A method of removing a conformal coating from a circuit board coated with said conformal coating, the method comprising: subjecting the circuit board to a jet comprising dry-ice ejected from a nozzle, to remove said conformal coating from said circuit board.

The temperature of the chamber housing a shot wheel of a shot blaster is controlled by positioning a fan exterior to the chamber that creates air flow across a mounting plate defining the chamber. The air flow created by the fan may also pass around the bearing surrounding the drive shaft that turns the shot wheel.

Apparatus for treating parts to remove imperfections in the parts includes: a chamber; a rotatable basket within the chamber; a source of liquified cold fluid; a source of dry ice particles; a programmed controller to control rotation of the basket, activation of the liquified cold fluid, cycle times and activation of the dry ice particles. The controller is programmed to activate rotation of the rotatable basket, activate the source of liquified cold fluid and activate the dry ice particles to treat parts in the rotatable basket.

Apparatus for treating parts to remove imperfections in the parts includes: a chamber; a rotatable basket within the chamber; a source of liquified cold fluid; a source of dry ice particles; a programmed controller to control rotation of the basket, activation of the liquified cold fluid, cycle times and activation of the dry ice particles. The controller is programmed to activate rotation of the rotatable basket, activate the source of liquified cold fluid and activate the dry ice particles to treat parts in the rotatable basket.

The invention relates to a treatment system for treating workpieces, in particular for cleaning and/or deburring, comprising at least one treatment device that has at least one treatment unit, which is configured to perform at least one treatment operation on the workpiece, as well as at least one receiving unit for accommodating the workpiece on or in the treatment device, a transport device that comprises at least one transport unit, with which the workpiece is transferable into a transfer position, from which the workpiece is transferable by means of the at least one receiving unit into a treatment position, as well as a control device for controlling the at least one treatment unit, the at least one receiving unit, and the at least one transport unit, wherein the at least one treatment device comprises two or more receiving units for accommodating a respective workpiece for transferring independently of one another into the treatment position, and wherein the control device controls the at least one treatment unit such that the workpieces are treated by said treatment unit in a time-offset manner according to a treatment operation of the same kind. The invention also relates to a method.

A multi-procedure integrated automatic production line for hard alloy blades under robot control is provided. The production line includes a rail-guided robot. A cutter passivation device and a blade cleaning and drying device are arranged on one side of the rail-guided robot. A blade-coating transfer table, a blade coating device, a blade boxing transfer table, a blade-tooling dismounting device and a blade boxing device are sequentially arranged on another side of the rail-guided robot. The blade-tooling dismounting device is arranged on one side of the blade boxing transfer table. The production line further includes squirrel-cage toolings for carrying the blades. The squirrel-cage tooling that are loaded with the blades can run among the cutter passivation device, the blade cleaning and drying device, the blade-coating transfer table and the blade boxing transfer table. The blades after being treated through the blade-tooling dismounting device are sent to the blade boxing device.

A cavitation peening system is disclosed, including a tank containing a fluid, a carrier, and an array of cavitation nozzles. The carrier is configured to deliver a workpiece to a treatment zone in the tank, and the array of cavitation nozzles are collectively configured to generate a cavitation induced whirlpool in the treatment zone.

A cavitation peening system is disclosed, including a tank containing a fluid, a carrier, and an array of cavitation nozzles. The carrier is configured to deliver a workpiece to a treatment zone in the tank, and the array of cavitation nozzles are collectively configured to generate a cavitation induced whirlpool in the treatment zone.

The invention relates to a method for the production and removal of a temporary protective layer for a cathodic coating, particularly for the production of a hardened steel component with an easily paintable surface, wherein a steel sheet made of a hardenable steel alloy is subjected to a preoxidation, wherein said preoxidation forms a FeO layer with a thickness of 100 nm to 1,000 nm and subsequently a melt dip coating is conducted, wherein, during the melt dip coating, a zinc layer is applied having a thickness of 5 to 20 μm, preferably 7 to 14 μm, on each side, wherein the melt dip process and the aluminum content of the zinc bath is adjusted such that, during the melt dip coating, an aluminum content for the barrier layer results of 0.15 g/m.sup.2 to 0.8 g/m.sup.2 and the steel sheet or sheet components made therefrom is subsequently heated to a temperature above the austenitizing temperature and is then cooled at a speed greater than the critical hardening speed in order to cause hardening, wherein oxygen-affine elements are contained in the zinc bath for the melt dip coating in a concentration of 0.10 wt.-% to 15 wt.-% that, during the austenitizing on the surface of the cathodic protective layer, form a thin skin comprised of the oxide of the oxygen-affine elements and said oxide layer is blasted after hardening by irradiation of the sheet component with dry ice particles.

Foam items may be buffed using particles such as particulate sodium bicarbonate in accordance with the present invention. Foam items may be, for example, expanded EVA foam items pre-formed into an intermediate size and shape. A skin layer may be formed during the expansion of the foam item to form an expanded foam item which may be entirely or partially removed by buffing the item using particles projected with selected buffing parameters. The buffing parameters may be varied based upon the thickness of at least a portion of the skin layer and/or the desired degree of moldability for the foam item after buffing. Particulate sodium bicarbonate or other types of particles used for buffing may be recycled and reused for further buffing of foam items.