A blasting or stripping booth is provided creating a generally downward flow for treatment of fluid and particle flow, which reduces operator exposure to potentially hazardous debris. The booth comprises an enclosure defining an upper region for a workpiece, a lower region, and a separator assembly. In some instances the separator assembly includes individual separator units which are discrete units, each having a generally square or rectangular plan view configuration which are arranged in an array for providing the required process flow capabilities. Further embodiments utilize structures forming the separator which have an elongated trough-like configuration. These embodiments find a particular application in large-scale stripping or blasting booth used in production environments where workpieces may flow through a treatment system in a serial manner. Other suitable applications include batch type processing of parts.

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.

A shot treatment device includes, a rotary table rotatable in a first rotation direction about a first rotation shaft extending along a vertical direction, a plurality of placement tables arranged at intervals in a circumferential direction on an upper surface of the rotary table, an ejector configured to eject shot media, a first inspection detector configured to inspect surface properties of a workpiece, a shot chamber in which shot media is ejected to a workpiece, and a first inspection chamber provided downstream in the first rotation direction from the shot chamber. The ejector ejects shot media to a workpiece held on a first placement table that has entered the shot chamber, and the first inspection detector capable of ascending and descending is disposed above a second placement table that has entered the first inspection chamber and inspects surface properties of a workpiece held on the second placement table.

A shot treatment device includes, a rotary table rotatable in a first rotation direction about a first rotation shaft extending along a vertical direction, a plurality of placement tables arranged at intervals in a circumferential direction on an upper surface of the rotary table, an ejector configured to eject shot media, a first inspection detector configured to inspect surface properties of a workpiece, a shot chamber in which shot media is ejected to a workpiece, and a first inspection chamber provided downstream in the first rotation direction from the shot chamber. The ejector ejects shot media to a workpiece held on a first placement table that has entered the shot chamber, and the first inspection detector capable of ascending and descending is disposed above a second placement table that has entered the first inspection chamber and inspects surface properties of a workpiece held on the second placement table.

A shot cascading apparatus for cleaning 3D printed components, generally of any surface debris, such as residue silica from the printing of the component, includes a series of vertically aligned structures, including a shot supply hopper, having a bottom regulated shot gate, for discharging through gravity of metallic shot, into a lower aligned funnel, nested within the bin of a machine base, that allows for surface cleansing of a printed component while achieving a finished product. The supply hopper has a shot gate that is adjustable, for controlling the amount of released shot, and the bottom of the funnel includes a sand separator nozzle, that separates the steel shot from the residue sand, drawing the sand back into the nozzle and conveying it by suction to a location for collection. Beneath the bin is a shot recycle pump, that returns the steel shot back into the supply hopper, for immediate reusage. Various structural support is provided for the hopper, the funnel, and the bin, to maintain the relative degree of separation between these components, to facilitate their usage and operations.

A shot cascading apparatus for cleaning 3D printed components, generally of any surface debris, such as residue silica from the printing of the component, includes a series of vertically aligned structures, including a shot supply hopper, having a bottom regulated shot gate, for discharging through gravity of metallic shot, into a lower aligned funnel, nested within the bin of a machine base, that allows for surface cleansing of a printed component while achieving a finished product. The supply hopper has a shot gate that is adjustable, for controlling the amount of released shot, and the bottom of the funnel includes a sand separator nozzle, that separates the steel shot from the residue sand, drawing the sand back into the nozzle and conveying it by suction to a location for collection. Beneath the bin is a shot recycle pump, that returns the steel shot back into the supply hopper, for immediate reusage. Various structural support is provided for the hopper, the funnel, and the bin, to maintain the relative degree of separation between these components, to facilitate their usage and operations.

The invention relates to a method for operating a control logic of a blasting system (100), the blasting system (100) comprising at least one blasting nozzle (111) for blasting blasting material (91) into a process chamber (110) of the blasting system (100), wherein at least one component (90) can be arranged in the process chamber (110), wherein the blasting material (91) is supplied to the at least one blasting nozzle (111) from a blasting material exchange container (200) via a blasting material circuit (180, 181-185) of the blasting system (100), and wherein the method comprises: —receiving (3010) control data (70) from a logic element (201) of the blasting material exchange container (200) which is detachably arranged in the blasting material circuit (180, 181-185), and—operating (3015) the blasting system (100) on the basis of the control data (70).

A remotely operated abrasive blasting apparatus is provided. Systems incorporating the apparatus, and methods of treating surfaces using the apparatus and systems are also provided. The abrasive blasting apparatus eliminates the need for human operators to be present in the area being treated, and allows areas inaccessible to human operators to be treated.

Disclosed herein are components, systems, and methods of operating an abrasive fluid jet system that recycles and reuses abrasive particles for multiple cycles. The systems and methods include adjusting one or more operating parameters of the abrasive fluid jet system to compensate for a reduction in cutting power of the used abrasives as the used abrasive particles are continuously discharged from the outlet of the cutting head across multiple cycles. The one or more operating parameters include fluid pressure that forms the fluid jet, a cutting speed of the cutting head, and flow rate of abrasive particles, which are changeable while continuing to operate the abrasive fluid jet system. The one or more operating parameters include an orifice size through which a fluid passes to generate the second fluid jet, a mixing tube diameter through which the second abrasive fluid jet passes, and a length of the mixing tube.