An air-blowing method includes the steps of blowing, inside a machine tool, air onto a workpiece after machining, issuing a workpiece pick-up advance notice signal for notifying beforehand of pick-up of the workpiece by a robot or a worker, on the basis of a task state of the robot or an operation of the worker, and calculating the additional time for air blow on the basis of a time required by the robot or the worker to arrive at a workpiece pick-up position in front of the machine tool after the workpiece pick-up advance notice signal is issued, where air blow is extended by just the additional time in the step of blowing air.

An air-blowing method includes the steps of blowing, inside a machine tool, air onto a workpiece after machining, issuing a workpiece pick-up advance notice signal for notifying beforehand of pick-up of the workpiece by a robot or a worker, on the basis of a task state of the robot or an operation of the worker, and calculating the additional time for air blow on the basis of a time required by the robot or the worker to arrive at a workpiece pick-up position in front of the machine tool after the workpiece pick-up advance notice signal is issued, where air blow is extended by just the additional time in the step of blowing air.

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.

A process is for the maintenance of a belt conveyor, which includes a longitudinal conveyor belt and a number of support stations for the conveyor belt distributed along the conveyor belt. Each support station includes a cradle on which the conveyor belt rests. The process includes inserting an inflatable pad in a deflated state below the conveyor belt, in a lifting position near one of the support stations, inflating the inflatable pad to an inflated state in which the conveyor belt rests directly on the inflatable pad and no longer rests on the cradle of the support station, performing a maintenance operation on the support station, and deflating the inflatable pad to its deflated state.

A process is for the maintenance of a belt conveyor, which includes a longitudinal conveyor belt and a number of support stations for the conveyor belt distributed along the conveyor belt. Each support station includes a cradle on which the conveyor belt rests. The process includes inserting an inflatable pad in a deflated state below the conveyor belt, in a lifting position near one of the support stations, inflating the inflatable pad to an inflated state in which the conveyor belt rests directly on the inflatable pad and no longer rests on the cradle of the support station, performing a maintenance operation on the support station, and deflating the inflatable pad to its deflated state.

A belt-shaped material conveying apparatus that supports a belt-shaped material conveyed in a conveying direction to a wind-up roll at a carrying-out side from a feed roll at a carrying-in side between these rolls in a noncontact state by air streams spouted to the belt-shaped material from support pads disposed to face a top surface side and an undersurface side of the belt-shaped material respectively, includes a pair of hydraulic cylinders as tilt means that tilts the support pad in the width direction of the belt-shaped material which crosses the conveying direction of the belt-shaped material.

A belt-shaped material conveying apparatus that supports a belt-shaped material conveyed in a conveying direction to a wind-up roll at a carrying-out side from a feed roll at a carrying-in side between these rolls in a noncontact state by air streams spouted to the belt-shaped material from support pads disposed to face a top surface side and an undersurface side of the belt-shaped material respectively, includes a pair of hydraulic cylinders as tilt means that tilts the support pad in the width direction of the belt-shaped material which crosses the conveying direction of the belt-shaped material.

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%.