A railway vehicle for moving material includes a first and a second railway wagon, each of which extend between respective first and a second end portion the first and second railway wagons engaged at the second end portion of the first railway wagon and at the first end portion of the second railway wagon, wherein the first and second railway wagons each include: a platform, a carriage, a conveyor carried by the platform and having an operating section configured to move the material along a advancement direction. The railway vehicle includes a connection device carried by at least one of the first and second railway wagons (and configured to define an intermediate section for connecting the operating sections of the conveyors of the first and second railway wagons.

A transport device for conveying a flowable material, comprises a screw conveyor for collecting the fluid from a collecting zone and transporting the fluid to a destination zone. The screw conveyor comprises a spiral which is wound around a shaft extending along a longitudinal axis and an outer casing which at least partly houses the spiral. The spiral has a plurality of turns. The outer casing has an inner surface facing respective head surfaces of at least some turns. Between two consecutive turns and the outer casing there is a compartment. The outer casing is made at least partly from a deformable polymeric material in such a way that the outer casing deforms radially and reversibly towards the outside when a solid particle of the flowable material conveyed by the spiral is interposed between a head surface of one turn and the inner surface of the outer casing, to allow the solid particle to be transferred from one compartment to a further compartment adjacent to said compartment passing between the head surface of the turn and the inner surface of the outer casing.

The invention employs a folding arm conveyor that rotates horizontally. The folding arm conveyor is mainly composed of an undercarriage mounted on the ground of a stockyard, a tower body mounted on the undercarriage, a balance arm, a conveying arm, a tower top, and other main components, wherein the balance arm, the conveying arm, and the tower top are mounted on the tower body. The conveying arm is provided with two portal frames (I) and (II) and an unloading trolley. The tower body is provided with a gyration apparatus and a hopper. The balance arm is provided with a balance trolley. The folding arm conveyor can rotate horizontally, and the conveying arm can be folded and retraced by controlling the wind rope by the windlass, so that the folding arm conveyor can be prevented from colliding with other devices or buildings during the rotation.

A vibrating screen feed conveying apparatus for conveying and separating sticky “moisture laden bulk solids” which are sticky and wet flowing onto a vibrating screening feeder and into a hopper. The apparatus includes a bed on which material is conveyed, a longitudinal counterbalance supported on a plurality of isolation springs, a plurality of inclined drive springs extending between the bed and the longitudinal counterbalance, and a plurality of stabilizers for controlling movement of the drive springs along their central axes. A plurality of vibratory motors, each having rotatable eccentric weights are attached to the rear end of the longitudinal counterbalance. The eccentric weights rotate in phase with one another to vibrate the bed at a vibration frequency.

A vibrating screen feed conveying apparatus for conveying and separating sticky “moisture laden bulk solids” which are sticky and wet flowing onto a vibrating screening feeder and into a hopper. The apparatus includes a bed on which material is conveyed, a longitudinal counterbalance supported on a plurality of isolation springs, a plurality of inclined drive springs extending between the bed and the longitudinal counterbalance, and a plurality of stabilizers for controlling movement of the drive springs along their central axes. A plurality of vibratory motors, each having rotatable eccentric weights are attached to the rear end of the longitudinal counterbalance. The eccentric weights rotate in phase with one another to vibrate the bed at a vibration frequency.

A sand conveying apparatus and a control method thereof, a controlling device, and a storage medium are provided. The sand conveying apparatus includes a storage device, a conveying device, and a hoisting device. The storage device is located above an area where sand needs to be input. The conveying device is connected with the storage device. The conveying device is configured to convey the sand to the storage device. The hoisting device is located above the conveying device. The hoisting device is configured to transport the sand in the sand container to the conveying device through an action of the hoist, and the hoist of the hoisting device is configured to move simultaneously along a plurality of route segments in different directions, so as to realize a linear movement between a first position where the hoist is located and a position where the hopper is located.

A system for continuously monitoring an apron feeder in real-time, the apron feeder having a plurality of units. The system includes a plurality of sensor modules of different types, wherein each sensor module includes at least one sensor configured to measure an individual condition of a unit of the apron feeder, to generate sensor data representing the measured individual condition, and to transmit the generated sensor data. A base station is configured to collect the sensor data from the plurality of sensor modules, and to transmit outbound data, which is based on the collected sensor data. A processing unit receives the outbound data from the base station, analyses the outbound data for determining whether or not any of the unit of the apron feeder needs to be replaced or readjusted based on its individual condition, and generates a result of the determination for continuously indicating an overall state of the apron feeder.

A method is provided for removing slack in a chain conveyor driven between a first sprocket and a second sprocket, the first sprocket and the second sprocket rotating in a first direction. The method includes: locking the second sprocket to prevent rotation of the second sprocket in a second direction opposite the first direction; operating the first sprocket in the second direction to position a slack portion between the first sprocket and the second sprocket; and removing at least one chain link from the slack portion.

A dry bulk pneumatic metering system includes a flow line configured for the passage of pneumatically-conveyed bulk material, a bulk material sensor arranged relative to the flow line, the bulk material sensor configured to send a first signal related to a quantity of the bulk material passing in the flow line and within a range of the bulk material sensor, a speed sensor arranged with respect to at least one area of the system, the speed sensor configured to send a second signal related to the speed of gas flow at the at least one area of the system, and a controller arranged to receive the first and second signals and configured to calculate a bulk material flow rate of the bulk material using the first and second signals.

The invention relates to a conveyor belt (100), in particular a tubular conveyor belt or a pocket conveyor belt, having a belt body (10), which has a cover plate (11) on the carrying side for receiving conveyable material to be transported, wherein a profiling formed substantially in the direction (Z) perpendicular to the surface (21) of the cover plate (11) on the carrying side is formed on the cover plate (11) on the carrying side. The profiling (14) has a plurality of transverse strip profiling regions (15) along a longitudinal direction (X) of the cover plate (11) on the carrying side, wherein the profiling (14) has a plurality of chevron profiling regions (16) in addition to the transverse strip profiling regions (15) along the longitudinal direction (X) of the cover plate (11) on the carrying side.