A method for cleaning using solid carbon dioxide is provided. Adhesive surfaces of the vehicle components are cleaned automatically in an assembly line including several work stations. The adhesive surfaces of the vehicle components may be adhesive surfaces of coated or painted vehicle components. The vehicle components may be composed of a metal alloy such as a steel or aluminum alloy, and/or composed of a fiber composite material such as carbon-fiber-reinforced plastic. The adhesive surfaces of the vehicle components may be cleaned with specifically adapted cleaning parameters.

Provided is a wet blasting treatment device including a first nozzle unit that discharges, toward a target treatment region of a workpiece, slurry in which a first liquid and abrasive grains are mixed, a second nozzle unit that discharges a second liquid toward an untreated region adjacent to the target treatment region such that a liquid film is formed in the target treatment region of the workpiece, and a control unit that controls a discharge amount of the second liquid discharged by the second nozzle unit such that the liquid film has a predetermined thickness.

Apparatus for use with a waterjet pump, a wellhead projecting above ground and a casing disposed below ground, the casing defining a longitudinal axis, the apparatus comprising, in use: a mount coupled to the wellhead; a platform coupled to the mount for rotation about a spin axis coincident with the longitudinal axis; a carrier coupled to the platform for rotation therewith, the carrier extending from an end disposed adjacent the platform, through the spin axis, to an end disposed adjacent the casing; a nozzle to which the carrier extends, which is coupled to the pump and which is directed radially with respect to the spin axis; a mechanism for causing the carrier to rotate; and an arrangement supporting the carrier for pivotal movement about a pivot axis perpendicular to the spin axis such that the nozzle is held in cutting position to the casing during rotation, to sever said casing.

Apparatus for use with a waterjet pump, a wellhead projecting above ground and a casing disposed below ground, the casing defining a longitudinal axis, the apparatus comprising, in use: a mount coupled to the wellhead; a platform coupled to the mount for rotation about a spin axis coincident with the longitudinal axis; a carrier coupled to the platform for rotation therewith, the carrier extending from an end disposed adjacent the platform, through the spin axis, to an end disposed adjacent the casing; a nozzle to which the carrier extends, which is coupled to the pump and which is directed radially with respect to the spin axis; a mechanism for causing the carrier to rotate; and an arrangement supporting the carrier for pivotal movement about a pivot axis perpendicular to the spin axis such that the nozzle is held in cutting position to the casing during rotation, to sever said casing.

A meshed shell and a sandblasting method are provided. The meshed shell includes a first end portion, a second end portion opposite to the first end portion, a first annular portion, a second annular portion connected to the first annular portion, a first mesh portion between the first end portion and the first annular portion and a second mesh portion between the second end portion and the second annular portion. The weights of the first end portion and the second end portion are the same. A maximum inner diameter of the mesh of the first and second mesh portions is smaller than a penetration size of the component. Both of the sum of the weights of the first and second end portions and the sum of the weights of the first and second annular portions are greater than the sum of the weights of the first and second mesh portions.

A device for cleaning adhesive surfaces of vehicle components using solid carbon dioxide is provided. The device may be used for automated cleaning in an assembly line with a plurality of work stations. The device includes a chamber-type cleaning area for vehicle components, a blasting device with a jet nozzle for emitting solid carbon dioxide onto the vehicle components, a transport device for transporting the vehicle components through the cleaning chamber, and a charge discharge device for discharging an electrostatic charge from the vehicle components in order to structurally and/or functionally improve the device.

A device for cleaning adhesive surfaces of vehicle components using solid carbon dioxide is provided. The device may be used for automated cleaning in an assembly line with a plurality of work stations. The device includes a chamber-type cleaning area for vehicle components, a blasting device with a jet nozzle for emitting solid carbon dioxide onto the vehicle components, a transport device for transporting the vehicle components through the cleaning chamber, and a charge discharge device for discharging an electrostatic charge from the vehicle components in order to structurally and/or functionally improve the device.

An apparatus for treatment of a surface has a holding tank configured to mix pressurized gas from the source with an abrasive glass powder, wherein the powder has a mean particulate size of 210 microns or less. A regulator in fluid communication with the holding tank is configured to reduce output pressure from the holding tank to 20 psi or lower. A nozzle is in fluid connection with the holding tank output, the nozzle having a shutoff valve, a feeder tube fitted to the valve and formed of a polymer material, and a hardened metal insert fitted into an end of the feeder tube and having an orifice that is configured to direct the compressed gas and abrasive glass powder to the surface.

An apparatus for treatment of a surface has a holding tank configured to mix pressurized gas from the source with an abrasive glass powder, wherein the powder has a mean particulate size of 210 microns or less. A regulator in fluid communication with the holding tank is configured to reduce output pressure from the holding tank to 20 psi or lower. A nozzle is in fluid connection with the holding tank output, the nozzle having a shutoff valve, a feeder tube fitted to the valve and formed of a polymer material, and a hardened metal insert fitted into an end of the feeder tube and having an orifice that is configured to direct the compressed gas and abrasive glass powder to the surface.

To treat parts printed by means of 3D printing from the powder bed, they are inserted into a trough belt conveyor which transports and circulates the parts and in which the parts are acted on by a fluid jet during the transport.