A portable debris removal system cleans debris and fluids from newly machined parts generally includes an enclosure assembly where a user cleans a machined part with a compressed air gun. The air within the enclosure assembly is evacuated for decontamination through a series of filters with remaining contaminates collected in a waste vessel. Ambient air and air gun expressed compressed air are drawn into the system via the Venturi effect created by a Venturi vent positioned on the bottom of the enclosure assembly.

A portable debris removal system cleans debris and fluids from newly machined parts generally includes an enclosure assembly where a user cleans a machined part with a compressed air gun. The air within the enclosure assembly is evacuated for decontamination through a series of filters with remaining contaminates collected in a waste vessel. Ambient air and air gun expressed compressed air are drawn into the system via the Venturi effect created by a Venturi vent positioned on the bottom of the enclosure assembly.

A method for cleaning a combustion engine is disclosed wherein an apparatus with a cable is coupled to an on-board diagnostic port on the vehicle, and a service hose with a misting nozzle adapter is coupled to a first port on a vehicle. A controller monitors data from the on-board diagnostic port on a vehicle, where the data preferably includes the engine rpm, the catalytic convertor temperature, the engine coolant temperature, the MAF, and the MAP. The controller monitors information from the cleaning apparatus, and the information is processed to adjust the dispensing of the cleaning solution. The adjustment of the cleaning solution can vary the rate, volume, pressure, pulse interval, flow pattern, and duration of the solution in the engine.

An example method to remove build material from a container is described. In that example a pulsed gas flow may be induced in a conduit to aspirate build material in pulses from the container.

An example method to remove build material from a container is described. In that example a pulsed gas flow may be induced in a conduit to aspirate build material in pulses from the container.

The electrical equipment dust collection system may comprise a cover panel, a vacuum port, a blow gun, a handle, and a light strip. The electrical equipment dust collection system may be a tool for removing dust from electrical equipment located inside of an equipment enclosure. The cover panel may be adapted to cover an open side of the equipment enclosure. An air hose fitting on the blow gun may be adapted to removably couple to a source of compressed air and the blow gun may direct a stream of air at the electrical equipment such that the dust is dislodged from the electrical equipment. A vacuum fitting on the vacuum port may be adapted to removably couple to a vacuum hose of a vacuum cleaner such that the vacuum cleaner may suction the dust out of the equipment enclosure.

The electrical equipment dust collection system may comprise a cover panel, a vacuum port, a blow gun, a handle, and a light strip. The electrical equipment dust collection system may be a tool for removing dust from electrical equipment located inside of an equipment enclosure. The cover panel may be adapted to cover an open side of the equipment enclosure. An air hose fitting on the blow gun may be adapted to removably couple to a source of compressed air and the blow gun may direct a stream of air at the electrical equipment such that the dust is dislodged from the electrical equipment. A vacuum fitting on the vacuum port may be adapted to removably couple to a vacuum hose of a vacuum cleaner such that the vacuum cleaner may suction the dust out of the equipment enclosure.

A conveyor belt cleaner system comprising a platen subassembly positioned transversely of the return path of the conveyor belt; a steam chamber disposed adjacent a first portion of the conveyor belt, the steam chamber including a steam header; a vacuum chamber adjacent the steam chamber and disposed adjacent a second portion of the conveyor belt, the vacuum chamber having an outlet connectable to a source of vacuum; a first belt wiper in wiping defining an entrance to the steam chamber; a second belt wiper having a discontinuous wiping surface defining a septum between the vacuum and steam chambers; a third belt wiper defining an exit from the vacuum chamber; and apparatus including a rotatable bolt cooperative with the steam header to vary the width of steam application from the steam header onto the conveyor belt in accordance with a width of conveyor belt presented to the conveyor belt cleaner system.

A conveyor belt cleaner system comprising a platen subassembly positioned transversely of the return path of the conveyor belt; a steam chamber disposed adjacent a first portion of the conveyor belt, the steam chamber including a steam header; a vacuum chamber adjacent the steam chamber and disposed adjacent a second portion of the conveyor belt, the vacuum chamber having an outlet connectable to a source of vacuum; a first belt wiper in wiping defining an entrance to the steam chamber; a second belt wiper having a discontinuous wiping surface defining a septum between the vacuum and steam chambers; a third belt wiper defining an exit from the vacuum chamber; and apparatus including a rotatable bolt cooperative with the steam header to vary the width of steam application from the steam header onto the conveyor belt in accordance with a width of conveyor belt presented to the conveyor belt cleaner system.

The treating arrangement (900) for an epitaxial reactor (1000) comprises: a reaction chamber (100) for treating substrates, a transfer chamber (200) adjacent to the reaction chamber (100), for transferring substrates placed over substrates support devices, a loading/unloading group (300) at least in part adjacent to the transfer chamber (200), arranged to contain a substrates support device with one or more substrates, a storage chamber (400) containing at least in part the loading/unloading group (300), having a first storage zone (410) for treated and/or untreated substrates and a second storage zone (420) for substrates support devices without any substrate, at least one external robot (500) for transferring treated substrates, untreated substrates and substrates support devices without any substrate between said storage chamber (400) and said loading/unloading group (300), at least one internal robot (600) for transferring substrates support devices with one or more substrates between said loading/unloading group (300) and said reaction chamber (100) via said transfer chamber (200); said loading/unloading group comprises a load-lock chamber (300A) and a preparation station (300B) associated with each other.