A bulk material discharging system includes a transmission station including a transmitting vessel having a transmitting vessel inlet configured to receive bulk material from an outlet of a bulk material transporter, and a transmitting vessel outlet to transmit bulk material therefrom. The system also includes a transporter handling station located operatively upstream of the transmission station and including at least a portion of a transporter handler including at least one carriage with transporter couplings configured to engage corresponding carriage couplings of the bulk material transporter and configured to convey the bulk material transporter over the transmitting vessel.

A bulk material handling method includes: a) receiving and pneumatically conveying bulk material via pressurized dilute phase, dense phase, and/or hybrid dilute/dense phase, and/or vacuum drawn conveyance into bulk material containers (a112, c276); b) storing the bulk material in the containers (a112, c276); c) dispensing the bulk material from the containers (a112, c276) into a bulk material transporter (b100); d) transporting the transporter (b100) from the containers to a bulk material transmitting vessel (d240); and e) discharging the bulk material from the transporter (b100) into the transmitting vessel (d240), including releasing the bulk material from the transporter (b100) into the transmitting vessel (d240), and pneumatically transmitting the bulk material out of the transmitting vessel (d240) to downstream bulk material processing equipment. Discharging also may include rejecting the bulk material from the transporter (b100) to a waste container (W). A related system, subsystems, and apparatuses are also disclosed.

A bin slide assembly controls the amount of particulate material that is transferred from an agricultural bin, such as a feed bin, to a feed line for delivery for some end use. To allow the control to be automated or otherwise electronically operated, electronic motors can operate one or more slides that selectively block an outlet of the feed bin. The electronic control provides for a more precise operation of the bin slide to control the amount of material. In addition, the use of the electric motor provides a more convenient and easier to operate system. The slides are connected to screws, such as acme screws, which are activated by operation of the electric motor to rotate the screw, which translates the slide between open and closed configurations.

A continuous concentrate feeding equipment of the present invention includes a plurality of concentrate supply mechanisms (50) each including a pressure-adjusting tank that temporarily accumulates granular concentrate; a lift tank that receives the concentrate from the pressure-adjusting tank (50) and discharges the concentrate to a smelting furnace; and a pressure control system that controls pressures of the pressure-adjusting tank (50) and the lift tank (51) such that the concentrate is continuously supplied from the lift tank to the smelting furnace throughout a time when the concentrate is received in the pressure-adjusting tank (50) and a time when the concentrate is discharged into the lift tank (51). The plurality of concentrate supply mechanisms (100) to (103) are connected in parallel to a conveyor for carrying in concentrate from an upstream side of the conveyor to a downstream side thereof. Supply control means is provided to control supply of the concentrate such that the concentrate reception of the concentrate supply mechanism is performed in order from the upstream side to the downstream side and the concentrate reception of the concentrate supply mechanism at an upstream end is started before the end of the concentrate reception of the concentrate supply mechanism at an downstream end.

A continuous concentrate feeding equipment of the present invention includes a plurality of concentrate supply mechanisms (50) each including a pressure-adjusting tank that temporarily accumulates granular concentrate; a lift tank that receives the concentrate from the pressure-adjusting tank (50) and discharges the concentrate to a smelting furnace; and a pressure control system that controls pressures of the pressure-adjusting tank (50) and the lift tank (51) such that the concentrate is continuously supplied from the lift tank to the smelting furnace throughout a time when the concentrate is received in the pressure-adjusting tank (50) and a time when the concentrate is discharged into the lift tank (51). The plurality of concentrate supply mechanisms (100) to (103) are connected in parallel to a conveyor for carrying in concentrate from an upstream side of the conveyor to a downstream side thereof. Supply control means is provided to control supply of the concentrate such that the concentrate reception of the concentrate supply mechanism is performed in order from the upstream side to the downstream side and the concentrate reception of the concentrate supply mechanism at an upstream end is started before the end of the concentrate reception of the concentrate supply mechanism at an downstream end.

An exemplary embodiment of the present invention is directed to an apparatus for emptying material from a container on a vehicle. The apparatus has a container with a bottom surface and a sidewall. A membrane being mounted within the container proximate the sidewall and the bottom surface. The apparatus further includes an engine and ducts having a first end and a second end. The first end connected to the engine so as to receive gas from the engine and connected at the second end to the membrane so as to direct the gas into the membrane.

A lock-out pinion can be coupled to a center sump control shaft to rotate therewith. A lock-out slide can include a rack and a blocking cover. A lock-out guide can be coupled to the sump control housing and can form a guide channel. The lock-out slide can be received in the guide channel with the lock-out pinion drivingly coupled to the rack to move the lock-out slide along the guide channel from a lock-out position in which the blocking cover prevents rotation of the intermediate sump control shaft with the driving handle, to an unlocked position in which the blocking cover permits rotation of the intermediate sump control shaft with the driving handle, in response to manual rotation of the center sump control shaft in the center sump opening direction.

A tubular molded body that can reduce restrictions on attachment to another member to be easily attached to another member. The tubular molded body 10 includes a tube main body 11 formed in a tubular shape and an attachment flange 100 formed in a flange shape to project from the tube main body 11. The attachment flange 100 includes a thin-walled hinge 130 and is rotatable by the hinge.

A tubular molded body that can reduce restrictions on attachment to another member to be easily attached to another member. The tubular molded body 10 includes a tube main body 11 formed in a tubular shape and an attachment flange 100 formed in a flange shape to project from the tube main body 11. The attachment flange 100 includes a thin-walled hinge 130 and is rotatable by the hinge.

A supply device with which elements in disordered form, in particular connection elements as bulk elements, are suppliable to a second receiving volume. The supply device includes a first receiving container from which, via an outlet opening, a plurality of elements is deliverable to a second receiving container. The second receiving container may consist of an oscillation feeder. The oscillation energy of the oscillation feeder is specifically transmitted onto the elements, which are stored in the first receiving container. With the help of the transmitted oscillations, elements are transferred from the first receiving container via a transfer zone from the first receiving container into the second receiving container.