The invention relates to a vibratory floor made up of shaker modules protected against the entry of dust, and capable of emptying cohesive products. The inner volume (10) of each module is connected by means of a pipe (14) to an air or clean gas volume (19). Each module past the first row is provided with an anti-pressure device (46) made up of an anti-pressure plate (47) situated above the motor cover (44), supported by two flanges (48) and (49) resting on stationary parts (36) on either side of the module. The modules thus formed are protected against the entry of dust, and effectively emptying any cohesive product from silos, vessels, railroad cars or any other containers, without human or mechanized intervention.

A powder feeder according to one aspect of the present disclosure is a powder feeding device that feeds powder from a feeder to a nozzle. The powder feeding device includes a cartridge configured to store the powder in an airtight condition, and includes the feeder. The cartridge includes a port from which the powder is stored and withdrawn, and an open/close valve for opening and closing the port. The feeder includes a connection portion to which the cartridge is removably connected, a supply port configured to supply the powder in the cartridge connected to the connection portion into the feeder, and an opening/closing valve for opening and closing the supply port. The feeder is configured to insert the powder supplied from the supply port to the feeder into the nozzle, and the cartridge and the feeder are configured to form an enclosed space between the port and the supply port in response to the cartridge being connected to the connection portion.

A method of transporting a vehicle engine wire harness from a component preparation location to a component pick location is provided. The method includes placing the vehicle engine wire harness on a hook of a component hanger. The component hanger with vehicle engine wire harness is directed along a supply track assembly through a heated enclosure to the component pick location at a vehicle assembly line.

A grain bin has a top opening with a hopper for receiving grain that is directed downwardly to a spreader supported for rotation by a vertical tubular center shaft. The spreader has an elongated inclined chute having a V-shape cross-section. The chute has a center portion having an opening with a trap door pivoted or controlled from a mechanism operable from the top opening of the bin. A deflector is positioned under the trap door opening and rotates the chute in response to the flow of grain through the opening. The tubular center shaft encloses an electrical cable that supports a temperature sensing element within the grain in the bin, and a temperature monitoring device is connected to the cable outside the grain bin.

An apparatus comprises a hopper housing, a first auger, a second auger, a dividing panel, and a motor. The hopper housing holds a bulk material, with the hopper housing including a first end at which the bulk material is added to the hopper housing and a second end comprising a discharge opening at which the bulk material exits the hopper housing. The first auger is disposed proximate to the discharge opening. The second auger is disposed between the first end of the hopper housing and the first auger. The dividing panel is disposed between the first auger and the second auger and the dividing panel is coupled to the hopper housing at the first side thereof and forming a panel opening between the hopper housing and the second side thereof. The motor rotates the first auger and the second auger to move the bulk material into the discharge opening.

An apparatus comprises a hopper housing, a first auger, a second auger, a dividing panel, and a motor. The hopper housing holds a bulk material, with the hopper housing including a first end at which the bulk material is added to the hopper housing and a second end comprising a discharge opening at which the bulk material exits the hopper housing. The first auger is disposed proximate to the discharge opening. The second auger is disposed between the first end of the hopper housing and the first auger. The dividing panel is disposed between the first auger and the second auger and the dividing panel is coupled to the hopper housing at the first side thereof and forming a panel opening between the hopper housing and the second side thereof. The motor rotates the first auger and the second auger to move the bulk material into the discharge opening.

In a post-processing method for a workpiece, a workpiece machined by a machining device is conveyed by a robot, from the machining device to a post-processing device, information regarding a state, at the machining device, of the workpiece after machining is acquired, a processing time for post-processing of the workpiece by the post-processing device is determined by a control device on the basis of the information regarding the state of the workpiece after machining, and the post-processing is performed on the workpiece by the post-processing device for just the processing time that is determined.

In a post-processing method for a workpiece, a workpiece machined by a machining device is conveyed by a robot, from the machining device to a post-processing device, information regarding a state, at the machining device, of the workpiece after machining is acquired, a processing time for post-processing of the workpiece by the post-processing device is determined by a control device on the basis of the information regarding the state of the workpiece after machining, and the post-processing is performed on the workpiece by the post-processing device for just the processing time that is determined.

The continuous process of the present invention is intended to obtain dry biomass from two treatment steps by drying organic waste. The waste previously sieved and crushed waste are dumped into a first dryer, inside of which temperatures are between 280° C. and 300° C. at the inlet thereof and between 90° C. and 100° C. at the outlet, then passing to a conveyor belt where at room temperature a partial cool-down occurs and the waste is dumped into a second dryer inside of which the temperatures are between 180° C. and 200° C. at the inlet and between 75° C. and 85° C. at the exit, completing the process, during which the interior of the dryers is maintained in negative pressure through exhaust flow and the oxygen content is kept between 5 and 7%.

The continuous process of the present invention is intended to obtain dry biomass from two treatment steps by drying organic waste. The waste previously sieved and crushed waste are dumped into a first dryer, inside of which temperatures are between 280° C. and 300° C. at the inlet thereof and between 90° C. and 100° C. at the outlet, then passing to a conveyor belt where at room temperature a partial cool-down occurs and the waste is dumped into a second dryer inside of which the temperatures are between 180° C. and 200° C. at the inlet and between 75° C. and 85° C. at the exit, completing the process, during which the interior of the dryers is maintained in negative pressure through exhaust flow and the oxygen content is kept between 5 and 7%.