophic failure.

Abstract: A device (33) for blast-machining or abrasive blasting objects such as structural elements, tools, household objects, pots, pans or the like, has a blast pot (3) for holding a blasting abrasive (35) which is connected via at least one line (21) to a blasting nozzle (24) which extends into a blasting space (1) in which the objects which are to be blasted can be placed. Compressed air is introduced above the blasting abrasive mixture (35) provided in the blast pot (3) by means of a pressure-generating means (43) and the blasting abrasive (35) thus being forced into the blasting space (1), the compressed air conveying via a second line (10) the granular material or the granular material mixture (35) and/or a suspension formed from granular material and liquid out of the blasting space (1) and back into the blast pot (3), which also takes the form of a pressurized space.

Abstract: To provide a scribing method by blasting that allows forming a groove at high accuracy without masking, a blasting machine that includes an ejection nozzle having a slit-shaped ejection opening with a width of 10 to 500 ?m and a length of 5 to 5000 times the width, and an abrasive with a median diameter equal to or less than one-half of a width of the ejection opening of the ejection nozzle and with a maximum particle diameter smaller than a width of the ejection opening are used; and the abrasive is ejected together with compressed gas on a surface of a workpiece at an ejection distance of 0.1 to 3.0 mm without masking so that an ejection quantity of the abrasive is to be 0.25 cm3 or less relative to discharge gas amount 1000 cm3 in a range of ejection pressure of 0.2 to 0.6 MPa.

Abstract: A waterjet system for generating and delivering fluid jets suitable for processing a workpiece has a cutting head body and a mixing tube. The cutting head body includes a mixing chamber and a bore. The bore is positioned downstream of the mixing chamber, and an abrasive fluid jet from the mixing chamber passes through the mixing tube. The mixing tube has a first coupler adapted to magnetically couple the mixing tube to the cutting head body when the mixing tube is installed. The cutting head body has a second coupler positioned to engage the first coupler of the mixing tube to keep the mixing tube properly positioned during operation of the waterjet system.

Abstract: The cutting head of an abrasivejet cutting system preferably includes a replaceable generally tubular cartridge supporting a waterjet-forming orifice-defining member on one side of a mixing region, and an abrasivejet nozzle positioned on the opposite side of the mixing region in axial alignment with said orifice. The cartridge is formed from a material having tensile strength, yield strength and fatigue strength sufficient to withstand the operating pressure of the cutting system and sufficiently malleable and ductile to form a hard seal with a water-inlet tube to which it is coupled. The mixing region is defined within the cartridge by a layer of another material that is more abrasion-resistant than the cartridge material.

Abstract: A nozzle for a high pressure cutting arrangement is disclosed. The cutting arrangement comprises a liquid stream and a slurry stream, the slurry comprising abrasive particles suspended in a fluid, with both fluids being supplied into the nozzle under pressure. The nozzle has a combining chamber, having an entry region arranged to receive the liquid stream and the slurry stream, such that the pressure in the entry region is determined by the pressure in the liquid stream. The pressure in the entry region acts on the pressure in the slurry stream to regulate the pressure in the slurry stream.

Abstract: To cut out a hard-brittle substrate by blasting, laying out substrates 2 on a plate material 1 made of a hard-brittle material with leaving a space for blasting; forming first protective films 4 on both surfaces of the plate material 1 at layout positions of the substrates 2; and forming second protective films 5 on both surfaces of a margin 3 of the plate material 1 with leaving a space with respect to the first protective films 4 and having outer edges from a periphery of the plate material 1 at a width of 5 mm or less; cutting regions 6 between the films 4, 4 and between the films 4, 5 from one surface of the plate material 1 to a depth of approximately half of a thickness thereof by blasting, then cutting from the other surface of the plate material 1 until the plate material 1 is penetrated.

Abstract: For to avoid clogging from abrasive media, a nozzle contains an element for circular vortexing the passing jet of detergents in combination with a defined flexibility of its elements, which—together with a pulsating stream of media—causes vibrations, that constantly lead to peeling off adhering residues.

Abstract: Provided is an abrasive water jet nozzle comprising a mixing chamber for absorbing the abrasives with air through a supply port; a water nozzle; a mixing nozzle disposed on the downstream side against the water nozzle, to mix the abrasives in a water jet jetted out of the water nozzle, and to jet the water jet into the mixing chamber out of a through hole of the mixing nozzle; and an abrasive nozzle disposed on the downstream side against the mixing nozzle, to introduce the water jet thereinto to jet an abrasive water jet. A diameter of the through hole is larger than that of the water nozzle so that the abrasives in the mixing chamber are absorbed with air in a clearance between the through hole and the water jet passing through the through hole to mix the abrasives in the water jet.

Abstract: A method of prepping a surface using a high-frequency forced pulsed waterjet entails generating a high-frequency signal having a frequency f using a high-frequency signal generator, applying the high-frequency signal to a transducer having a microtip to cause the microtip of the transducer to vibrate to thereby generate a forced pulsed waterjet through an exit orifice of a nozzle having an exit orifice diameter d and a length L. The forced pulsed waterjet prepares the surface to within a predetermined range of surface roughness. The surface roughness is determined by selecting operating parameters comprising a standoff distance (SD), a traverse velocity VTR of the nozzle, a water pressure P, a water flow rate Q, a length-to-diameter (L/d) ratio, a microtip-to-orifice distance (a), the frequency f, and an amplitude A of the high-frequency signal.

Abstract: A profile cutting apparatus comprising: a cutting head supporting a nozzle through which a cutting medium passes, and at least two drives that drive the cutting head to tilt relative to a vertical axis while driving the cutting head to rotate about the vertical axis, wherein the tilt of the cutting head is achieved by the relative difference in motion between the two drives.

Abstract: A nozzle for providing carbon dioxide for cleaning is disclosed. The nozzle includes a reservoir for receiving liquid carbon dioxide, a barrel defining a passageway therethrough, the passageway extending to an outlet of the barrel, an orifice effecting fluid communication between the reservoir and the passageway, and a screen member constructed and arranged for interrupting flow of the carbon dioxide pellets greater than a select size from being emitted from the passageway of the barrel. Liquid carbon dioxide flows through the orifice to phase transfer into gaseous carbon dioxide and carbon dioxide pellets in the passageway. An internal diameter of the passageway is smaller than an internal diameter of the reservoir.

Abstract: A taper head control assembly is provided for a fluid jet cutting system. A base is movably mounted relative to a cutting table. A tilt body carries a fluid jet cutting apparatus and includes a rack. A tilt housing supports the tilt body and includes a pinion engaging the rack for selectively tilting the fluid jet cutting apparatus. A rotational axis housing is mounted to the base and a collar is rotatably mounted relative to the rotational axis housing. The collar carries the tilt axis housing to selectively rotate the water jet cutting apparatus relative to the base.

Abstract: A nozzle for cooling lubricant is described having a connecting chamber with a chamber inlet and with a deflector plate in the interior of the connecting chamber that is held on at least two mounting means, a main chamber that is removably mounted by the rear face on the front face of the connecting chamber and has a diffusion plate with drilled holes, and a nozzle plate that is removably mounted by the rear face on the front face of the main chamber and has a hole pattern adapted to a grinding wheel profile.

Abstract: A fixture for facilitating sandblasting of a generally cylindrical object includes a frame, a rotary table mounted on the frame, and a moveable blast head which can direct a flow of grit onto a cylindrical object mounted on the rotary table. The blast head may be movable vertically so that it can be extended down into the interior of a cylindrical object. The blast head may also be movable in a rotational fashion. Further the blast head may be movable in horizontal directions so that the blast head can be moved relative to a vertically extending cylindrical surface of a cylindrical object mounted on the rotary table. Controlled movements of the rotary table and the blast head allow uniform sandblasting of the cylindrical object.

Abstract: A system and a method for removing a coating from a substrate. The system provides a compressed air source, a heated water source, a particulate cleaning medium source, and a mixing valve including an air input, a water input, and a particulate cleaning medium input. The inputs are positioned on the valve so that the water input is positioned downstream of the compressed air input, and the particulate cleaning medium input is positioned downstream of both the compressed air and water inputs. The method of mixing the air, water, and particulate cleaning medium provides a coating removal mixture having a volumetric ratio of air to water of at least 100:1 and a volumetric ratio of air to particulate cleaning medium of at least 70:1.

Abstract: A high pressure cutting arrangement is formed by combining a liquid stream, such as water, and a slurry stream, the slurry comprising abrasive particles suspended in a liquid. Energy is supplied to the liquid stream by a first energising means, such as a constant pressure pump. Energy is supplied to the slurry stream by a second energising means, such as by a piston powered by a constant volume pump. The liquid stream and the slurry stream are combined in a cutting tool, in which the supplied energy is converted to kinetic energy to produce a combined liquid and abrasive stream at high velocity.

Abstract: A blasting device includes a flow passage (14) for a carrier gas, the flow passage (14) forming a blasting nozzle (12) at its downstream end, and a supply line (22) for liquid CO2, the supply line opening out into an expansion chamber (26) that is coaxially accommodated in the flow passage (14), the expansion chamber (26) being formed by a pipe (20) that is held at its upstream end by a holder (18) which is passed by the flow of carrier gas in the flow passage, and in that the supply line (22) extends through the holder (18) in transverse direction of the flow passage and opens into an expansion valve (24) that extends in parallel with the axis of the flow passage (14).

Abstract: Certain embodiments disclosed herein relate to compositions, methods, devices, systems, and products regarding frozen particles. In certain embodiments, the frozen particles include materials at low temperatures. In certain embodiments, the frozen particles provide vehicles for delivery of particular agents. In certain embodiments, the frozen particles are administered to at least one substrate.

Abstract: A nozzle and method of providing CO2 for cleaning includes providing a CO2 flow; phase transferring the CO2 flow into gaseous CO2 and CO2 pellets; interrupting the CO2 flow with a screen member; retaining the CO2 pellets of a select larger size upstream of the screen member; permitting the CO2 pellets of a select smaller size to pass through the screen member for cleaning.

Abstract: A sandblasting apparatus includes a processing chamber, a sandblasting nozzle positioned on a top of the processing chamber, a support mechanism, an elevation mechanism, a worktable, and a cutting mechanism. The support mechanism is positioned in the processing chamber and opposite to the sandblasting nozzle. The support mechanism is used for supporting a template with a cutting pattern. The elevation mechanism is positioned on the bottom of the processing chamber. The worktable is located between the support mechanism and the elevation mechanism and configured for supporting a plate for processing and being opposite to the template. The center of worktable defines a through hole matching with the pattern of the template. The cutting mechanism is fixed on the elevation mechanism and faces the through hole. The elevation mechanism drives the cutting mechanism to move toward or away the worktable.

Abstract: A processing apparatus is provided to process a workpiece. The processing apparatus can have a low-profile nozzle system capable of navigating through spaces in order to process target regions with relatively small clearances. A fluid jet outputted from the nozzle system is used to cut, mill, or otherwise process the target region of the workpiece.

Abstract: A nozzle assembly (1) generates a jet (9) of water, or abrasive particles suspended in water, for use in an abrasive waterjet-cutting head. The nozzle assembly (1) comprises a nozzle element (5, 80, 84, 86, 91) with a tapering bore (7) therethrough, mounted to a carrier (2, 52) so that the bore (7) is connected coaxially to a passage (4) through the carrier (2, 52), the bore (7) and passage (4) preferably having the same diameter where they meet. The nozzle element comprises a superhard material, such as diamond, in the form of a solid body (5, 81, 83, 86) or a coating (90). The nozzle element is mounted to the carrier (2, 52) by a brazed or soldered joint (6), extending normally to a longitudinal axis of the passage (4) and bore (7).

Abstract: A machine has a head with a nozzle, a pipe for supplying water under pressure to the nozzle, and a duct for supplying an abrasive agent, and adding it to the jet of water under pressure. The duct has a first duct portion, fixed with respect to the head in the movements of rotation about a main axis, and a second duct portion, which is fixed with respect to the movements of rotation. A rotating distributor connects the first rotating portion with the second fixed portion of the duct for supplying the abrasive agent. The distributor's stator and rotor are rotatably mounted on one another without the interposition of seal rings and define between them an internal chamber that is substantially at atmospheric pressure and from which the abrasive agent drops by gravity to a duct outlet that converges into the pipe for supplying water under pressure.

Abstract: Methods, systems, and techniques for automatically determining jet orientation parameters to correct for potential deviations in three dimensional part cutting are provided. Example embodiments provide an Adaptive Vector Control System (AVCS), which automatically determines speeds and orientation parameters of a cutting jet to attempt to insure that a part will be cut within prescribed tolerances where possible. In one embodiment, the AVCS determines the tilt and swivel of a cutting head by mathematical predictive models that examine the cutting front for each of “m” hypothetical layers in a desired part, to better predict whether the part will be within tolerances, and to determine what corrective angles are needed to correct for deviations due to drag, radial deflection, and/or taper.

Abstract: A glass manufacturing device includes a working container, a loading device, a sand blower, a shielding device, and a supporting device. The loading device is received in the working container and configured for loading a glass substrate in place. The sand blower is arranged opposite to the loading device and configured for sandblasting the glass substrate. The supporting device is used for supporting the shielding device and pressing the shielding device onto the glass substrate during the process of sandblasting. The shielding device includes a shielding cover having a number of shielding units. The shielding units are configured to shield portions of the glass substrate and prevent the portions of the glass substrate from being cut during sandblasting.

Abstract: A glass manufacturing device includes a work container, a loading device, a sandblaster, a shield device, and a lift device. The loading device is received in the work container and loads a glass substrate in place. The sandblaster is arranged opposite to the loading device and sandblasts the glass substrate. The lift device is connected to the shield device and used for pressing the shield device onto the glass substrate during the process of sandblasting. The shield device includes a shield cover having a number of shield units. The surfaces of the shield units facing the bottom of the work container are engaged with elastic washers. The shield units are configured to shield portions of the glass substrate and prevent the portions of the glass substrate from being cut during sandblasting.

Abstract: A grit pickup apparatus and method, and a grit pickup member used therewith that avoids the difficulties encountered with conventional devices. In accordance with certain embodiments, the grit pickup member includes an elbow-shaped preferably tubular member, having an aperture or slot formed in a wall thereof that allows communication between grit pickup media and the interior of the grit pickup member. The pickup member is submerged in the media such as granular material (e.g., sand), and as high velocity fluid travels by the aperture, the media is drawn into the interior region of the pickup member through the aperture and becomes entrained in the high velocity air stream, which carries it to the nozzle where it is expelled and directed toward a substrate to be cleaned.

Abstract: A fixture for facilitating sandblasting of a generally cylindrical object includes a frame, a rotary table mounted on the frame, and a moveable blast head which can direct a flow of grit onto a cylindrical object mounted on the rotary table. The blast head may be movable vertically so that it can be extended down into the interior of a cylindrical object. The blast head may also be movable in a rotational fashion. Further the blast head may be movable in horizontal directions so that the blast head can be moved relative to a vertically extending cylindrical surface of a cylindrical object mounted on the rotary table. Controlled movements of the rotary table and the blast head allow uniform sandblasting of the cylindrical object.

Abstract: A road marking removal system creating a blasting mixture by injecting particulate matter from a media hopper into flowing compressed air. The blasting mixture is directed at a road marking via a blasting nozzle. The nozzle discharges the blasting mixture from within a marking removal head housing. A vacuum is applied to an interior of the marking removal head housing for collecting the residual material created by the removal process. The residual material consists of particulate matter, road marking debris, and the like. The collected material can optionally be sorted with material of an acceptable size being reclaimed and forwarded to the media hopper for reuse. The road marking removal system can be manually operated being integrated into a cart, or remotely operated when integrated into a vehicle.

Abstract: An abrasive cutting or drilling system, apparatus and method, which includes an upstream supercritical fluid and/or liquid carrier fluid, abrasive particles, a nozzle and a gaseous or low-density supercritical fluid exhaust abrasive stream. The nozzle includes a throat section and, optionally, a converging inlet section, a divergent discharge section, and a feed section.

Abstract: In one aspect of the invention, an abrasion resistant nozzle has at least two sintered diamond bodies having flat, mating, exterior surfaces and a thickness, the surfaces being held against each other under compression. An enclosure is formed between the mating surfaces, at least one surface having a groove forming a portion of the enclosure and the other surface forming a remaining portion of the enclosure. The enclosure connects an entry and an exit formed in at least one side of at least one of the bodies.

Abstract: A waterjet system selectively produces fluid jets for water jet cutting or abrasive jets for abrasive-waterjet-cutting. The abrasive materials in the abrasive jet are determined based on the properties of the workpiece. The waterjet system includes an abrasive delivery system that is capable of delivering either a single abrasive or a plurality of abrasives as an abrasive blend, to a cutting head assembly. The cutting head assembly entrains the abrasive into a fluid jet to form an abrasive jet.

Abstract: Some embodiments can be implemented as a system, method, or nozzle and can include some of these features. A fluid jet cutting system can include a frame, a cutting head, a high-pressure fluid source, an abrasive source, and an actuator. The cutting head can include a fluid inlet, an orifice, a mixing chamber, and a fluid jet nozzle. The fluid jet nozzle can include an elongated body which can include a body axis, a fluid inlet orifice that can be in fluid communication with a plurality of conduits, and a source of high speed fluid and abrasive, which can be the cutting head's mixing chamber. Each of the plurality of conduits can: be in fluid communication with the fluid inlet orifice; have its own conduit axis that forms an angle with the body axis; and be in fluid communication with its own fluid outlet orifice.

Abstract: In a polishing performed by imparting kinetic energy to abrasive using a compressed gas flow, horizontal cutting force is obtained while vertical cutting force acting on a surface of a workpiece is inhibited. A compressed gas containing no abrasive is ejected from an accelerated flow generation nozzle 10 toward a surface of a workpiece W to generate an accelerated flow S along the surface of the workpiece W. Also, abrasive 30 is introduced into an abrasive introduction path 20 opening toward the surface of the workpiece W at an area where the accelerated flow S is generated, preferably together with a compressed gas to merge the abrasive 30 with the accelerated flow S and make the abrasive 30 slide along the surface of the workpiece W. Thus, horizontal cutting force is exerted on the surface.

Abstract: A method for drilling or cutting a pin surrounded by solid material includes the use of a water jet tool having a nozzle that is arranged at an angle with respect to a main body of the water jet tool. The water jet is directed over a portion of the surface of the pin, and removes that portion thereby fragmenting the pin. In order to minimize damage to the surrounding material, the portions removed touches the interface between the pin and the surrounding solid material at a minimal number of points and over a minimal extent of the interface. The method is applicable in particular to the removal of pins used in a press-fit for the securing of blades on a turbine rotor. The method facilitates “in situ” removal of pins within a confined space in a short time and at reduced cost.

Abstract: An abrasive waterjet assembly has a cutting head assembly with a venting system for controlling the flow of abrasive within a cutting head body. The venting system includes one or more vents for regulating the pressure within a cutting head body to minimize, limit, or substantially eliminate any abrasive from reaching a jewel orifice. The vents include venting ports positioned between an orifice mount that retains the jewel orifice and a mixing region in which abrasive is mixed with a fluid jet produced by the jewel orifice. An isolator retained in the cutting head body further inhibits the upstream flow of abrasive, if any.

Abstract: As a means of increasing the productivity and improving the safety of an internal diameter cylindrical blast cleaning, the introduction of an attachment apparatus makes it possible to eliminate or dramatically reduce the use of personnel inside a blast chamber while the process is ongoing thus improving safety of the process and improving the productivity and uniformity of the blasting process. The apparatus includes three principal elements: a blast chamber in which a cylindrical product to be to be treated is mounted on a device that rotates the cylindrical product to be treated; one or more blasting systems and one or more blasting operators. The system includes a delivery means for delivering a blast material output device into the inside of cylindrical product.

Abstract: A media blast nozzle for cleaning a surface with compressed air and ejected particles of a sublimating blast media comprises a media size changer to change a size of the blast media particles. The media blast nozzle has an entrance and an exit and a throat therebetween. A converging passageway extends from the entrance to the throat, and a diverging passageway extends from the throat to the exit. The media size changer is operably located in the diverging passageway and has one or more media size changing members to fragment moving blast media particles by impact therewith. The blast media particles are provided to the media blast nozzle in an initial consistent size, and when a moving blast media particle impacts with one or more media size changing members, two or more fragments of reduced size are created from the initial blast media particle for ejection from the nozzle device. The media size changer can be adjusted by an operator to eject whole particles or fragments of particles.

Abstract: The method of the present invention includes: a first blasting step of carrying out blasting of the surface of a metal base material, such as a shower head or a processing container, by using a blasting material composed of a non-sublimable material (e.g. alumina); and a second blasting step of carrying out blasting of the surface of the metal base material, which has undergone the first blasting step, by using a blasting material composed of a sublimable material (e.g. dry ice). The first blasting step properly roughens the surface of the metal base material so that a film, which adheres to the surface during film-forming processing, hardly peels off. In addition, the second blasting step almost fully removes the residual non-sublimable blasting material adhering to the surface of the metal base material, thereby preventing the generation of particles deriving from the residual non-sublimable blasting material falling off the metal base material.

Abstract: A sandblasting apparatus includes a processing chamber, a sandblasting nozzle positioned on a top of the processing chamber, a support mechanism, an elevation mechanism, a worktable, and a cutting mechanism. The support mechanism is positioned in the processing chamber and opposite to the sandblasting nozzle. The support mechanism is used for supporting a template with a cutting pattern. The elevation mechanism is positioned on the bottom of the processing chamber. The worktable is located between the support mechanism and the elevation mechanism and configured for supporting a plate for processing and being opposite to the template. The center of worktable defines a through hole matching with the pattern of the template. The cutting mechanism is fixed on the elevation mechanism and faces the through hole. The elevation mechanism drives the cutting mechanism to move toward or away the worktable.

Abstract: A device (33) for blast-machining or abrasive blasting objects such as structural elements, tools, household objects, pots, pans or the like, has a blast pot (3) for holding a blasting abrasive (35) which is connected via at least one line (21) to a blasting nozzle (24) which extends into a blasting space (1) in which the objects which are to be blasted can be placed. Compressed air is introduced above the blasting abrasive mixture (35) provided in the blast pot (3) by means of a pressure-generating means (43) and the blasting abrasive (35) thus being forced into the blasting space (1), the compressed air conveying via a second line (10) the granular material or the granular material mixture (35) and/or a suspension formed from granular material and liquid out of the blasting space (1) and back into the blast pot (3), which also takes the form of a pressurized space.

Abstract: An apparatus, method and computer program product for modifying a surface of a component is provided. In use, a surface of a component is translated relative to at least one jet for a period of time to form a plurality of features thereon.

Abstract: A spray coating process and apparatus suitable for depositing coatings on surfaces of components, and particularly surfaces that are difficult to access with conventional cold spraying equipment. The process and apparatus employ a spray gun having a tubular body with a longitudinal axis and an exit at one end thereof. The body has a first portion defining a converging passage, a second portion defining a diverging passage that defines the exit of the body, and a throat portion therebetween that defines a throat between and connecting the converging and diverging passages. The gun is further equipped with at least one gas inlet for introducing a gas upstream of the converging passage, and at least one feedstock inlet for introducing a feedstock at or immediately upstream of the throat.

Abstract: The invention relates to a gun for spraying liquid at a very high pressure, referred to as a focusing gun, and to a method for manufacturing same, according to which two elongate parts (2) are manufactured to be assembled so as to form the focusing gun. Each of said parts includes an assembly surface (J) comprising a central groove (3) for forming the duct of the focusing gun once the parts have been assembled, and a gluing tank (9) for being filled with an adhesive substance. Further, at least one of said parts (2) has a centering rib (6), projecting relative to the assembly surface thereof, while the other part has, for each centering rib (6), a centering cavity (7), the size of which is suitable for tightly housing said centering rib.

Abstract: An innovative method of prepping a surface entails entraining a coating particle into a fluid stream, directing the fluid stream containing the coating particle at the surface to be prepped to thereby prep the surface using the coating particle. The prepped surface can then be coated using the same or substantially similar coating particle. This method can be used with a continuous airjet, a forced pulsed airjet, a continuous waterjet or a forced pulsed waterjet as the carrier stream. This invention solves the problem of foreign blasting particles becoming embedded in the atomic matrix of the surface to be prepped, which can result in unpredictable behaviour of the surface properties and even catastrophic failure.

Abstract: A nozzle for a high pressure cutting arrangement is disclosed. The cutting arrangement comprises a liquid stream and a slurry stream, the slurry comprising abrasive particles suspended in a fluid, with both fluids being supplied into the nozzle under pressure. The nozzle has a combining chamber, having an entry region arranged to receive the liquid stream and the slurry stream, such that the pressure in the entry region is determined by the pressure in the liquid stream. The pressure in the entry region acts on the pressure in the slurry stream to regulate the pressure in the slurry stream.