An independent safety warning and notification system for sandblasting operations that require an operator of a blasting hose to be remotely positioned to the blasting pot operator. A dedicated activation switch assembly is secured to an existing sandblast hose with a separate dead man switch or alternately with an integrated dead man switch allowing the blast nozzle operator to communicate critical information to the pot operator. A warning notification light display and audible alarm assembly with a remotely positional warning light alarm is selectively secured near the pot operator for notification that a prescribed predetermined action has been requested by the blast nozzle operator or an emergency situation by activation of the switch assembly.

A waterjet system in accordance with at least one embodiment of the present technology includes a cutting head and an associated catcher assembly. The cutting head directs an abrasive-containing waterjet toward a workpiece supported by a cutting deck of the catcher assembly. The catcher assembly also includes a tank and a container fluidly connected to the tank. The tank contains abrasive-containing liquid in which the waterjet diffuses after the waterjet passes through the workpiece. The container collects abrasive at least primarily by shielding abrasive-containing liquid within the container from at least some turbulence of abrasive-containing liquid within the tank during operation of the waterjet system. The catcher assembly also includes a quick-release coupling through which the container is removably connected to the cutting deck. Operating the quick-release coupling allows the container to be removed to dispose of the collected abrasive.

An abrasive blasting system and associated methods are disclosed. The abrasive blasting system includes a blast enclosure that receives a component to be blasted by an abrasive media. A dust collector is fluidly coupled to the blast enclosure and collects the dust from the blast enclosure generated by the blasting of the component by the abrasive media. The dust collector includes a filter and a fan having a motor. The filter is disposed upstream of the fan. The fan draws air and dust from the blast enclosure into the dust collector and draws air through the filter to separate the dust from the air. A sensor monitors a condition of the abrasive blasting system and generates a condition signal corresponding to the condition. A controller receives the condition signal and controls the fan based on the condition signal.

An abrasive blasting system and associated methods are disclosed. The abrasive blasting system includes a blast enclosure that receives a component to be blasted by an abrasive media. A dust collector is fluidly coupled to the blast enclosure and collects the dust from the blast enclosure generated by the blasting of the component by the abrasive media. The dust collector includes a filter and a fan having a motor. The filter is disposed upstream of the fan. The fan draws air and dust from the blast enclosure into the dust collector and draws air through the filter to separate the dust from the air. A sensor monitors a condition of the abrasive blasting system and generates a condition signal corresponding to the condition. A controller receives the condition signal and controls the fan based on the condition signal.

First guide pipes are disposed on both sides of blasting areas, and second guide pipes are disposed on both sides of the blasting area. A wire rod W is inserted through the first guide pipes and the second guide pipes, penetrating in a conveying direction of the wire rod W. The diameter of each of first insertion holes of the first guide pipes and second insertion holes of the second guide pipes is gradually reduced toward the downstream side in the conveying direction. The second guide pipe is installed in a state in which the downstream-side end portion in the conveying direction is inserted into the first insertion hole from the inlet side of the first guide pipe.

First guide pipes are disposed on both sides of blasting areas, and second guide pipes are disposed on both sides of the blasting area. A wire rod W is inserted through the first guide pipes and the second guide pipes, penetrating in a conveying direction of the wire rod W. The diameter of each of first insertion holes of the first guide pipes and second insertion holes of the second guide pipes is gradually reduced toward the downstream side in the conveying direction. The second guide pipe is installed in a state in which the downstream-side end portion in the conveying direction is inserted into the first insertion hole from the inlet side of the first guide pipe.

A separation device that separates a mixture of magnetic bodies that are granular and non-magnetic bodies that is granular into the magnetic bodies and the non-magnetic bodies. The separation device includes a magnetic force separating mechanism, a wind force generation portion, a first wind force separating portion, and a second wind force separating portion. The magnetic force separating mechanism separates the mixture into first separated objects and second separated objects by attracting the magnetic bodies from the mixture of magnetic force. The first separated objects mainly contain the magnetic and non-magnetic bodies. The second separated objects mainly contain the non-magnetic bodies and magnetic bodies. The wind force generation portion generates wind force. The first wind force separates the first separated objects into the magnetic and non-magnetic bodies of wind force. The second wind force separates the second separated objects into the non-magnetic bodies and magnetic bodies of wind force.

A separation device that separates a mixture of magnetic bodies that are granular and non-magnetic bodies that is granular into the magnetic bodies and the non-magnetic bodies. The separation device includes a magnetic force separating mechanism, a wind force generation portion, a first wind force separating portion, and a second wind force separating portion. The magnetic force separating mechanism separates the mixture into first separated objects and second separated objects by attracting the magnetic bodies from the mixture of magnetic force. The first separated objects mainly contain the magnetic and non-magnetic bodies. The second separated objects mainly contain the non-magnetic bodies and magnetic bodies. The wind force generation portion generates wind force. The first wind force separates the first separated objects into the magnetic and non-magnetic bodies of wind force. The second wind force separates the second separated objects into the non-magnetic bodies and magnetic bodies of wind force.

Included are methods and systems for recycling a gas emitted from non-aqueous cleaning. An example method includes contacting a contaminated equipment with a non-aqueous cleaning material; wherein the spent non-aqueous cleaning material emits the gas. The method further comprises capturing the emitted gas, filtering the emitted gas, and recycling the emitted gas into the non-aqueous cleaning material.

A shot processing apparatus including: a cabinet with a processing chamber formed therein, the processing chamber allowing a workpiece to be conveyed thereinto; a ejecting mechanism ejecting a shot media to a hole of the workpiece; and a conveyance device conveying the workpiece between a preparation position for the workpiece and the cabinet, wherein the conveyance device includes a plate-like rotary table provided to be rotatable about a rotation axis, being provided with a conveyor for moving the workpiece on an upper surface of the rotary table, and allowing the plurality of workpieces to be arranged thereon, the rotary table connects the conveyor to the preparation position and the cabinet at a predetermined rotational position, and the shot processing apparatus has an inspection area for inspecting a state of the hole of the workpiece, between the preparation position and the rotation axis of the rotary table.